es ete ate saaeee te ee te aoe i a o Qe Ak N14 1916 CORNELL UNIVERSITY THE Flower Urterinary Library FOUNDED BY ROSWELL P. FLOWER for the use of the N. Y. STATE VETERINARY COLLEGE 1897 This Volume is the Gift of Dr. V. A. Moore. 356 Ms Cornell University Library “iT BOOKS BY JOSEPH McFARLAND, M. D. Pathogenic Bacteria and Protozoa Octavo of 807 pages, illustrated. Eighth Edition Pathology Octavo of 856 pages, with 437 illustra- tions. Cloth, $5.00 net. Second Edition Biology: General and Medical yzmo of 457 pages, with 160 illustra- tions. Cloth, $1.75 net. Second Edition A TEXT-BOOK UPON THE PATHOGENIC BACTERIA AND PROTOZOA FOR STUDENTS OF MEDICINE AND PHYSICIANS ' BY JOSEPH McFARLAND, M. D., Sc. D. Professor of Pathology and Bacteriology in the Medico-Chirurgical College, Philadelphia; Pathologist to the Philadelphia General Hospital and to the Medico-Chirurgical Hospital, Philadelphia; Fellow of the College of Physicians of Philadelphia EIGHTH EDITION, REVISED WITH 323 ILLUSTRATIONS A NUMBER IN -COLORS PHILADELPHIA AND LONDON W. B. SAUNDERS COMPANY 1916 BOOKS BY JOSEPH McFARLAND, M. D. Pathogenic Bacteria and Protozoa Octavo of 807 pages, illustrated. ; Eighth Edition Pathology Octavo of 856 pages, with 437 illustra- tions. Cloth, $5.00 net. Second Edition Biology: General and Medical i2mo of 457 pages, with 160 illustra- tions, Cloth, $1.75 net. Second Edition A TEXT-BOOK UPON THE PATHOGENIC BACTERIA AND PROTOZOA FOR STUDENTS OF MEDICINE AND PHYSICIANS ' BY JOSEPH McFARLAND, M. D., Sc. D. Professor of Pathology and Bacteriology in the Medico-Chirurgical College, Philadelphia; Pathologist to the Philadelphia General Hospital and to the Medico-Chirurgical Hospital, Philadelphia; Fellow of the College of Physicians of Philadelphia EIGHTH EDITION, REVISED WITH 323 ILLUSTRATIONS A NUMBER IN COLORS PHILADELPHIA AND LONDON W. B. SAUNDERS COMPANY 1916 £6 M [4 19/6 Me 970 Copyright, 1896, by W. B. Saunders. ‘Reprinted September, 1896. Re- vised, reprinted, and recopyrighted August, 1898. Reprinted November, 1898. Revised, reprinted, and recopyrighted August, 1900. Reprinted June, 1901. Revised, entirely reset, reprinted, and recopyrighted May, 1903. eprinted August, 1904. Revised, reprinted, and recopyrighted May, 1906. Reprinted August, 1907, and May, 1908. Revised, reprinted, and recopyrighted August, 1909. Revised, reprinted, and recopyrighted September, 1912. Reprinted May, 1914. Revised, entirely reset, re- printed, and recopyrighted November, 1915. Copyright, 1915, by W. B. SAUNDERS CoMPANY. PRINTED IN AMERICA PRESS OF W. B. SAUNDERS COMPANY PHILADELPHIA TO MY HONORED AND BELOVED GRANDFATHER Mit. Jacob Grim WHOSE PARENTAL LOVE AND LIBERALITY ENABLED ME TO PURSUE MY MEDICAL EDUCATION THIS BOOK IS AFFECTIONATELY DEDICATED PREFACE TO THE EIGHTH EDITION Ir is a difficult thing to write a preface for an Eighth Edition. No part of the work was found to be so embarrassing or was sub- jected to greater: procrastination. What can be said that has not been said seven times already? Probably very little about the book; certainly very much about the ’ feelings of the author. He desires to express to those who have already made acquaintance with the book, and may with friendly feelings look into its new edition, his sincere satisfaction and appreciation of the hearty receptions that have been accorded his previous attempts. He also desires to thank his reviewers for some helpful criticisms. So numerous are the additions, subtractions and alterations to which the seventh edition was submitted in the preparation of this Eighth Edition, that it might almost be said that the text had been rewritten. Indeed they were such that the type of the entire book has been reset. It now appear with slightly larger pages; in two sizes of type, and gives a general effect of contraction, though there is really an expansion of matter that would have covered more than fifty of the old-size pages. The “Pathogenic Bacteria and Protozoa” is a medical work. It is hoped that it shall be found helpful to medical workers— students and practitioners of every class. PHILADELPHIA, Pa. THE AUTHOR. November, 1915. CONTENTS PART I.—GENERAL PaGE HISTORICAL INTRODUCTION . . 2. 1... ee ee ee 17 CHAPTER I STRUCTURE AND CLASSIFICATION OF THE Micro-OrcanisMs ...... 26 CHAPTER II Brotocy oF Micro-ORGANISMS .. 2... 1... ee et ee 50 CHAPTER III INFECTION 4 2 6 6 & )«@ @ ea & Site Bh Lat A aia digo cal Make tea pt sh 66 CHAPTER IV IMMUNITY ©... ....-..2., Ben hy ae dn ea a wt es sg Ag ae ws 88 CHAPTER V METHODS OF OBSERVING Micro-ORGANISMS .........0044 144 CHAPTER VI STERILIZATION AND DISINFECTION... 2... eee eee ee es 167 CHAPTER VII CuLturE-MEDIA AND THE CULTIVATION OF Micro-ORGANISMS. ... . 187 CHAPTER VIII CULTURES, AND THEIR STUDY .. 2 1 1 1 ee ee ee ee 201 CHAPTER IX THE CULTIVATION OF “Anairosic ORGANISMS .... 1... ee eee 215 CHAPTER X EXPERIMENTATION UPON ANIMALS. . 1. / 6 ee ee ee ee ee 222 CHAPTER XI Tuer IDENTIFICATION OF SPECIES ...-- - 1 ee ee eee ee + 230 CHAPTER XII THE BACTERIOLOGY OF THE AIR... .- +++ eee ene Ba a cas ae 284, CHAPTER XIII THE BACTERIOLOGY OF WATER... - - + et ee te ee eee ee 237 CHAPTER XIV Tue BacTERIOLOGY OF THE SOIL... 1. 1 ee ee ee ee eee 243 14 Contents CHAPTER XV es Tue BacTERIOLOGY oF Foops ... 1... 6 ee ee eee es 245 CHAPTER XVI Tue DETERMINATION OF THE THERMAL DEATH-POINT OF BACTERIA . . 249 CHAPTER XVII Tue DETERMINATION OF THE VALUE OF ANTISEPTICS, GERMICIDES, AND Dis- INBECTANTS 2) ng. a! Gig ce dee eo gy RU eae SO RAGA, A ea 251 CHAPTER XVIII BACTERIO-VACCINES . 0... 1 oe ee Sy pas teas 263 CHAPTER XIX Tue Pyacocytic POWER OF THE BLOOD AND THE Opsonic INDEX. . . 270 CHAPTER XX THE WASSERMANN REACTION FOR THE D1acNosis oF SYPHILIS ... . 279 PART II.—_THE INFECTIOUS DISEASES AND THE SPECIFIC MICRO-ORGANISMS CHAPTER I SUPPURATION isa" S.5 ioe ee Ae ae es Ry a eT oe Oe es 299 CHAPTER II MALIGNANT EDEMA’ 04 goa eg a a ee eo eS Re we 329 CHAPTER III RETANUS) 2:6 eae SO Googe Peay ok we ae ae Ge eee a eG 340 CHAPTER IV ANTHRAN? 2 2 Go. 2 cal a Me hs Iain Se Re SR EL a 352 CHAPTER V HypropHosia, Lyssa, on RABIES... ..... 1 ee ee te eee 363 CHAPTER VI AcuTE ANTERIOR POLIOMYELITIS .. 2... 1. 1 eee ee ee eee 381 CHAPTER VII CEREBRO-SPINAL MENINGITIS. . 2... 2. eee ee ee 386 CHAPTER VIII GONORRHEA. © ase cd. ge Bk Gk Ge ee ae ae we Ge Ged 394 CHAPTER IX CATARRHAL INFLAMMATION... 1... eee ee ee ee eee 400 CHAPTER X CHANCROID Contents 15 CHAPTER XI PaGE Acute CONTAGIOUS CONJUNCTIVITIS. . . 1... 5 0 ee ew ee es 406 CHAPTER XII DDIPBTHERTA > Gs rs te ae See Ey GS Bes RO 732 CHAPTER XXVI Mycetoma, on Mapura-Foot ....... 1... ee wee eee e 741 CHAPTER XXXVII BUASTOMYCOSIS® wh (ea A a Oo a ae ee + + 747 CHAPTER XXXVIII RINGWORM: 6. G4 ap ted. ge BRE ww Sha) ee ha GP w, SB ee a a 752 CHAPTER XXXIX . AVS. “Sty Gabe an Ae? PACA id ord a dah ut Malad cae Ses 755 CHAPTER XL SPOROTRICHOSIS. 2 se x 24) @ YY aM Se Re RSS Re RR 759 BrprioGrapuHic INDEX... 2... 1. 1 ee ee ee te ee 767 PART |. GENERAL HISTORICAL INTRODUCTION Brotocy, chemistry, medicine, and surgery, in their evolution, contributed to a new branch of knowledge, Bacteriology, whose subsequent development has become of inestimable importance to each. Indeed, bacteriology illustrates the old adage, “The child is father of the man,” for while it is in part the offspring of the medicine of the past, it has established itself as the dictator of the medicine of the present and future, especially so far as concerns the infectious diseases. THE EVOLUTION OF BACTERIOLOGY I. BIOLOGIC CONTRIBUTIONS; THE DOCTRINE OF SPONTANEOUS GENERATION Among the early Greeks we find that Anaximander (43d Olym- piad, 610 B. C.) of Miletus held the theory that animals were formed from moisture. Empedocles of Agrigentum (450 B. C.) attributed to spontaneous generation all the living beings which he found peopling the earth. Aristotle (384 B. C.) is not so general in his view of the subject, but asserts that ‘“‘sometimes animals are formed in putrefying soil, sometimes in plants, and sometimes in the fluids of other animals.” Three centuries later, in his disquisition upon the Pythagorean philosophy, we find Ovid defending the same doctrine of spontaneous generation, while in the Georgics, Virgil: gives directions for the artificial production of bees. The doctrine of spontaneous generation of life was not only current among the ancients, but we find it persisting through the Middle Ages, and descending to our own generation. In 1542, in his treatise called ‘“‘De Subtilitate,”’ we find Cardan asserting that water engenders fishes, and that many animals spring from fermenta- tion. Van Helmont gives special instructions for the artificial production of mice, and Kircher in his ‘Mundus Subterraneus”’ (chapter ““De Panspermia Rerum’’) describes and actually figures certain animals which were produced under his own eyes by the transforming influence of water on fragments of stems from different plants.* About 1671, Francesco Redi seems to have been the first to doubt that the maggots familiar in putrid meat arose de novo: * See Tyndall: ‘Floating Matter in the Air.” 2 17 18 Introduction “Watching meat in its passage from freshness to decay, prior to the appearance of maggots, he invariably observed flies buzzing around the meat and frequently alighting on it. The maggots, he thought, might be the half-developed progeny of these flies. Placing fresh meat in a jar covered with paper, he found that although the meat putrefied in the ordinary way, it never bred maggots, while meat in open jars soon swarmed with them. For the paper he substituted fine wire gauze, through which the odor of the meat could rise. Over it the flies buzzed, and on it they laid their eggs, but the meshes being too small to permit the eggs to fall through, no maggots generated in the meat; they were, on the contrary, hatched on the gauze. By a series of such experiments Redi destroyed the belief in the spontaneous generation of maggots in meat, and with it many related beliefs.”’ In 1683 Anthony van Leeuwenhoek, justly called the “Father of microscopy,” demonstrated the continuity of arteries and veins through intervening capillaries, thus affording ocular proof of Harvey’s discovery of the circulation of the blood; discovered bacteria, seeing them first in saliva, discovered the rotifers, and first saw the little globules in yeast which Latour and Schwann subse- ‘quently proved to be plants. Leeuwenhoek involuntarily reopened the old controversy about spontaneous generation by bringing forward a new world, peopled by creatures of such extreme minuteness as to suggest not only a close relationship to the ultimate molecules of matter, but an easy transition from them. In succeeding years the development of the compound microscope showed that putrescent infusions, both animal and vegetable, teemed with minute living organisms. Abbé Lazzaro Spallanzani (1777) filled flasks with organic in- fusions, sealed their necks, and, after subjecting their contents to the temperature of boiling water, placed them under conditions favorable for the development of life, without, however, being able to produce it. Spallanzani’s critics, however, objected to his experiment on the ground that air is essential to life, and that in his flasks the air was excluded by the hermetically sealed necks. Schulze (1836) set this objection aside by filling a flask only half full of distilled water, to which animal and vegetable matters were added, boiling the contents to destroy the vitality of any organisms which might already exist in them, then sucking daily into the flask a certain amount of air which was passed through a series of bulbs containing concentrated sulphuric acid, in which it was supposed that whatever germs of life the air might contain would be destroyed. This flask was kept from May to August; air was passed through it daily, yet without the development of any infusorial life. : It must have been a remarkably germ-free atmosphere in which The History of the Subject 19 Schulze worked, for, as was shown by those who repeated his experiment, under the conditions that he regarded as certainly excluding all life, germs can readily enter with the air. In 1838 Ehrenberg devised a system of classifying the minute forms of life, a part of which, at least, is still recognized at the present time. The term “‘infusorial life” having been used, it is well to remark that during all the early part of their recognized existence the bacteria were regarded as animal organisms and classed among the infusoria. Tyndall, stimulated by the work of Pasteur, conclusively proved that the micro-organismal germs were in the dust suspended in the atmosphere, and not ubiquitous in distribution. His experiments were very ingenious and are of much interest. First preparing light wooden chambers, with a large glass window in the front and a smaller window in each side, he arranged a series of test-tubes in the bottom, half in and half out of the chamber, and a pipet, working through a rubber diaphragm, in the top, so that when desired the tubes, one by one, could be filled through it. Such chambers were allowed to stand until all the contained dust had settled, and then submitted to an optical test to determine the purity of the contained atmosphere by passing a powerful ray of light through the side windows. When viewed through the front, this ray was visible only so long as there were particles suspended in the atmosphere to reflect it. When the dust had completely settled and the light ray had become invisible because of the purity of the contained atmos- phere, the tubes were cautiously filled with urine, beef-broth, and a variety of animal and vegetable broths, great care being taken that in the manipulation the pipet should not disturb the dust. Their contents were then boiled by submergence in a pan of hot brine placed beneath the chamber, in contact with the projecting ends of the tubes, and subsequently allowed to remain undisturbed for days, weeks, or months. In nearly every case life failed to develop in the infusions after the purity of the atmosphere was established. Il. CHEMIC CONTRIBUTIONS; FERMENTATION AND PUTREFACTION As in the world of biology the generation of life was an all- absorbing problem, so in the world of chemistry the phenomena of fermentation and putrefaction were inexplicable so long as the nature of the ferments was not understood. In the year 1837 Latour and Schwann succeeded in demonstrating that the minute oval bodies which had been observed in yeast since the time of Leeuwenhoek were living organisms—vegetable forms— capable of growth. ; So long as yeast was looked upon as an inert substance it was impossible ‘to understand how it could impart fermentation to other substances; but when it was shown by Latour that the essential 20 Introduction element: of yeast was a growing plant, the phenomenon became a perfectly natural consequence of life. Not only the alcoholic, but also the acetic, lactic, and butyric fermentations have been shown to result from the energy of low forms of vegetable life, chiefly bacterial in nature. Prejudice, however, prevented many chemists from accepting this view of the subject, and Liebig strenuously adhered to his theory that fermentation was the result of the internal molecular movements which a body in the course of de- composition communicates to other matter whose elements are connected by a very feeble affinity. Pasteur was the first to prove that fermentation is an ordinary chemic transformation of certain substances, taking place as the result of the action of living cells, and that the capacity to produce it resides in all animal and vegetable cells, though in varying degree. In 1862 he published a paper ‘“‘On the Organized Corpuscles Existing in the Atmosphere,” in which he showed that many of the floating particles collected from the atmosphere of his laboratory were organized bodies. If these were planted in sterile infusions, abundant crops of micro-organisms were obtained. By the use of more refined methods he repeated the experiments of others, and showed clearly that “the cause which communicated life to his infusions came from the air, but was not evenly distributed through it.” Three years later he showed that the organized corpuscles which he had found in the air were the spores or seeds of minute plants, and that many of them possessed the property of withstanding the temperature of boiling water—a property which explained the peculiar results of many previous experimenters, who failed to prevent the development of life in boiled liquids inclosed in her- metically sealed flasks. Chevreul and Pasteur, by having proved that animal solids do not putrefy or decompose if kept free from the access of germs, suggested to surgeons that putrefaction in wounds is due rather to the entrance of something from without than to changes within. The deadly nature of the discharges from putrescent wounds had been shown in a rough manner by Gaspard as early as 1822 by injecting some of the material into the veins of animals. II. MEDICAL AND SURGICAL CONTRIBUTIONS; THE STUDY OF THE INFECTIOUS DISEASES Probably the first writing in which a direct relationship between micro-organisms and disease is suggested is by Varro, who says: “Tt is also to be noticed, if there be any marshy places, that certain minute animals breed [there] which are invisible to the eye, and yet, getting into the system through mouth and nostrils, cause serious disorders (diseases which are difficult to treat).” Surgical methods of treatment depending for their success upon The History of the Subject 2I exclusion of the air, and of course, incidentally if unknowingly, exclusion of bacteria, seem to have been practised quite early. Theodoric, of Bologne, about’ 1260 taught that the action of the air upon wounds induced a pathologic condition predisposing to sup- puration. He also treated wounds with hot wine fomentations. The wine was feebly antiseptic, kept the surface free from bacteria, and the treatment was, in consequence, a modification of what in later centuries formed antiseptic surgery. Henri de Mondeville in 1306 went even further than Theodoric, whom he followed, and taught the necessity of bringing the edges of a wound together, covered it with an exclusive plaster com- pounded of turpentine, reSin, and wax, and then applied the hot wine fomentation. In 1546 Geronimo Fracastorius published at Venice a work “ De contagione et contagiosis morbis et curatione,”’ in which he divided infectious diseases into— 1. Those infecting by immediate contact (true contagions). 2. Those infecting through intermediate agents, such as fomites. 3. Those infecting ata distance or through the air. He mentions as belonging to this class phthisis, the pestilential fevers, and a certain kind of ophthalmia (conjunctivitis). “Tn his account of the true nature of disease germs, or seminaria contagionum, . . . he describes them as particles too small to be apprehended by our senses, but as capable in appropriate media of reproduction, and in this way of infecting surrounding tissues. “These pathogenic units Fracastorius supposed to be of the nature of colloidal systems, for if they were not viscous or glutinous by nature they could not be transmitted by fomites. Germs transmitting disease at a distance must be able to live in the air a certain length of time, and this condition he holds is possible only when the germs are gelatinous or colloidal systems, for only hard, inert, discrete particles could endure longer. “Fracastorius conceived that the germs became pathogenic through the action of animal heat, and in order to produce disease it is not necessary that they should undergo dissolution, but only metabolic change.’’* In 1671 Kircher wrote a book in which he expressed the opinion | that puerperal fever, purpura, measles, and various other fevers were the result of a putrefaction caused by worms or animalcules. His opinions were thought by his contemporaries to be founded upon too little evidence, and were not received. Plencig, of Vienna, became convinced that there was an undoubted connection between the microscopic animalcules exhibited by the microscope and the origin of disease, and advanced this opinion as early as 1762. In 1704 John Colbach described ‘‘a new and secret method of * “Brit. Med. Jour.,” May 7, 1910, p. 1122. 22 Introduction treating wounds by which healing took place quickly, without inflammation or suppuration.” Boehm succeeded in 1838 in demonstrating the occurrence of yeast plants in the stools of cholera, and conjectured that the process of fermentation was concerned in the causation of that disease. In 1840 Henle considered all the evidence that had been collected, and concluded that the cause of the infectious diseases was to be sought for in minute living organisms or fungi. He may be looked upon as the real propounder of the Germ THEORY OF DISEASE, for he not only collected facts and expressed opinions, but also investi- gated the subject ably. The requirements which he formulated in order that the theory might be proved were so severe that he was never able to attain to them with the crude methods at his disposal. They were so ably elaborated, however, that in after years they were again postulated by Koch, and it is only by strict conformity with them that the definite relationship between micro-organisms and disease has been determined. Briefly summarized, these requirements are as follows: 1. A specific micro-organism must be constantly associated with the disease. 2. It must be isolated and studied apart from the disease. 3. When introduced into healthy animals it must produce the disease, and in the animal in which the disease has been experiment- ally produced the organism must be found under the original conditions. a In 1843 Dr. Oliver Wendell Holmes wrote a paper upon the “‘Contagiousness of Puerperal Fever.”’ - In 1847 Semmelweiss, of Vienna, struck by the similarity between fatal wound infection with pyemia and puerperal fever, cast aside the popular theory that the latter affection was caused by the absorption into the blood of milk from the breasts, and announced his belief that the disease depended upon poisons carried by the fingers of physicians and students from the dissecting room to the woman in child-bed, and recommended washing the hands of the accoucheur with chlorin or chlorid of lime, in addition to the use of soap and water. He was laughed to scorn for his pains. In 1849 J. K. Mitchell, in a brief work upon the ‘‘Cryptogamous Origin of Malarious and Epidemic Fevers,” foreshadowed the germ theory of disease by collecting a large amount of evidence to show that malarial fevers were due to infection by fungi. Pollender (1849) and Davaine (1850) succeeded in demonstrating the presence of the anthrax bacillus in the blood of animals suffering from and dead of that disease. Several years later (1 863) Davaine, having made numerous inoculation experiments, demonstrated that this bacillus was the materies morbi of the disease. The bacillus of anthrax was probably the first bacterium shown to be specific for a The History of the Subject 23 disease. Being a very large bacillus and a strongly vegetative organism, its growth was easily observed, while the disease was one readily communicated to animals, Klebs, who was one of the pioneers of the germ rect published, in 1872, a work upon septicemia and pyemia, in which he expressed himself convinced that the causes of these diseases must come from without the body. Billroth, however, strongly opposed such an idea, asserting that fungi had no especial importance either in the processes of disease or in those of decomposition, but that, existing everywhere in the air, they rapidly developed in the body as soon as through putrefaction a ‘‘Faulnisszymoid” (putrefactive ferment), or through inflammation a “Phlogistischezymoid” (inflammatory ferment), supplying the necessary feeding-grounds, was produced. In 1873 Obermeier observed that actively motile, flexible spiral organisms were present in large numbers in the blood of patients in the febrile stages of relapsing fever. In 1875 the number of scientific men who had entirely abandoned the doctrine of spontaneous generation and embraced the germ theory of disease was small, and most of those who accepted it were experimenters. A great majority of medical men either believed, like Billroth, that the presence of fungi where decomposition was in progress was an accidental result of their universal distribution, or, being still more conservative, adhered to the old notion that the bacteria, whose presence in putrescent wounds as well as in artificially prepared media was unquestionable, were spontaneously generated there. Before many of the important bacteria had been discovered, and while ideas upon the relation of micro-organisms to disease were most crude, some practical measures were suggested that produced greater agitation and incited more observation and experimentation than anything suggested in surgery since the introduction of anes- thetics—namely, antisepsis. “Tt is to one of old Scotia’s sons, Sir Joseph Lister, that the everlasting gratitude of the world is due for the knowledge we possess in regard to the relation existing between micro-organisms and inflammation and suppuration, and the power to render wounds aseptic through the action of germicidal substances.’’* Lister, convinced that inflammation and suppuration were due to the entrance of germs from the air, instruments, fingers, etc., into _wounds, suggested the employment of carbolic acid for the purpose of keeping sterile the hands of the operator, the skin of the patient, the surface of the wound, and the instruments used. He finally concluded every operation by a protective dressing to exclude the extrance of germs at a subsequent period. Listerism, or ‘‘antisepsis,” originated in 1875, and when Koch published his famous work on the “ Wundinfectionskrankheiten”’ " * Apnew’s “Surgery,” vol. 1, chap. 11. 24 Introduction (Traumatic Infectious Diseases), in 1878, it spread slowly at first, but surely in the end, to all departments of surgery and obstetrics. From time to time, as the need for them was realized, the genius of investigators provided new devices which materially aided in their work, and have made possible many discoveries that must otherwise have failed. Among them may be mentioned the improvement of the compound microscope, the use of sterilized culture fluids by Pasteur, the introduction of solid culture media and the isolation methods by Koch, the use of the cotton plug by Schréder and van Dusch, and the introduction of the anilin dyes by Weigert. It is interesting to note that after the discovery of the anthrax bacillus by Pollender and Davaine, in 1849, there was a period of . nearly twenty-five years during which no important pathogenic organisms were discovered, but during which technical methods were being elaborated, making possible a rapid succession of subsequent important discoveries. Thus, in 1873, Obermeier discovered Spirillum obermeieri of relapsing fever. In 1879 Hansen announced the discovery of bacilli in the cells of leprous nodules, and Neisser discovered the gonococcus In 1880 the bacillus of typhoid fever was observed by Eberth and independently by Koch, Pasteur published his work upon ‘‘ Chicken- cholera,’ and Sternberg described the pneumococcus, calling it Micrococcus pasteurt. In 1882 Koch made himself immortal by his discovery of and work upon the tubercle bacillus, and in the same year Pasteur published a work upon “ Rouget du porc,” and Léffler and Shiitz discovered the bacillus of glanders. In 1884 Koch reported the discovery of the ‘comma bacillus,” the cause of cholera, and in the same year Léffler isolated the diphtheria bacillus, and Nicolaier the tetanus bacillus. In 1892 Canon and Pfeiffer discovered the bacillus of influenza. In 1894 Yersin and Kitasato independently isolated the bacillus causing the bubonic plague, then prevalent at Hong-Kong. A new era in bacteriology, and probably the most triumphant achievement of scientific medicine, was inaugurated in 1890, when Behring discovered the principles of the ‘‘blood-serum therapy.” Since that time investigations have been largely along the lines of immunity, immunization, and the therapeutic serums, the names of Behring, Kitasato, Wernicke, Roux, Ehrlich, Metschnikoff, Bordet, . Wassermann, Shiga, Madsen, and Arrhenius taking front rank. The discovery of the Treponema pallidum, the specific organism of syphilis, was made in 1905 by Schaudinn and Hoffmann, long after clinical study of the disease had anticipated it to such an extent that when the discovery was finally made it was unnecessary to modify our ideas of the disease in any essential. The History of the Subject 25 In the same year, 1905, Castellani discovered the Treponema pertenue, the cause of frambesia or yaws. In 1911 Noguchi succeeded in obtaining pure cultures of the treponema. In 1913 Flexner and Noguchi appear to have been successful in cultivating the virus of acute anterior poliomyelitis, in vitro. During the time that so much investigation of the problems of infection was in progress the discoveries were by no means restricted to the bacteria and their products, as the reader might infer from the perusal of a chapter whose purpose is to explain the development of the department of science now known as Bacteriology. Other organisms of different—i.e., animal—nature were also found in large numbers. In 1875 Lésch discovered the Amceba coli; in 1878 Rivolta de- scribed the Coccidium cuniculi of the rabbit; in 1879 Lewis first saw Trypanosoma lewisi in the blood of the rat; in 188: Laveran discovered Plasmodium malarie in the blood of cases of human paludism; in 1885 Blanchard described the sarcocystis in muscle- fibers; in 1893 Councilman and Lafleur studied Amceba dysenteriae in the stools and tissues of human dysentery; in 1903 Leishman .and Donovan found the little body, Leishmania donovani, in the splenic juice of cases of kala-azar, and in 1903 Dutton and Forde, working in- dependently, observed trypanosomes—the Trypanosoma gambiense of African lethargy—in the blood of human beings. That the specific micro-organisms of many of the infectious diseases remained undiscovered was a source of perplexity so long as it was supposed that all living things must be visible to the eye aided by the microscope. To-day, thanks to the invention of the ultra- microscope, that shows the existence of things too small to be defined, and still more to the adaptation of the method of filtration to the study of the diseases in question, we realize that the “viruses” of disease may be visible or invisible and that they have no limita- tions of size. Just as bacteria readily find their way through paper filters, so the invisible and hence undescribed viruses—i.e., micro- eppanians—ol yellow fever, pleuro-pneumonia of cattle, foot-and- mouth disease, rinderpest, hog-cholera, African horse-fever, infec- tious anemia or swamp sickness of horses, fowl plague, small-pox, cow-pox, sheep-pox, horse-pox, swine-pox, and goat-pox are at some or all stages able to pass through the Berkefeld or diatomaceous _ earth filters, and some of them through the much less porous unglazed porcelain or Chamberland filters. Thus there is opened a new world that is ultramicroscopic, but still teems with invisible living organisms. CHAPTER I STRUCTURE AND CLASSIFICATION OF THE MICRO-ORGANISMS BACTERIA Wuen Leeuwenhoek with his improved microscope discovered the new world of micro-organisms, he supposed them, on account: of the active movements they manifested, to be small animals, and described them as animalcule. The early systematic writers, Ehrenberg and Dujardin, fell into the same error, and it was many years before biologists had arrived at even approximate accuracy in arranging them. Indeed, for a long time a great number baffled systematic writers, and no less an authority than Haeckel, in 1878, suggested that they form a group by themselves to be known as Protista. Such a grouping, however, was unsatisfactory alike to botanists and zodlogists, and, therefore, was used by few. It was evident that structure could not be looked upon as a satisfactory differential character, for between the protozoa, or most simple animals, and the protophyta, or most simple plants, the structural differences were too minute to prevent overlapping. Motion and locomotion had to be abandoned, since it was common to both groups. Reproduction was likewise an unreliable means when taken by itself, for much the same means of multiplication were found to obtain in both groups. One great physiologic and metabolic difference was, however, noted: plants possess the power of nourishing themselves upon purely inorganic compounds, while animals are unable to do so and cannot live except upon complex molecular combinations synthesized by the plants. In this metab- olic difference we find the present criterion for the separation of the living organisms into the two main groups. But this does not dis- pose of all of the difficulties, for there are certain small groups to which it does not apply. Thus, for example, the fungi which, when judged by other criteria, are undoubted plants, lack the power of inorganic synthesis, and so resemble animals. Fortunately, the question is a purely academic one. Though seemingly at first sight a most fundamental one, it is, in reality, of trifling importance, for after a limited experience the student un- hesitatingly assigns most of the known organisms to one or the other groups, and that occasional mistakes may be made, and organisms, like the spirocheta, appear sometimes in the group of plants among the bacteria, and in other writings in the group of ani- mals among the protozoa, is a matter of small consequence so long , 26 Bacteria | as the knowledge of the organisms themselves is in no particular diminished by the method of classifying them. In discussing the matter Delage says, “The question is not so important as it appears. From one point of view and on purely _ theoretic grounds it does not exist, while from another standpoint it is insoluble. If one be asked to divide living things into two distinct groups, of which one contains only animals and the other only plants, the question is meaningless, for plants and animals are concepts which have no objective reality, and in nature they are only individuals. If in considering those forms which we regard as true animals and plants we look for their phylogenetic history and decide to place all of their allies in one or the other group, we are sure to reach no result; such attempts have always been fruitless.” “Huxley pointed out as early as 1876 the extremely close relation- ship between the lowest alge and some of the flagellates, and it is the general opinion that no one feature separates the lowest plants from the lowest animals, and the difficulty—in many cases the impossibility—of distinguishing between them is clearly recognized. “The point of view which demands a strict separation of animals and plants has, however, little utility save, perhaps, to determine the limits of a text-book or a monograph.’’* The relative position of the pathogenic vegetable micro-organisms to the other vegetable organisms can be determined by reference to the following table. The wide separation of the bacteria in Group II. and all of the others, which appear in Group X., should be noted. The various genera to which the pathogenic fungi belong are by no means closely related to one another, as can at once be seen by the following amplification of Group X. Eumycetes: No entirely satisfactory grouping of the bacteria themselves has yet been achieved, the best characters to be used as the basis of classification being undecided. The best system for their provi- sional arrangement is probably that of Migula,f or the modification of it suggested by F. D. Chester, { in which the morphology, sporula- tion, and appendages of the bacteria all enter as important features. Size.—Bacteria are so minute that a special unit has been adopted for their measurement. This is the micron, micromillimeter or u, and is the one-thousandth part of a millimeter, equivalent to the one-twenty-five-thousandth (125000) of an inch. There is no limit to the minuteness of micro-organisms. Visibility is no longer a criterion. There are micro-organisms that can be seen with low powers, others that can only be seen with high powers, and a few that probably cannot be seen with any power of * Calkins’, “The Protozoa,” p. 23. . +“System der Bakterien,” Jena, 1897-1900 (vols. 1 and 1m appearing at different times). : i { “Preliminary Arrangement of the Species of the Genus Bacterium,” “Ninth Annual Report of the Delaware College Agricultural Experiment Station,” 1897, Newark, Delaware, U. S. A. they ? They are icro-organisms bility to pass through the pores of the fication of Mi TABLE I THE PLANT KINGDOM i These are called “invisible viruses.”’ Structure and Class known to us through the biological quality of filtrates in which they filters. For this reason they are also called “‘filterable viruses. As they cannot be seen, we have no way of classifying them may be bacteria or protozoa, or neither or both. the microscope. are present because of their a 28 I. Phytosarcodina; myxothallophyta; myxomycetes (slime moulds). I. Schizophyta (cx:tew to cleave or split; gvrovy plant). Plants repro- Cryptogamia (xpumros hidden, yapos ducing by division. marriage). Plants without flowers or Class 1. Schizomycetes (Bacteria). seeds, reproducing by spores. Class 2. Schizophycee (blue-green alge). H IV. Dinoflagellata and zoologists. V. Zygophycee—conjugate alge. ; ( Alga VI. Chlorophycee—green alge. VII. Charales—Stoneworts. Thallophyta— (@add\os a young shoot, gvrov a plant). Plants with- out differentiation into| Fungi— X. Eumycetes—fungi, moulds, yeasts, smuts, rusts, mildews, etc. (See root, stem, leaf, flower, etc. Table II.) XI. Embryophyta asiphonogama. { Bryophyta (Spvov mossy seaweed, ¢gurov Archegonitea— plant). Liverworts and mosses. (&pxeyovos, the first of the | Pteridophyta (rrepis fern, ¢urov plant). race). Plantsshowinga Ferns, horse-tails, club-mosses, ground regularalternationoftwo pine, etc. generations in the life history. The asexual generation multiplies by spores. VIII. Pheophycee—brown seaweeds. IX. Rhodophycee—red seaweeds. These primary divisions, like the cor- i i division of animal $ into vertebrata and invertebrata, are responding primary now falling into disuse. Phanzrogamia (¢avepos visible, yauos XII. Embryophyta siphonogama. marriage). Plants having flowers (Gymnospermz (yrds naked, oreppa and seeds. Spermatophyte— 1 seed). Cycads, pines, spruces, cedars, (oweppaseed, guros plant). ginkos, etc. Plants with true flowers | Angiosperme (4yyefoy a tube or vessel, and true seeds. omeppa a seed). Monocotyledons.. Dicotyledons. Bacteria 29 TABLE II X. Eumycetes (ev good, wuxyros fungus). The true fungi: plants without chlorophyl. Class 1. Phycomycetes (duos seaweed), alga-like fungi. Order 1. Zygomycetes. Sub-order—Mucorinez. Family—Mucoracez. Genus—Mucor. Order 2. Odmycetes. Class 2. Hemiascomycetes. Order 1. Hemiascales. Family—Saccharomycetacee. Genus—Saccharomyces. ““ —Blastomyces (?). Class 3. Euascomycetes. [ Fungi imperfecti. Order x. Euascales (contains 45 families). | This is a large sup- Family—Aspergillacez. plementary group, of Genus—Aspergillus. imperfectly known “ —Penicillium. fungi not included in the tabulation. Class 4. Laboulbeniomycetes. In it we find Oidium. Order 1. Laboulbeniales. Class 5. Basidiomycetes. Sub-class—Hemibasidii. Order 1. Hemibasidiales. Family—Ustilaginacez (smuts). Sub-class—Eubasidii. Order 1. Protobasidiomycetes. Family—Uredineinee (rusts). Order 2. Autobasidiomycetes (mushrooms, toad-stools, etc.). CLASSIFICATION OF THE BACTERIA I, ORDER: EUBACTERIA (True Bacteria) A. SuB-oRDER: Haplobacteria (Lower Bacteria) I. Family Coccacez. Cells globular, becoming slightly elongate before division. Division in one, two, or three directions of space. Forma- tion of endospores very rare. (A) Without flagella. 1. Streptococcus. Division in one direction of space, producing chains like strings of beads. 2. Micrococcus. Division in two directions of space, so that tetrads are often formed. 3. Sarcina. Division in three directions of space, leading to the formation of bale-like packages. (B) With flagella. 1. Planococcus. Division in two directions of space, like micrococcus. 2. Planosarcina. Division in three directions, like sarcina. Il. Family Bactertace#. Cells more or less elongate, cylindric, and straight. They never form spiral windings. Division in one direction of space only, transverse to the long axis of the cell. (A) Without flagella. 1. Bacterium. Occasional endospores. (B) With flagella. 2. Bacillus. Flagella arising from any part of the surface. Endo- spore-formation common. 3. Pseudomonas. Flagella attached only at the ends of the cell. Endospores very rare. TTI. Family Sprrittacez. Cells twisted spirally like a corkscrew, or representing sections of the spiral. Division only transverse to the long diameter. 30 Structure and Classification of Micro-organisms 1. Spirosoma. Rigid; without flagella. f 2. Microspira. Rigid; having one, two, or three undulating flagella at the ends. . 3. Spirillum. Rigid; having from five to twenty curved or undulat- ing flagella at the ends. 4. Spirocheta.* Serpentine and flexible. Flagella not observed; probably swim by means of an undulating membrane. B. Sup-orpER: Trichobacteria (Higher Bacteria) IV. Family Mycopacteriacez. Cells forming long or short cylindric filaments, often clavate-cuneate or irregular in form, and at times showing true or false branchings. No endospores, but formation of gonidia-like bodies due to segmentation of the cells. No flagella. Division at right angles to the axis of rod in filament. Filaments not surrounded by a sheath as in Chlamydobacteriacee. 1. Mycobacterium. Cells in their ordinary form, short cylindric rods often bent and irregularly cuneate. At times Y-shaped forms or longer filaments with true branchings may produce short coccoid elements, perhaps gonidia. (This genus includes the Corynebacterium of Lehmann-Neumann.) No flagella. 2. Actinomyces. Cells in their ordinary form as long branched fila- ments; growth coherent, dry or crumpled. Produce gonidia- like bodies. Cultures generally have a moldy appearance, due to the development of aérial hyphe. No flagella. V. Family CHLAMYDOBACTERIACE2. Forms that vary in different stages of their development, but all characterized by a surrounding sheath about both branched and unbranched threads. Division transverse to the length of the filaments. 1. Cladothrix. Characterized by pseudo-dichotomous branchings. Division only transverse. Multiplication by the separation of whole branches. Transplantation by means of polar flagellated swarm-spores. 2. Crenothrix. Cells united to form unbranched threads which in the beginning divide transversely. Later the cells divide in all three directions of space. The products of final division become spheric, and serve as reproductive elements. 3. Phragmidiothrix. Cells at first united into unbranched threads. Divide in three directions of space. Late in the development, by the growth of certain of the cells through the delicate, closely approximated sheath, branched forms are produced. 4. Thiothrix. Umnbranched cells inclosed in a delicate sheath. Non- motile. Division in one direction of space. Cells contain sulphur grains. II. ORDER: THIOBACTERIA (Sulphur Bacteria) I. Family Brccratoaces. Cells united to form threads which are not surrounded by an inclosing sheath. The septa are scarcely visible. Divide in one direction of space only. Motility accomplished through the presence of an undulating membrane. Cells contain sulphur grains. There are two families, numerous sub-families, and thirteen genera in this order. They are all micro-organisms of the water and soil, and have no interest for the medical student. Structure.—Wucleus——When subjected to the action of nuclear stains, large vague nuclear formations are usually observed in the bacterial cells. f *The spirocheta and some closely related forms are now thought to be more properly classified among the protozoa than among the bacteria. They will, therefore, appear again in the tabulation of the protozoan organisms. } For literature upon the nucleus of the bacteria, see the lengthy paper by Douglas and Distaso (‘‘Centralbl. fiir Bakt.,” etc., I. Abt. Orig., txvi, p. 321). Bacteria 31 Cytoplasm.—The cytoplasm, of which very little exists between the large nucleus and cell-wall, is sometimes granular, as in Bacillus megatherium, and sometimes contains fine granules of chlorophyl, sulphur, fat, or pigment. Capsule-—Each cell is surrounded by a distinct cell-wall, which in some species shows the cellulose reaction with iodin. The cell-walls of certain bacteria at times undergo a peculiar gelatinous change or permit the exudation of gelatinous material from the cytoplasm, and appear surrounded by a halo or. capsule. Such capsules are seen about the pneumococcus as found in blood or sputum, Friedldnder’s bacillus, as seen in sputum, Bacillus aérogenes capsulatus in blood or tissue, and many other organisms. Friedlinder pointed out that the capsule of his pneumonia bacillus, as found in the lung tissue or in the “prune-juice”’ sputum, was very distinct, though it could not be demonstrated at all when the organ- isms grew in gelatin. Polar Granules.—By carefully staining an appropriate organism, certain peculiarities of structure can sometimes be shown. Thus, some bacilli contain distinct “polar granules” (metachromatic or Babes-Ernst granules)—rounded or oval bodies—situated at the ends of the cell. Their significance is unknown. They have been supposed to bear some relationship to the biologic activity of the organism, especially its pathogenesis, but this is uncertain, and Gauss* and Schumburgt believe that they vary with the reaction of the culture-media upon which the bacteria grow and have nothing to do with virulence. The diphtheria bacillus and the cholera spirillum stain very irregularly in fresh cultures, as if the tingeable substance were not uniformly distributed throughout the cytoplasm. Vacuolated bacteria and bacteria that will not stain, or stain very irregularly, may usually be regarded as degener- ated organisms (involution forms) which, because of plasmolysis, or solution, can no longer stain uniformly. Flagella—Many bacteria possess delicate straight or wavy filaments, called flagella, which appear to be organs of locomotion. Messeat has suggested that the bacteria be classified, according to the arrangement of the flagella, into: I. Gymnobacteria (forms without flagella). II. Trichobacteria (forms with flagella). 1. Monotricha (with a single flagellum at one end). 2. Lophotricha (with a bundle of flagella at one end). 3. Amphitricha (with a flagellum at each end). . 4. Peritricha (flagella around the body, springing from all parts of its surface). . *“Centralbl. f. Bakt.,” etc., Feb. 5, 1902,‘xxxI, No. 3, p. 106. } Ibid., June 3, 1902, xxx1, No. 14, p. 694. { “Rivista d’igiene e sanata publica,” 1890, I. 32 Structure and Classification of Micro-organisms This arrangement is, however, less satisfactory than that of Migula already given. Motility—The greater number of the bacteria supplied with flagella are actively motile, the locomotory power no doubt being the lashing flagella. The rod and spiral micro-organisms are most plentifully supplied with flagella; only a few of the spheric forms have them. The presence of flagella, however, does not invariably imply motility, as they may also serve to stimulate the passage of currents of nutrient fluid past the organism, and so favor its nutrition. The flagellate bacteria are more numerous among the saprophytic than the pathogenic forms. Bacillus megatherium has a distinct but limited ameboid move- ment. The dancing movement of some of the spheric bacteria seems to be the well- known Brownian movement, which is a physical phenomenon. It is some- - times difficult to determine whether an organism viewed under the microscope is really motile or whether it is only vibrating. One can usually determine by observing that in the latter case it does not change its relative position to surrounding objects. In some cases the colonies of actively motile bacteria, such as the proteus bacilli, show definite migratory tendencies upon 5 per cent. gelatin. The active movement of the bacteria composing the colony causes its shape constantly to change, so that it bears a faint resemblance to an ameba, and moves about from place to place upon the surface of the gelatin. Reproduction.—Fission.—Bacteria multiply by binary division (fission). A bacterium about to divide appears larger than normal, and, if a spheric organism, more or less ovoid. By appropriate staining karyokinetic changes: may be observed in the nuclei. When the conditions of nutrition are good, fission progresses with astonishing rapidity. Buchner and others have determined the length of a generation to be from fifteen to forty minutes. The results of binary division, if rapidly repeated, are almost appalling. ‘Cohn calculated that a single germ could produce by simple fission two of its kind in an hour; in the second hour these would be multiplied to four, and in three days they would, if their surroundings were ideally favorable, form a mass which can scarcely be reckoned in numbers.” ‘Fortunately for us,” says Woodhead, “they can seldom get food enough to carry on this appalling rate of development, and a great number die both for want of food and because of the presence of other conditions unfavorable to their existence.” Sporulation.—When the conditions for rapid multiplication by fission are no longer good, many of the organisms guard against extinction by the formation of spores. Endospores, or spores developed within the cells, are generally Bacteria 33 formed in the elongated bacteria—bacillus and spirillum—but Zopf has observed similar bodies in micrococci. Escherich also claims to have found undoubted spores in a sarcina. Spores may be either round or oval. As a rule, each organism produces a single spore, which is situated either at its center or at its end. When, as sometimes happens, the diameter of the spore is greater than that of the bacillus, it causes a peculiar barrel shape bulging of the organism, described as clostridium. When the dis- tending spore is at the end, a “‘Trommelschlager,” or ‘“drum- stick,” is formed. End-spores are almost characteristic of anaerobic bacilli. When the formation of a spore is about to commence, a small bright point appears in the cytoplasm, and increases in size until its diameter is nearly or quite as great as that of the bacterium. A dark, highly refracting capsule is finally formed about it. As soon as the spore arrives at perfection the bacterium seems to die, as if its vitality were exhausted. The spores differ from the bacteria in that their capsules prevent evaporation and enable them to withstand drying and the applica- tion of a considerable degree of heat. Very few adult bacteria are able to resist temperatures above 70°C. Spores are, however, a b c d € i cs> 5) 4 Qo cé> ee Fig. 1.—Diagram illustrating sporulation: a, Bacillus inclosing a small oval spore; b, drumstick bacillus, with the spore at the end; ¢, clostridium; d, free spores; e and f, bacilli escaping from spores. uninjured by such temperatures, and can even successfully resist the temperature of boiling water (100°C.) for a short time. The extreme desiccation caused by a protracted exposure to a dry temperature of 150°C. will invariably destroy them, as will also steam under pressure. Not only can the spores successfully resist a considerable degree of heat, but they are also unaffected by cold of almost any intensity. Von Szekely* found anthrax spores capable of germination after eighteen years and six months in some dried-up old gelatin cultures found in his laboratory. Arthrospores.—The formation of arthrospores is less clear, and seems to be the conversion of the entire organism into a spore or. permanent form. Arthrospores have been observed particularly among the micrococci, where certain individuals become enlarged beyond the normal, and surrounded by a capsule. Though the cell-wall of the adult bacterium is easily penetrated by solutions of the anilin dyes, it is difficult to stain spores, which are distinctly more resistant to the action of chemic agents than the bacteria themselves. * “Zeitschr. fiir Hygiene,” 1903, XLIV, 3. 34 Structure and Classification of Micro-organisms Germination of Spores.—When a spore is about to germinate, the contents, which have been clear and transparent, become granular, the body increases slightly in size, the capsule becomes less distinct, and in the course of time splits open to allow the escape of a young organism. The direction in which the capsule ruptures varies in different species. Bacillus subtilis escapes from the side of the spore; Bacillus anthracis from the end. This difference can be made use of as an aid in differentiating otherwise similar organisms. So soon as the young bacillus escapes it begins to increase In size, develops a characteristic capsule, and presently begins the propaga- tion of its species by fission. Morphology.—The three principal forms of bacteria are spheres (cocci), rods (bacilli), and screws (spirilla). Cocci.—The spheric bacteria, from a fancied resemblance to little berries, are called cocci or micrococci. When they divide, and the resulting organisms remain attached to one another, a a b e se g h o oO @ @ Fig. 2.—Diagram illustrating the morphology of the cocci: @, Coccus or micrococcus; , diplococcus; ¢, d, streptococci; e, f, tetracocci or merismopedia; g, k, modes of division of cocci; i, sarcina; j, coccus with flagella; %, staphylococci. diplococcus is produced. Diplococci may consist of two attached spheres, though each half commonly shows flattening of the con- tiguous surfaces. In a few cases, as the gonococcus, the approxi- mated surfaces may be slightly concave, causing the organism to resemble the German biscuit called a ‘‘Semmel.” When a second binary division occurs, and four resulting individuals remain at- tached to one another, without disturbing the arrangement of the _first two, a tetrad, or éefracoccus, is formed. To the entire groups of cocci dividing in two directions of space so as to produce fours, eights, twelves, etc., on the same plane, the name merismopedia has - been given. Migula uses the term micrococcus for the unflagellated tetrads, and planococcus for the flagellated forms. If division takes place in three directions of space, so as to pro- duce a cubic “package” of cocci, the resulting aggregation is described as asarcina. This form resembles a dice or a miniature bale of cotton. Few sarcine have flagella, similar flagellated organisms being called by Migula planosarcina. If division always take place in the same direction, so that the Bacteria 35 cocci remain attached to one another like a string of beads, the organism is described as a streptococcus. Cocci commonly occur in irregular groups having a, fancied re- semblance to bunches of grapes. Such are called staphylococci, and most organisms not finding a place in the varieties already described are so classed. Cocci associated in globular or lobulated clusters, incased in a resisting gelatinous, homogeneous mass have been described by Billroth as ascococcus. Cocci solitary or in chains, surrounded by an incasement of almost cartilaginous consistence, have been called leuconostoc. a b ¢ d e ° ~e Of ») & ae OS Fig. 3.—Diagram illustrating the morphology of the bacilli: a, 6, c, Various forms of bacilli} d, e, bacilli with flagella; f, chain of bacilli, individuals distinct; g, chain of bacilli, individuals not separated. Bacilli.—Better known, if not more important, bacteria consist of elongate or ‘‘rod-shaped forms,” and bear the name bacillus (a rod). These present considerable variation of form. Some are ellipsoid, some long and slender. Some have rounded ends, as Bacillus subtilis; others have square ends, as B. anthracis. Some are large, some exceedingly small. Some always occur singly, never uniting to form threads or chains; others are nearly always so conjoined. The bacilli divide by transverse fission only, so that the only peculiarity of arrangement is the formation of threads or chains. In the older writings, short, stout bacilli were described under the generic term bacterium. Migula now employs the term to include only bacillary forms without flagella. A pseudomonas is a bacillary a b € ~~ ew OM Fig. 4.—Diagram illustrating the morphology of the spirilla: a, 6, c, Spirilla. form with polar flagella. Some of the flexile bacilli have sinuous movements resembling the swimming of a snake or an eel, and are sometimes described as vibrio; but this name also has passed into disuse, except in France. Spirilla—If a rod- shaped bacterium ' ‘is spirally twisted and re- sembles a corkscrew, it is called spirillum. The rigid forms without flagella are known as spirosoma; rigid forms with flagella, spiridla and microspira. 36 Structure and Classification of Micro-organisms A spiral organism of ribbon shape is called spiromonas, while a similar oganism of spindle shape is called a spirulina. One species of spiral bacteria in whose cytoplasm sulphur granules have been detected has been called ophidiomonas. Spiral organisms with undulating membranes are known as spirocheta, but these and the similar genus /reponema are now regarded as more correctly placed among the protozoan organisms. THE HIGHER BACTERIA The Higher Bacteria form a group intermediate between the Schizomycetes, or true bacteria, and the Hyphomycetes, or molds. In the classification of Migula and Chester they include the Myco- » ») / kb fy oe 2 a Oe - see Si oa he te Fig. 5.—Cladothrix, showing false branching. (From Hiss and Zinsser, “Text-Book of Bacteriology,’ D. Appleton & Co., publishers.) bacteriacez and the Chlamydobacteriacee. Some, like Petruschky, believe them to be more closely related to the true molds than to the bacteria. They are characterized by filamentous forms with real or apparent branchings. The filaments are usually regularly divided transversely, so as to appear as if composed of bacilli. The free ends only seem to be endowed with reproductive functions, and develop peculiar elements that differentiate the higher from the other bacteria whose cells are all equally free and independent. Leptothrix.—These comprise long threads which do not branch. They are not always easily separated from chains of bacilli. They rarely appear to play a pathogenic réle, though those inhabiting the mouth occasionally secure a foothold upon the edges of the tonsillar crypts, where they grow, with the formation of persistent white patches. This form of leptothrix mycosis is chronic and diffi- The Higher Bacteria 37 cult to treat. The leptothrix is a very difficult organism to secure in culture. The attempts of Vignal* and of Arustamoff' were successful, but upon the usual culture-media the organisms grew very sparingly. Cladothrix.—These also produce long thread-like filaments, but they occasionally show what is described as false branching; that is, branches seem to originate from the threads, but no distinct connec- tion between the thread and the apparent branch obtains. None of the cladothrices is known to be pathogenic. They are frequent organisms of the atmospheric dust, and not infrequently appear as “weeds” in culture-media. The colonies grow to about a centi- meter in diameter, are usually white in color, irregularly rounded, Fig. 6.—Streptothrix enteola. Film preparation from peptone-beef-broth culture, fourteen days at 37°C. X 1000. (Foulerton.) sharp at the edges, more or Jess concentric, dry and powdery (not velvety) or scaly on the surface. They commonly liquefy gelatin and blood-serum. Streptothrix.—These organisms certainly branch. They also form endospores. Many of them can be cultivated. Not a few are found under circumstances suggesting pathogenic action. Fora long time there has been a disposition to regard Bacillus tuberculosis as a form of streptothrix, since old cultures show branching involution forms. The old genus actinomyces is also included by a number of writers among the streptothrices, so that the Actinomyces bovis of Bollinger is called Streptothrix actinomyces, the Actinomyces madure, Streptothrix madure, and the organism found by Nocard in the disease known as “‘farcin du beuf,’ Streptothrix farcinica. *“ Annales de physiologie,” 1886. ; . . t“Kolle and Wassermann, “Handbuch der Pathogenen Mikroorganismen, 1903, 11, p. 851; Wratsch, 1880. 38 Structure and Classification of Micro-organisms There seems, however, no adequate ground for this arrangement, and the old genus Actinomyces should be kept. Eppinger found a streptothrix in the pus of a cerebral abscess, and Petruschky, Berestneff, Flexner, Norris, and Larkin have found streptothrices in cases of pulmonary disease simulating tuberculosis. The organisms described by these writers were not identical, so that there are prob- ably several different species. They usually grow well upon ordinary media and upon solid media form whitish, glistening, well- circumscribed colonies attaining a diameter of several millimeters. As they grow old they turn yellowish or brownish. They liquefy gelatin. Some of the cultures were not harmful to the laboratory animals, others caused suppuration. Actinomyces.—The chief characterization of the organisms of this group is a clavate expansion of the terminal ends of radiating fila- ments. These are seen in sections of diseased tissues containing the organisms, but rarely are well shown in the artificial cultures. For further particulars of these organisms see Actinomyces bovis, etc. THE YEASTS, OR BLASTOMYCETES The organisms of this group are sharply separated from the bacteria by their larger size, elliptic form, and by multiplication by gemmation or budding. Fig. 7.—Blastomycetes dermatitidis. Budding forms and mycelial growth from glucose agar. (Irons and Graham, in “Journal of Infectious Diseases’’.) Each organism is surrounded by a sharply defined, doubly contoured, highly refracting, transparent cellulose envelope. Com-— monly each cell contains one or more distinct vacuoles. When multiplication is in progress, smaller and larger buds are formed. The Oidia 39 The yeasts, of which Saccharomyces cerevisiae may be taken as: the type, are active fermentative organisms, quickly splitting the sugars into CO: and alcohol, and are largely cultivated and used in the manufacture of fermented liquors and bread. They grow well in fermentable culture-media and most of them also grow upon the ordinary laboratory culture-media. Many varieties, some of which produce red or black pigment, some no pigment at all, are known. They play very little part in. the pathogenic processes. Burse has observed a case of generalized fatal infection caused by an yeast that he calls Saccharomyces hominis. Gilchrist, Curtis, Ophiils, and others have seen localized human infections by blasto- mycetes. (See Blastomycetic dermatitis.) THE OIDIA These organisms seem to occupy a place intermediate between the yeasts and the molds—the blastomycetes and the hyphomycetes. In certain stages they appear as oval cells which multiply by gem- Fig. 8.—Oidium, showing the various vegetative and reproductive elements. X 350. (Grawitz.) mation, but instead of becoming separated, hang together. At a later stage of development they grow into long filamentous forma- tions suggesting the mycelia of molds, but being less regular. Certain cells also develop as reproductive organs. They are common micro-organisms of the air and appear as frequent causes of contamination in culture-media, upon all forms of which they grow readily, producing liquefaction where possible. They engage in but few pathogenic processes, the most familiar being that brought about by Oidium albicans, which causes the common disease of childhood known as thrush (g. 2.). 40 Structure and Classification of Micro-organisms THE MOLDS In this group it is customary to place a miscellaneous collection of organisms having in common the formation of a well-marked Fig. 9.—Oidium. (Kolle and Wassermann.) mycelium, but being so diversified in other respects as to place them in widely separated groups in the systematic arrangement of the en Gs apy Rael ren cas, Fig. 1o—Mucor mucedo: 1, A sporangium in optical longitudinal section; c, columella; m, wall of sporangium; sf, spores; 2, a ruptured sporangium with only the columella (c) and a small portion of the wall (m) remaining; 3, two smaller sporangia with only a few spores and no columella; 4, germinating - spores; 5, ruptured sporangium of Mucor mucilaginus with deliquescing wall (m) and swollen interstitial substance (z); sp, spores. (After Brefeld.) fungi. Some are correctly placed among the “Imperfect fungi,” some among the Ascomycetes, and some among the Phycomy- The Molds AI cetes. They are all active enzymic agents and produce fer- mentative and putrefactive changes. 1. Achorion.—The organisms of this genus are characterized by a more or less branched hypha, 3 to sy in diameter, which break up after a time into rounded or cuboidal spores. The Achorion schénleini is highly pathogenic and will be described in the section upon Favus. 2. Tricophyton and Microsporon.—These names are applied some- what loosely to organisms affecting skin and hair follicles of men and animals. They form tangled slender mycelia with many spores of varying size. They occasion “ringworm,” barber’s itch, pityriasis, and tinea. Further description of the organisms will be found in the section upon Ringworm. Fig. 11.—Mucor mucedo. Single-celled mycelium with three hyphe and one developed sporangium. (After Kny, from Tavel.) 3. Mucor.—The mucors, or ‘‘black molds,” belong to the phyco- mycetes. They form a thick, tangled mycelium, in and above which the rounded black sporangia can be seen with the naked eye. The mycelium becomes divided at the time of reproduction. Miultiplica- tion takes place asexually through conidia-spores which develop within sporangia, and sexually by the conjugation of specialized terminal septate branches of the mycelium, which conjugate with similar cells, belonging to other colonies, to form zygospores. The sporangia form upon the ends of aérial hypha and consist of a smooth spherical capsule within which the spores develop, to become liberated only when the membrane ruptures. The colonies, each of which is unisexual, may be described as + and —. Colonies of the + type will not conjugate; colonies of the — type will not conj ugate, but when terminal filaments of + and — come together, conjuga- tion occurs and zygospore formation takes place. 42 Structure and Classification of Micro-organisms Mucors are not infrequent organisms of the atmosphere and occasionally appear as contaminations upon solid culture-media. About 130 species are known. Of these, Mucor corymbifer, Mucor rhizopodiformis, Mucor ramosus, Mucor pusillus, Mucor septatus, and Mucor conoides are said by Plaut* to be pathogenic when introduced into laboratory animals. Mucor corymbifer has been known to produce inflammation of the external auditory meatus in man.{ General mucor mycosis in man has also been observed by Paltauft to result from the presence of the same organism. 4. Aspergillus and Eurotium—tThe organisms of this genus are included among the Ascomycetes. They are common organisms of Fig. 12.—Mucor mucedo. Different stages in the formation and germination of the zygospore: 1, Two conjugating branches in contact; 2, septation of the conjugating cells (a) from the suspensors (b); 3, more advanced stage in the development of the conjugating cells (a); 4, ripe zygospore (b) between the suspensors (a); 5, germinating zygospore with a germ-tube bearing a sporangium. (After Brefeld.) the air and frequent contaminations of solid culture-media. To secure them an agar-agar plate can, be exposed to the atmosphere of the laboratory for a short time, then covered and stood aside for a day or two, when tangled mycelial growths with rapidly spreading hyphe will usually be discovered. The recognition is easily made when the sporangia appear. These are well shown in the accom- panying illustration. The mycelium is divided into many cells. Reproduction is asexual and takes place through conidia spores. The fruit hyphe, which are aérial, terminate in rounded extremities which are known as columella, from which many radiating sterig- mata arise, each terminating in a series of rounded spores. A sexual * Kolle and Wassermann, “Die Pathogenen Mikroorganismen,” 1903, 1, 552 } Hiickel-Lésch in Fliigge, “‘Die Mikroorganismen.” Ibid. The Molds 43 form of reproduction also takes place through the production of ascospores. Many species are known, only a few of which are pathogenic. Aspergillus malignum has been found by von Lindt in the auditory meatus of man. Aspergillus nidulans occasionally infects cattle. It is pathogenic for laboratory animals, usually causing death in sixty hours. The kidneys are found enlarged to twice their normal size, and show small whitish dots and stripes of cell infiltration containing the fungi. Fig. 13.—Aspergillus glaucus: A, A portion of the mycelium m, with a con- idiaphore c, and a young perithrecium F, magnified 190 diameters; B and B’, conidiaphore with conidia; B, individual sterigma greatly magnified; C, early stage of the development of the fructifying organ; D, young perithrecium in longitudinal section; w, the future wall of the contents; as, the screw, magnified 250 diameters; E, an ascus with spores from a perithrecium, magnified 600 diameters. (duBary.) The heart muscle, diaphragm, and spleen may also be involved. The liver usually escapes. It takes a large number of spores to infect. ‘ Aspergillus fumigatus —This is a widespread and not infrequently pathogenic form. Its most common lesion is a pneumomycosis, in which the lung is riddled with small inflammatory necrotic and cavernous areas containing the molds. The same condition has occasionally been observed in human beings, Sticker having collected 39 cases.* Leber and others have observed keratitis following corneal infec- tion by this organism. Aspergillus flavus is also pathogenic. * Nothnagel’s Spezielle Path. u. Therap., xIv, 1900. 44 Structure and Classification of Micro-organisms Aspergillus subfuscus is also pathogenic and highly virulent. ; Aspergillus niger —Pathogenic and found at times in inflammation of the external auditory meatus. ; 5. Penicillium.—These are common green molds, widely dis- seminated throughout the atmosphere and frequent sources of contamination of the culture-media in the laboratory. Moist bread exposed to the atmosphere soon becomes covered with them. They are included in the group of fungi imperfecti, and are characterized by a luxuriant tangled septate mycelium, with aérial fruit hyphe, ending in conidiophores, each of which divides into two or three sterigmata, the tip of which forms a chain of rounded spores. The whole germinal organ thus comes to resemble a whisk-broom or, as Hiss describes it, a skeleton hand, in which the conidiophore cor- responds to the wrist; the sterigmata, to the metacarpal bones; the chains of spores, to the phalanges. None of the penicillia is known to be pathogenic either for man or animals. Penicillium crustaceum (glaucum) is the most common source of contamination of the laboratory media. Penicillium minimum, which may be identical with the preceding, was once found in the human ear by Sievenmann. THE PROTOZOA The protozoa are unicellular animal organisms as differentiated from the metazoa which are multicellular animal organisms. The restriction, implied by the term unicellular is, however, too narrow, for there are colonial protozoa that consist of many cells, yet share other protozoan characters. . For the purposes of this work, however, all protozoa are to be re- garded as unicellular and the individuals independent of one another. Classification.—Many schemes have been devised for systematic- ally arranging the protozoa, that which follows being an abbrevia- tion of the standard classification, made to correspond with the requirements of this work that deals only with the pathogenic forms. The Protozoa 45 CLASSIFICATION OF THE PATHOGENIC PROTOZOA Phylum PROTOZOA (pros first, fwor animal). Unicellular animal organisms. Class Rhizopoda (Alfa root, rwdos foot). Having soft plasmic bodies with or without external protecting shells. The contour subject to change through the formation of extensions known as pseudopods. These may be blunt, rounded, or lobose, filamentous, or anastomosing. The nutrition is holozoic or holophytic. Order GYMNAMG@BA (yuuvds naked). Rhizopoda without external shells or coverings. Genus Amceba (ayol8a to change). Genus Entamoeba. Genus Chlamydophrys. Genus Leydenia. Class Mastigophora (nacryos waips, ¢épos to bear). Organisms of well-defined form, naked or surrounded by a well-defined membrane. Nutrition is holozoic, holophytic, parasitic, or saprophytic. Mouth, contractile vesicle, and nucleus usually present. Order FLaGELiata (Latin, flagellare, to beat). Small organisms with a well-defined mononucleate body, at the anterior end or both ends of which are one or more flagella. Actively motile. May become encysted. Nutrition is holozoic, holophytic, parasitic, or saprophytic. Family Cercomonide. Body pyriform with several anterior flagella and an undulating membrane. Genus Cercomonas. Genus Trichomonas. Genus Monas. Genus Plagiomonas. Family Lambliade. Body pyriform, very much attenuated behind. Ventral surface shows a reniform depression, about the posterior part of which there are six flagella. There are also two flagella at the posterior extremity. Genus Lamblia (Megastomum). Family Trypanosomide. Body delicately fusiform. Contains a nucleus, a blepf.aroplast or centrosome, and an undulating mem- brane. A single wavy flagellum arises in the posterior part of the body close to the centrosome, passes along the edge of the undulating membrane to the anterior extremity, where it continues free for some distance. Nutrition parasitic. Reproduces by division. Genus Trypanosoma. Genus Leishmania. Genus Babesia. Family Spirochetide. Organisms very long and spirally twisted. Nucleus indistinct. Multiplication probably by longitudinal division only. Nutrition is parasitic or saprophytic. Genus Spirocheta. Body flattened, with a very narrow undulating membrane. Genus Treponema. - Body not flattened. No undulating membrane. Extremities sharp pointed and terminating in short flagella. Class Sporozoa (omépos a spore, {wov an animal). Organisms unprovided with cilia or flagella in the adult stage. Always endoparasites in the cells, tissues, or cavities of other animals. Nutrition is parasitic and osmotic. Reproduction always by spore-formation, the sporozoites either being produced by the parent or indirectly from spores, into which the parent divides. Subclass Telosporidia. Spore-formation ends the individual life, the entire organism being transformed to spores. Order GREGARINIDA. Possess distinct membrane with myonemes during adult life; locomotion mainly by contraction. Young stages alone (cephalonts) are intracellular parasites, the adults (sporonts) being found in the digestive tract or the body cavities. Sporulation takes place after or without conjugation, but within a cyst that is never formed, while the parasite is intracellular. 46 Structure and Classification of Micro-organisms Order Coccrpimpa. Spherical or ovoid in form, without a free and motile ‘adult stage. Never ameboid. Sporulation takes place within cysts formed while the organism is an intracellular parasite. ° Genus Coccidium. Genus Eimeria. Order HzMmosporipiipa. Sporozoa of small size living in the blood- corpuscles or plasma of vertebrates. The adult form is mobile and in some cases provided with myonemes. Reproduction by endogenous or asexual sporulation, while in the host or by ex- ogenous sporulation after conjugation. Genus Plasmodium. Subclass Neosporidia. Organisms that form sparoeyats throughout life, the entire cell not being used up in the formation of the spores. Order Sarcosporip1A. The initial stage of the life history is passed in the muscle cells of vertebrates. Form is elongate, tubular, oval, or even spherical. Cysts have a double membrane, in which reniform or falciform sporozoites are formed. Genus Sarcocystis. Genus Miescheria. Genus Balbiania. Subclass Haplosporidia. Spores provided with large round nuclei. No polar capsules. Genus Rhinosporidium. Class Infusoria (Latin, infusus, to pour into. The organisms were given this name because they were first found in infusions exposed to the air). Protozoa in which the motor apparatus is in the form of cilia, either simple or united into membranes, membranelles, or cirri. The cilia may be permanent or limited to the embryonic stages. There are two kinds of nuclei, macronucleus and micronucleus. Reproduc- tion is effected by simple transverse division or by budding. Nutrition is holozoic or parasitic. Subclass Ciliata. Mouth and anus usually present. The contractile vacuole often connected with a complicated system of canals. Order Hoxorricuipa. The cilia are similar and distributed all over the body, with a tendency to lengthen at the mouth. Trichocysts are always present, either over the whole body or in special regions. Genus Colpoda. Genus Chilodon. / Order HrTERoTricHipa. Organisms possessing a uniform covering of cilia over the entire body, and an adoral zone consisting of short cilia fused together into membranelles. Suborder Polytrichina. Uniform covering of cilia. Family Bursaridz. The body is usually short and pocketlike, but may be elongated. The chief characteristic is the peristome, which is not a furrow, but a broad triangular area deeply insunk, and ending in a point at the mouth. The adoral zone is usually confined to the left peristome edge or it may cross over to the Bight anterior ede, Genus Balantidium. Structure.—From the table it will at once be evident that the protozoa form an extremely varied group, and that no kind of descriptive treatment can be looked upon as adequate that does not consider individuals. Cytoplasm.—In some of the smaller protozoa, and in certain stages of others, the cytoplasm appears almost hyaline and structureless. In most cases, however, it appears granular, and in the larger organ- isms, such as ameba, it presents the appearance which some described as oranular, others, as frothy. The accepted theory of structure teaches that the protoplasm is honeycombed or frothy, and that it is The Protozoa 47 filled with endless chambers in which its enzymes and other active substances, etc., are stored up and its functions carried on. In addition to these chambers, which are minute and of uniform size, there are larger spaces called vacuoles, some of which are the result of temporary conditions—accumulations of digested but not yet assimilated food, etc.; but others, seen in ameba and in the ciliata, are large, permanent, and characterized by rhythmical contractions through which they disappear from one part of the body substance to appear in another. These are known as “‘con- tractile vacuoles,” and are supposed to subserve the useful purpose of assisting in maintaining cytoplasmic currents and so distributing the nourishing juices. The cytoplasm also contains remnants of undigested or indigest- ible foods which constitute the paraplasm or deuteroplasm. In a Fig. 15.—Internal parasites: A, Amoeba coli, Liésch; B, Monocystis agilis, Leuck., a gregarine; C, Megastoma entericum, Grassi, a flagellate; D, Balantidium coli, Ehr., a ciliate. ‘ few cases granules of chlorophy! are also to be found in organisms otherwise resembling animals too closely to be confused with plants. The cytoplasm may be soft and uniform in quality, or there may be a surface differentiation into ectosarc, or body covering, and endosarc, body substance. In the rhizopoda there is little difference between the two, though certain fresh-water ameba cover themselves with minute grains of mineral substance, but in most of the masti- gophora and infusoria corticata the ectosarc is characterized by a peculiar rigidity that gives the animal a definite and permanent - form. From the surface covering or ectosarc coarse threads or fine hair-like appendages—flagella and cilia—often project. In many of the infusoria the ectosarc contains trichocysts from which nettling or stinging threads are thrown out when the organisms are irritated. The body substance may show no morphologic differentiation in thizopoda, but in the corticata there may not only be a permanent 48 Structure and Classification of Micro-organisms form, but there may be adaptations, such as an oral aperture, some- times infundibuJar in shape and communicating with the soft endosarc through a blind tube. An anal aperture may also be present. In the higher infusoria the ectosarc may also be continued pos- teriorly to form a stalk, by which the organism attaches itself (Vorticella). Such stalks are contractile. Nucleus—In certain protozoa of very simple and indefinite structure—spirocheta and treponema—no distinct well-contoured nucleus can be observed. In the rhizopoda the nucleus is a distinct organ surrounded by a nuclear membrane and containing the usual chromatin and linin. The greater number of mastigophora possess two distinct bodies, either a nucleus and a centrosome or a major and minor nucleus. This is well shown in trypanosoma. The infusoria vary greatly in the character of the nuclei. Asa rule, there are two indefinite nuclei, the macronucleus and the micronucleus. Both seem to be essential organs, and in the phe- nomena supervening upon conjugation both participate. The nuclei of the protozoa are, therefore, extremely diversified, and vary from the most simple collections of granules of nuclear sub- stance to large well-formed fantastically shaped composite organs. Movement.—Some kind of movement is to be observed at some period in the life of almost every protozoan. In rhizopoda with the soft ectosarc the movement consists of flowing currents by which lobose projections of the body substance appear now here, now there, in the form of pseudopodia, or else a continuous flowing, by which the upper surface continually coming forward in a thin layer coincides with the progress of the animal, which continually rolls over and over as it were. In mastigophora the movement of the more rigid bodies is effected through the presence of longer or shorter, flexile or rigid, coarse threads or “whips.” These usually project anteriorly—trypano- soma—and by means of.a spiral movement draw the cell along with a propeller-like action; symmetrically arranged flagella may operate more like oars. The sporozoa usually manifest very little movement, yet their sporozoites are motile, and the spermatozoites are also motile and commonly flagellated. The infusoria are actively motile through abundant fine hair-like formations known as cilia. These, multitudinous as they are, vibrate synchronously with an oar-like movement, propelling the organisms forward or backward or making them revolve with great rapidity. Independent cilia not infrequently encircle the oral aperture, causing a vortex, in which the minute structures upon which the creatures feed are caught and carried into the body. Size-—The protozoa show very great variation in size. Some of The Protozoa 49 the sporozoa form minute parasites of the red blood-corpuscles or other cells of the vertebrates. The treponema is so small that it can slowly find its way through the pores of a Berkefeld filter. On the other hand, the sarcoporidium is so large that one of its cysts, composed of a single organism, can be seen with the naked eye. Certain protozoa that play no part in morbid processes— myxosporidia—and so do not come within the scope of this work, may be several centimeters in diameter. Reproduction.—The reproduction of the protozoa takes place both asexually and sexually. It may be that there are no strictly asexual protozoa, nearly all forms having been shown upon intimate ac- quaintance to be subject to occasional conjugation. Conjugation may result in the loss of individual identity or the conjugated individuals may again separate. Whether the reproduction takes place asexually without con- jugation or sexually after conjugation, it always occurs by division, which may be simple and binary or complex and multiple. Wherever a distinct nucleus can be found, the multiplication of the protozoa is preceded by some kind of mitotic change. The more complex the structure of the nucleus, the more complicated and perfect the mitosis. The elongate protozoa divide lengthwise, which is sometimes _ contrary to expectation, as in the cases of treponema and spirocheta. The multitudinous sporozoites into which the zygotes of the sporozoa divide are commonly the result of anterior division into intermediate bodies known as odcysts, odkinetes, sporocysts, etc. The nuclear substance is first divided so as to be uniformly dis- tributed among these, then further divided so that some of it reaches each sporozoite. In the process of sporulation the entire parent may be used up, as in the coccidium and plasmodium or the parent may continue to live and later form additional sporozoites, as in sarcocystis. Encystment—Nearly all of the protozoa are capable at times of encysting themselves, i.e, surrounding themselves with dense capsules by which life may be preserved for some time amid such unfavorable surroundings as excessive cold, excessive dryness, and absence of food. Sometimes the encysted stage is the spore stage (coccidium), sometimes it is the adult stage (ameba).. Under these circumstances we find an analogy with the sporulation of the bacteria which is not for purposes of multiplication, but for self- preservation. The encysted protozoa are less hardy, however, than the bacterial and other plant spores, and succumb to comparatively slight elevations of temperature. 4 CHAPTER II BIOLOGY OF MICRO-ORGANISMS Tue distribution of micro-organisms is well-nigh universal. They and their spores pervade the atmosphere we breathe, the water we drink, the food we eat, and luxuriate in the soil beneath our feet. They are not, however, ubiquitous, but correspond in distribution with that of the matter upon which they live and the conditions they can endure. Tyndall* found the atmosphere of high Alpine altitudes free from them, and likewise that the glacier ice contained none; but wherever man, animals, or plants live, die, and decom- pose, they are sure to be. ; Their presence in the air generally depends upon their previous existence in the soil, its pulverization, and distribution by currents of the atmosphere. Koch has shown that the upper stratum of the soil is exceedingly rich in bacteria, but that their numbers decrease as the soil is penetrated, until below a depth of one meter there are very few. Remembering that micro-organisms live chiefly upon organic matter, this is readily understandable, as most of the organic matter is upon the surface of the soil. Where, as in the case of porous soil or the presence of cesspools and dung-heaps, the de- composing materials are allowed to penetrate to a considerable depth, micro-organisms may occur much farther below the surface; yet they are rarely found at any great depth, because the majority of them require free oxygen for successful existence. The water of stagnant pools always teems with micro-organisms; that of deep wells rarely contains many unless it is polluted from the surface of the earth. It has been suggested by Soyka that currents of air passing over the surface of liquids might take up organisms, but, although he seemed to show it experimentally, it is not generally believed. Where bacteria are growing in colonies they seem to remain un- disturbed by currents of air unless the surface of the colony becomes roughened or broken. Most of the organisms carried about by the air are what are called saprophytes, and are harmless. Oxygen.—As all micro-organisms must have oxygen in order to live, the greater number of them grow best when freely exposed to the air. Some will not grow at all where uncombined oxygen is present, but secure all they need by severing it from its chemic combinations. These peculiarities divide bacteria into the * “Floating Matter in the Air.” 50 Conditions Prejudicial to Growth of Bacteria 51 Aérobes, which grow in the presence of uncombined oxygen, and Anaérobes, which do not grow in the presence of uncombined oxygen. As, however, some of the aérobic forms grow almost as well with- out free oxygen as with it, they are known as optional (facultative) anaérobes. ; ‘ As examples of strictly aérobic bacteria Bacillus subtilis, Bacillus aérophilus, Bacillus tuberculosis, and Bacillus diphtherie may be given. These will not grow if oxygen is denied them. The cocci of suppuration, the bacillus of typhoid fever, and the spirillum of cholera grow almost equally well with or without free oxygen, and hence belong to the optional anaérobes. The bacilli of tetanus and of malignant edema and the non-pathogenic Bacillus butyricus, Bacillus muscoides, and Bacillus polypiformis, will not develop at all where any free oxygen is present, and hence are strictly anaérobic: The higher bacteria, oidia, molds and protozoa, are for the most part aérobesand optional anaérobes. Treponema pallidum seems to be a strictly anaérobic protozoan. Food.—The bacteria grow best where diffusible albumins are present, the ammonium salts being less fitted to support them than their organic compounds. Proskauer and Beck* have succeeded in growing the tubercle bacillus in a mixture containing ammonium carbonate 0.35 per cent., potassium phosphate 0.15 per cent., mag- nesium sulphate o.25 per cent., and glycerin 1.5 per cent. Some of the water microbes can live in distilled water to which the smallest amount of organic matter has been added; others require so con- centrated a medium that only blood-serum can be used for their cultivation. The statement that certain forms of bacteria can flourish in clean distilled water seems to be untrue, as in this medium the organisms soon die and disintegrate. If, however, in making the transfer, a drop of culture material is carried into the water with the bacteria, the distilled water ceases to be such, and becomes a diluted bouillon fitted to support bacterial life for a time. Sometimes a species witha preference fora particular culture medium can gradually be accustomed to another, though immediate trans- plantation causes the death of the organism. Sometimes the addi- tion of such substances as glucose and glycerin has a peculiarly favorable influence, the latter, for example, enabling the tubercle bacillus to grow upon agar-agar. The yeasts grow best upon media containing sugars, but can also be cultivated upon media containing diffusible protein and non- fermentable carbohydrates and glycerin. The molds flourish upon almost all kinds of organic matter, but perhaps attain their most rapid development upon media containing fermentable carbohydrates. * “Zeitschrift fiir Hygiene,” etc., Aug. 10, 1894, vol. xv, No. 1. 52 Biology of Micro-organisms _ The saprophytic and parasitic protozoa live by osmosis and absorb through the ectosarc such substances as are capable of assimilation and nutrition. These forms are cultivable only upon media con- taining the same or approximately the same proteins as those to which they have been accustomed. ‘Thus, to cultivate trypanosoma, blood-serum must be added to the media. The larger protozoa live upon smaller animal and vegetable organ- isms, which they ingest entire. Such can only be artificially culti- vated provided the attempt be made under conditions of symbiosis with some other and smaller organism that may constitute the food. Moisture.—A certain amount of water is indispensable to the growth of bacteria. The amount can be exceedingly small, however, Bacillus prodigiosus being able to develop successfully upon crackers and dried bread. Artificial culture-media should not be too con- centrated; at least 80 per cent. of water should be present. The molds and oidia grow well upon bread that contains very little moisture. Protozoa usually require fluid media. Pond-water protozoa can only grow in water, not in concentrated culture-media. Reaction.—Should the pabulum supplied contain an excess of either alkali or acid, the growth of the micro-organisms is inhibited. Most true bacteria grow best in a neutral or feebly alkaline medium. There are exceptions to this rule, however, for Bacillus butyricus and Sarcina ventriculi can grow well in strong acids, and Micrococcus urea can tolerate excessive alkalinity. Acid media are excellent for the cultivation of molds. Neutral or feebly alkaline media serve best for the cultivable protozoa. ' Light.—Most organisms aré not influenced by the presence or -absence of ordinary diffused daylight. The direct rays of the sun, and to a less degree the rays of the electric arc-light, retard and in numerous instances kill bacteria. In a careful study of this subject Weinzirl* found that when bacteria were placed upon glass or paper, and exposed to the direct rays of the sun, without any covering, most non-spore-bearing bacteria, including Bacillus tubercu- losis, B. diphtherie, B. typhosus, S. cholere asiatice, B.. coli, B. prodigiosus, and others are killed in from two to ten minutes. Certain colors are distinctly inhibitory to the growth, blue being especially prejudicial. Treskinskajat} found that sunlight had a marked destructive effect upon the tubercle bacillus, and varied according to altitude. By direct sunlight at the sea-level they were-destroyed in five hours: at an altitude of 1560 meters, in three hours. In winter the time of destruction was about two hours longer than insummer. In diffused daylight the time required for destruction was about twice as long *“Centralbl. f. Bakt. u. Parasitenk. Ref.,” xivi1, Nos. 22-24, p. 681. } “Jour. Infectious Diseases,’’ 1907, vol. 1v, Supplement, No. 3, p. 128. Conditions Prejudicial to Growth of Bacteria 53 as in direct sunlight. His experiments were performed with pure cultures dried in a thin layer upon glass. Certain chromogenic bacteria produce colors only when exposed to the ordinary light of theroom. Bacillus mycoides roseus produces its red pigment only in the dark. The virulence of many pathogenic bacteria is gradually attenuated if they are kept in the light. Molds and yeasts grow best in the dark, so that in general it can be said that the vegetable micro-organisms, belonging to the fungi and having no chlorophyl, need no light and are injured rather than benefited by it. The pathogenic protozoa have not been particularly studied with reference to light. Non-pathogenic water protozoa love the light and die in the dark. Electricity, X-rays, etc.—Powerful currents of electricity passed through cultures have been found to kill the organisms and change the reaction of the culture-medium; rapidly reversed currents of high intensity, to destroy the pathogenesis of the bacteria and transform their toxic products into neutralizing bodies (antitoxin?). Atten- tion has been called to this subject by Smirnow, d’Arsonval and Charin, Bolton and Pease, Bonome and Viola, and others. An interesting contribution upon the “Effect of Direct, Alter- nating, Tesla Currents and X-rays on Bacteria” was made by Zeit,* whose conclusions are as follows: 1. A continuous current of 260 to 320 milliampéres passed through bouillon cultures kills bacteria of-low thermal death-points in ten minutes by the pro- duction of heat (98.5°C). The antiseptics produced by electrolysis during this time are not sufficient to prevent the growth of even non-spore-bearing bacteria. The effect is a purely physical one. 2. A continuous current of 48 milliampéres passed through bouillon cultures _ for from two to three hours does not kill even non-resistant forms of bacteria. The temperature produced by such a current does not rise above 37°C., and the electrolytic products are antiseptic, but not germicidal. 3. A continuous current of 100 milliampéres passed through bouillon cultures for seventy-five minutes kills all non-resistant forms of bacteria even if the temperature is artificially kept below 37°C. The effect is due to the formation of germicidal electrolytic products in the culture. Anthrax spores are killed in hours. Subtilis spores were still alive after the current was passed for three ours. 4. A continuous current passed through bouillon cultures of bacteria produces a strongly acid reaction at the positive pole, due to the liberation of chlorin which combines with oxygen to form hypochlorous acid. The strongly alkaline reaction of the bouillon culture at the negative pole is due to the formation of sodium hydroxid and the libération of hydrogen in gas bubbles. With acurrent of roo milliampéres for two hours it required 8.82 milligrams of H2SO, to neutral- ize 1 cc. of the culture fluid at the negative pole, and all the most resistant forms of bacteria were destroyed at the positive pole, including anthrax and subtilis spores. At the negative pole anthrax spores were killed also, but subtilis spores remained alive for four hours. 5. The continuous current alone, by means of Du Bois-Reymond’s method of non-polarizing electrodes, and exclusion of chemic effects by ions in Kruger’s sense, is neither bactericidal nor antiseptic. The apparent antiseptic effect on suspension of bacteria is due to electric osmosis. The continuous electric current has no bactericidal nor antiseptic properties, but can destroy bacteria * “Jour. Amer. Med. Assoc.,’’ Nov. 30, rgor. 54 Biology of Micro-organisms only by its physical effects (heat) or chemic effects (the production of bactericidal substances by electrolysis). 6. A magnetic field, either within a helix of wire or between the poles of a powerful electromagnet, has no antiseptic or bactericidal effects whatever. 7. Alternating currents of a 3-inch Ruhmkorff coil passed through bouillon cultures for ten hours favor growth and pigment production. 8. High-frequency, high potential currents—Tesla currents—have neither antiseptic nor bactericidal properties when passed around a bacterial suspension within a solenoid. When exposed to the brush discharges, ozone is produced and kills the bacteria. ; - 9- Bouillon and hydrocele-fluid cultures in test-tubes of non-resistant forms of bacteria could not be killed by Réntgen rays after forty-eight hours’ exposure at a distance of 20 mm. from the tube. Io. Suspensions of bacteria in agar plates and exposed for four hours to the rays, according to Rieder’s plan, were not killed. 11. Tubercular sputum exposed to the Réntgen rays for six hours, at a distance of 20 mm. from the tube, caused acute miliary tuberculosis of all the guinea-pigs inoculated with it. 12. Réntgen rays have no direct bactericidal properties. The clinical results must be explained by other factors, possibly the production of ozone, hypochlor- ous acid, extensive necrosis of the deeper layers of the skin, and phagocytosis. The action of the x-rays upon bacteria has been investigated by Bonome and Gros,* Pott,t and others. When the cultures are exposed to their action for prolonged periods, their vitality and virulence seem to be slightly diminished. They are not killed by the x-rays. . Movement.—Rest seems to be the condition best adapted for micro-organismal development. Slow-flowing movements do not have much inhibitory action, but violent agitation, as by shaking a culture in a machine, may hinder or prevent it. This explains why rapidly flowing streams, whose currents are interrupted by falls and rapids, should, other things being equal, furnish a better drinking- water than a deep, still-flowing river. Galli-Valeriof has shown, however, that agitation does not in- hibit the growth of the anthrax, typhoid or colon bacilli or the pheumococcus, but sometimes facilitates it. Association.—Symbiosis is the vital association of different species of micro-organisms by which mutual benefit to one or the other is brought about. Antibiosis is an association detrimental to one of the associated organisms. Bacterial growth is greatly modified by the association of different species. Coley found the streptococcus more active when combined with Bacillus prodigiosus; Pawlowski, that mixed cultures of Bacillus anthracis and Bacillus prodigiosus were less virulent than pure cultures of anthrax; Meunier, § that when the influenza bacillus of Pfeiffer is inoculated upon blood agar together with Staphylococcus aureus its growth is favored by a change which the staphylococci bring about in the hemoglobin. A similar advantageous association has been pointed out by Sanarelli, who found that Bacillus icteroides grows best and retains *“Giornal. med. del Regis Esercito,” an 45, u. 6. t “Lancet,” 1897, vol. 11, No. 21. t ‘‘Centralbl. f. Bakt.,” etc., Sept. 23, 1904, Orig., xxxvu, p- I51. § Société de Biologie, Séance du 11 Juin, 1898, ““La Semaine médicale,”’ June 15, 1898. : Conditions Prejudicial to Growth of Bacteria 55 its vitality longest when grown in company with certain of the molds. Rarely, the presence of one species of micro-organism entirely eradicates another. Hankin* found that Micrococcus ghadialli destroyed the typhoid and colon bacilli, and suggested the use of this coccus to purify waters polluted with typhoid. An interesting experimental study of the bacterial antagonisms with special reference to Bacillus typhosus, that the student should read, is by W. D. Frost, and appears in the “Journal of Infectious Diseases,” 1904, 1, p. 599. Temperature.—According to Frankel, bacteria will rarely grow below 16° and above 40°C., but Fligge has shown that Bacillus subtilis will grow very slowly at 6°C.; at 12.5°C. fission does not take place oftener than every four or five hours; at 25°C. fission occurs every three-quarters of an hour, and at 30°C. about every half-hour. The temperature at which micro-organisms grow best is known as the optimum, the lowest temperature at which they continue active as the minimum, the highest that can be endured the maximum. A few forms of bacteria grow at very high temperatures (60° 7o°C.), and are described as thermophilic. They are found in manure piles and in hot springs. Tsiklinskyt has described two varieties of actinomyces and a mold that he cultivated from earth and found able to grow well at 48° to 68°C., though not at all at the temperature of the room. Most bacteria are killed by temperatures above 60° to 75°C., but their spores can resist boiling water for some minutes, though killed by dry heat if exposed to 150°C. for an hour or to 175°C. for from five to ten minutes. The resistance of low forms of life to low temperatures is most astonishing. Some adult bacteria and most spores seem capable of resisting almost any degree of cold. Ravenel{ exposed anthrax spores to the action of liquid air for three hours; diphtheria bacilli, for thirty minutes; typhoid bacilli, for sixty minutes; and Bacillus prodigiosus, for sixty minutes, the temperature of the cultures being reduced to about —140°C., yet in no case was the vegetative ca- pability of all of the bacteria destroyed, and when transferred to fresh culture bouillon they grew normally. His researches corroborate those of Pictet and Yung and others. To say that bacteria are not injured by cola is a mistake, as Sedgwick and Winslow§ have found that when typhoid bacilli are frozen, the greater number of them are destroyed, and that subsequent * “Brit. Med. Jour.,” Aug. 14, 1897, p. 418. + “Russ. Archiv f. Path.,” etc., June, 1898, Bd. v. t “The Medical News,” June 10, 1899. ite cla f. Bakt. u. Parasitenk.,” etc., May 26, 1900, Bd. xxvu, Nos. 18, 19, p. 684. 56 Biology of Micro-organisms development of the frozen cultures takes place from the few surviving organisms. Bacteria usually grow best at the temperature of a comfortably heated room (17°C.), and are not affected by its occasional] slight variations. Some, chiefly the pathogenic forms, are not cultivable except at the temperature of the body (37°C.); others, like the tu- bercle bacillus, grow best at a temperature a little above that of the normal body. The temperature endurance of the molds resembles that of the - bacteria. The mycelia are killed at temperatures of 60°C. and over, but their spores endure 100°C. The yeasts and oidia, that have no resisting spores, are killed at about 60°C. The protozoa are still more sensitive to heat variations than the plant organisms and are killed by less extreme variations. Here again, however, the encysted protozoa endure greater variations than the active organisms. Effect of Chemic Agents.—The presence of chemic agents, espe- cially certain of the mineral salts, in an otherwise perfectly suitable medium may completely inhibit the development of bacteria, and if added to grown cultures in greater concentration, destroy them. Such substances are spoken of as antiseptics in the former, germi- cides in the latter case. Bichlorid of mercury and carbolic acid are the most familiar examples of germicides. Though these agents are supposed to operate in definite concentra- tions with almost unvarying result, Trambusti* found it possible to produce a tolerance to a certain amount of bichlorid of mercury by cultivating Friedlinder’s bacillus upon culture-media containing gradually increasing amounts of the salt, until from 1-15,000, which inhibit ordinary cultures, it could accommodate itself to 1-2000. The various chemic agents act in different ways upon the micro- organisms. ‘Thus, they may combine with the protoplasm to make a new and no longer vital compound; or, they may coagulate or dissolve or dehydrate or oxidize the protoplasm to a destructive extent. The addition of chemic agents to solutions containing micro- organisms also changes the osmotic pressure. When an active organism is living in its normal environment, it contains within its plasm a greater concentration of solutes than are to be found in the surrounding fluid. Under these circumstances the pressure on the inside of the ectosarc or other cell membrane is greater than that on the outer side, and the cell is in a state of turgor. If now salts are added so that the solutes on the outside exceed those on the inside, water is drawn out and the protoplasm is made to shrink or condense. According to the degree of this change the organism will be embarrassed, made impotent, or destroyed. On the other hand, when micro-organisms have enjoyed a con- centrated medium like blood-serum and are suddenly transferred to * “Lo Sperimentale,” 1893-94. Fermentation 57 distilled water, so much water may be suddenly drawn into their protoplasm that they swell up and may burst and go to pieces. This is particularly true of the delicate protozoa like the trypanosoma. Metabolism.—According to their activities, micro-organisms are classed as— Zymogens, when they cause fermentation. Saprogens, when they cause putrefaction. Chromogens, when they produce colors. Photogens, when they phosphoresce. Aérogens, when they evolve gas. Pathogens, when they cause disease. The metabolic activities of micro-organisms occasion many well- known changes in nature. Thus, it is through their energies that by fermentative and putrefactive changes organic matter is gradually transformed from complex to simple compounds. It is by the energy of bacteria that foul waters are gradually purified, and while it is true that the presence of large numbers of bacteria in water detracts from its potability, the very bacteria that cause its con- demnation ultimately effect its purification by exhausting the organic matter, it contains in their own nutrition. In the treat- ment of sewage by the ‘“‘septic tank’’ method, the organic matter contained in the water is consumed through the agency of anaérobic and aérobic bacteria, until the water once more becomes clear and pure, the bacteria dying out as the nutrition becomes exhausted. The promptness with which bacteria attack organic matter is seen in the changes brought about in foods, some of which are ruined in flavor or quality, though others are thought tobe improved. Thus, the flavor of butter, sausage, and cheese, the aroma of wines, and many other important gustatory characteristics of our foods depend solely upon the activity of bacteria or other micro-organisms. Many of these activities are harmless, and, indeed, advantageous, though the fact that they are not infrequently accompanied by chemic changes, some of which are poisonous, makes it necessary to watch and time their operations lest acridity, acidity, insipidity, or toxicity of the food replace the desired effect. Briefly considered, the best known phenomena resulting from micro-organismal energy are as follows: Fermentation.—Fermentation is catalysis of carbon compounds caused by catalysts or ferments resulting from micro-organismal metabolism. The alcoholic fermentation, which is a familiar phenomenon to the layman as well as to the brewer and chemist, depends upon the activity of an yeast-plant, one of the saccharo- myces fungi by which the sugar is broken up into alcohol and carbon dioxid, with some glycerin and other by-products. The following equation shows the chief changes produced: CeHi206 = 2C.H,;OH + 2COr2 Sugar Alcohol Carbon dioxid 58 Biology of Micro-organisms There are also several bacteria which produce the acetic fermenta- tion, though it is generally attributed to Bacillus aceticus. There are two equations to express this fermentation: I. CH,CH:,OH + O CH;CHO + 4H:0 Alcohol ~ Oxygen Aldehyd Water II. CH;CHO + O = CH;COOH : Aldehyd Oxygen Acetic acid A number of different bacilli seem capable of converting milk-sugar into lactic acid, though Bacillus acidi lactici is the best known and. most active acid producer. The butyric fermentation generally due to Bacillus butyricus may also be caused by other bacilli. (For an exact description of the chemistry of the fermentations reference must be made to special text-books.*) The lactic acid and butyric acid fermentation, have the following equations: I. Cyw2H2O01 + H.0 = C6H1202 + CeHi206 Lactose or milk sugar Galactose Dextrose Il. CeHi20¢ = 2C3H,.O3 Sie Ea pet Galactose Lactic acid III. CeHi20¢6 = C4Hg02 + COz + 2H pases bos ' Galactose Butyric acid Putrefaction.—Putrefaction is a catalysis of proteins resulting from the activity of micro-organismal catalysts or enzymes. It is associated with the evolution of a vile odor. The first step in the process seems to be the transformation of the albumins into peptones, then the splitting up of the peptones into gases, amino-acids, bases, and salts. In the process innocuous albumins are frequently changed to toxalbumins, and sometimes to peculiar putrefactive alkaloids known as ptomains. . Vaughan and Novy define a ptomain as “a chemical compound, basic in character, formed by the action of bacteria on organic matter.” The chemistry of these bodies is very complex, and for a satisfac- tory description of them Vaughan and Novy’s book} is excellent. Ptomains probably play but a small part in pathologicconditions. They are formed almost exclusively outside of the living body, and only become a source of danger when ingested with the food. It is supposed that cases of ice-cream and cheese poisoning are usually due to ¢yrotoxicon, a ptomain produced by the putrefaction of the protein substances of the milk before it is frozen into ice-cream or made into cheese. The safeguard is to freeze the milk only when perfectly fresh and avoid mixing the milk, cream, sugar, and flavor- ing substances, and allowing the mixture to stand for some time beforehand. *See “Enzymes and Their Applications,’ by Jean Effront, translated by S. C. Prescott, New York, 1902; “‘Micro-organisms and Fermentation,” by Alfred Jorgensen, translated by A. K. Miller and A. E. Lennholm, London, Igoo0; and the many writings of Christian Hansen. { “Ptomaines and Leucomaines,” 1888; ‘Cellular Toxins,” 1902. Production of Gases . 59 The occasional cases of ‘“‘Fleischvergiftung,” “meat-poisoning,” or “Botulismus,” are due to the development of toxic ptomains in consequence of the growth of certain bacteria (Bacillus botulinus) in the meat. Kaensche* has carefully investigated the subject, and _ given a synoptic table containing all the described bacteria of this class. His researches show that there are at least three different bacilli whose growth causes the meat to become poisonous. With the increase of knowledge upon the toxic character of the bacteria themselves, the importance of the toxic ptomains has diminished, until at present we have come to regard them as very rare causes of disease. Production of Gases.—Various gases are given off during decom- position and fermentation, among them being COs, HoS, NH, H, CH,. Gases produced by aérobic bacteria usually fly off from the surface of the culture unnoticed, but if the bacterium | be anaérobic and develop the lower part of a tube of solid cuiture media, a visible bubble of gas is usually formed about the colonies. Such gas bubbles are almost invariably pres- ent in cultures of the bacilli of tetanus and malignant edema. To quantitatively determine the gas-produc- tion, some form of the Smith fermentation-tube is most convenient. The tube is filled with bouillon containing some sugar, sterilized as usual, inoculated, and stood aside to grow. As the gases form, the bubbles ascend and accumulate in the closed arm. In estimating quantitatively, one must be careful that the tube is not so constructed as to allow the gas to escape as well as to ascend into the main Fig. 16.—Smith’s fer- “ mentation -tube. reservoir. For the determination of the nature of the gases produced, Theobald Smith has recommended the following method: a B “The bulb is completely filled with a 2 per cent. solution of sodium hydroxid (NaOH) and tightly closed with the thumb. The fluid is shaken thoroughly with the gas and allowed to flow back and forth from the bulb to the closed branch, and the reverse several times to insure intimate contact of the COz with the alkali. Lastly, before removing the thumb all the gas is allowed to collect in the closed branch so that none may escape when the thumb is removed. If COz be present, a partial vacuum in the closed branch causes the fluid to rise suddenly when the thumb is removed. After allowing the layer of foam to subside somewhat the space occupied by gas is again measured, and the difference between this amount and that measured before shaking with the sodium -hydroxid solution gives the proportion of CO: absorbed. The explosive character of the residue is determined as follows: The cotton plug is replaced and the gas from the closed branch is allowed to flow into the bulb and mix with the air there present. The plug is then removed and a lighted match inserted into * “Zeitschrift fiir Hygiene,” etc., June 25, 1896, Bd. xx, Heft 1. 60 Biology of Micro-organisms the mouth of the bulb. The intensity of the explosion varies with the amount of air present in the bulb. ‘The relative proportion of gases resulting from the fermentation is frequently of importance for the differential diagnosis of related . H ‘ bacteria. Smith has designated this relation of co, 3 the ‘gas formula.’ ‘ 5 H 2 , ; The colon bacillus has a gas formula corresponding to C0; me Other aerogenic -- bacilli sometimes show a formula=— = i ” CO. 2° Liquefaction of Gelatin.—As certain organisms grow in gelatin, the medium becomes partly or entirely liquefied. This peculiarity is apparently independent of any other property of the organisms, and is manifested alike by pathogenic and non-pathogenic forms. The liquefaction is supposed to be dependent upon a form of pepto- nization. Bitter* and Sternberg have shown that if from a culture in which liquefaction has taken place the bacteria be removed by filtration, the filtrate will retain the power of liquefying gelatin, showing: the property is not resident in the bacteria, but in some substancein solutionin their excreted products. These products were described as “‘tryptic enzymes” by Fermi,{ who found that heat de- stroyed them. Mineral acids seem to check their power to act upon -gelatin. Formalin renders the gelatin insoluble. Some of the bacteria liquefy the gelatin in such a peculiar and characteristic manner as to make the appearance a valuable guide for the differen- tiation of species. Production of Acids and Alkalies.—Under the head of ‘‘ Fermen- tation” the formation of acetic, lactic, and butyric acids has been dis- cussed. Formic, propionic, baldrianic, palmitic, and margaric acids also result from microbic metabolism. As the acidity progresses, it impedes, and ultimately completely inhibits, the activity of the organisms. The cultivation of the bacteria in milk to which litmus or lacmoid has been added is a convenient method for de- tecting changes of reaction. Rosolic acid solutions may also be used, the acid converting the red into an orange color. Neutral red is also much employed for this purpose, the acids turning it yellow. The quantitative estimation of changes in reaction can be best made by titration, and the fermentation-tube culture can be employed for the purpose. The contents of the bulb and branch should be . shaken together, a measured quantity withdrawn, and titration with = sodium hydroxid, or = hydrochloric acid, performed. The alkali most frequently formed by bacterial growth is ammo- nium, which is set free from its combinations, and either flies off asa gas or forms new combinations with acids simultaneously formed. Some bacteria produce acids only, some alkalies only, others both — * “Archiv fiir Hygiene,” 1886, Heft 2. t “Medical News,” 1887, No. 14. t “Centralbl. f. Bakt.,” etc., 1891, Bd. x, p. gor. Chromogenesis 61 acids and alkalies. Both acids and the alkalies, when in excess, serve to check the further activity of the micro-organisms. Chromogenesis.—Bacteria that produce colored colonies or impart color to the medium in which they grow are called chromogenic; those producing no color, mon-chromogenic. Most chromogenic bacteria are saprophytic and non-pathogenic. Some of the patho- genic forms, as Staphylococcus pyogenes aureus, are, however, color producers. It seems more likely that certain chromogenetic sub- stances unite with constituents of the culture medium to produce the colors than that the bacteria form the actual pigments; but, as Gale- otti* has shown, there are two kinds of pigment, one being soluble, readily saturating the culture medium, as the pyocyanin and fluorescin of Bacillus pyocyaneus, the other insoluble, not tingeing the solid culture media, but retained in the colonies, like the pigment of Bacil- lus prodigiosus. The pigments are found in greatest intensity near the surface of a bacterial mass. The coloring matter never occupies the cytcplasm of the bacteria (except Bacillus prodigiosus, in whose cells occasional pigmeént-granules may be seen), but occurs as an in- tercellular deposit. ; Almost all known colors are formed by different bacteria. One bacterium will sometimes elaborate two or more colors; thus, Bacillus ' pyocyaneus produces pyocyanin and fluorescin, both being soluble pigments—one blue, the other green. Gessard{ has shown that when Bacillus pyocyaneus is cultivated upon white of egg, it produces only the green fluorescent pigment, but if cultivated in pure peptone solution it produces only the blue pyocyanin. His experiments prove the very interesting fact that for the production of fluorescin it is necessary that the culture medium contain a definite amount of a phosphatic salt. Sometimes, an organism produces two pig- ments, one is soluble, the other insoluble, so that the colony will appear one color, the medium upon which it grows another. The author once found an interesting coccus,{ with this peculiarity, upon the conjunctiva. It formed a brilliant yellow colony upon the sur- face of agar-agar, but colored the agar-agar itself a beautiful violet. In this case the yellow pigment was insoluble, the violet pigment soluble and diffusible through the jelly. Some organisms will only produce pigments in the light; others, as Bacillus mycoides roseus, only in the dark. Some produce them only at the room temperature, but, though growing luxuriantly in the incubator, re- fuse to produce pigments at so higha temperature. Thus, Bacillus prodigiosus produces a brilliant red color when growing at the tem- perature of the room, but is colorless when grown in the incubator. The reaction of the culture medium is also of much importance in this connection. Thus, Bacillus prodigiosus produces an intense * “To Sperimentale,” 1892, XLVI, Fasc. 1, p. 261. + “Ann. de l’Inst. Pasteur,” 1892, pp. 810-823. t See Norris and Oliver, ‘System of Diseases of the Eye,” vol. I, p. 489, and “University Medical Magazine,” Philadelphia, Sept., 1895. 62 Biology of Micro-organisms scarlet-red color upon alkaline and neutral media, but is colorless or pinkish upon slightly acid media. Some of the pigments—per- haps most of them—are formed only in the presence of oxygen. Production of Odors.—Gases, such as H2S and NHy, and acids, butyric and acetic acids, have sufficiently characteristic odors. There are, however, a considerable number of pungent odors which ‘seem to arise from independent odoriferous principles. Many of them are extremely unpleasant, as that of the tetanus bacillus. The odors seem to be peculiar individual characteristics of the organisms. Production of Phosphorescence.—Cultures of Bacillus phos- phorescens and numerous other organisms are distinctly phosphor- escent. So much light is sometimes given out by gelatin cultures of these bacteria as to enable one to see the face of a watch in a dark room. Gorham found the photogenesis most marked when the organisms are grown in alkaline media at room temperature. Most of the phosphorescent bacteria are found in sea-water, and are best cultivated in sea-water gelatin. Some are familiar to butchers through the phosphorescence they cause on the surface of stale meats. Production of Aromatics.—Phenol, kresol, hydrochinone, hydro- paracumaric acid, and paroxyphenylic-acetic acid are by no means uncommon products of bacteria. The most important is indol, which was at one time thought to be peculiar to the cholera spirillum, but is now known to be produced by many other bacteria. The best method of testing for it is that of Salkowski,* known as the nitrosoindol reaction. To perform it, ro cc. of the fluid to be tested receive an addition of 10 drops of concentrated sulphuric acid. The mixture is shaken in a test-tube. A few cubic centimeters of a 0.02 per cent. solution of potassium nitrite are then allowed to flow down the side of the tube. If indol is present, a purple-red color develops at the junction of the two fluids.| McFarland and Small{ have found that the intensity of this color corresponds to the quantity of indol present, and that quantitative tests can be made by means of a comparative color test series. ; The Formation of Nitrates.—A process of fundamental importance is carried on by certain lowly bacteria of the soil. Since plants are unable to assimilate the free nitrogen of the air, but must obtain this element from the soil in the form of some soluble compound, and since there is a relatively limited amount of combined nitrogen in the world, it becomes of the last importance that the supplies which are continually withdrawn from the soil should be replaced by the nitrogen liberated in the decay of organic material. This nitrogen, after a series of putrefactive changes have occurred, ap- pears asammonia. The odor of this gas is often plainly perceptible * “Zeitschrift. f. physiol. Chemie,” v111, p. 417. t See Grubs and Francis, “Bull. of the Hyg. Laboratory,” 1902, No. 7. t ‘Trans. of the American Public Health Association,” 1905. Reduction of Nitrates 63 about manure heaps. In this form nitrogen is poorly adapted for use by plants, and moreover may be easily dissipated. An extensive further process of oxidation is carried on by the nitrifying bacteria, whereby nitrates are ultimately formed. These are eminently adapted for use by plants, and so the soil is rendered continuously capable of supporting vegetation. Nitrosomonas and Nitrosococcus convert ammonia into nitrous acid, and Nitrobacter oxidizes the latter to form nitric acid. These genera are well nigh universal in the soil. They do not grow on the ordinary culture media, but require special solutions, free from the ditfusive albumins—free, indeed, from organic com- pounds of any sort. Their supplies of carbon are obtained by the dissociation of carbon dioxid. It is highly noteworthy that they are thus able to flourish without food more complex than ammonia, a fact which is without parallel among organisms devoid of chlorophyl. ’ Reduction of Nitrates.—A considerable number of bacteria are able to reduce nitrogen compounds in the soil or in culture media, prepared for them, intoammonia. To the horticulturist this matter is of much interest. Winogradsky* has described specific nitrifying bacilli which he found in soil, and asserts that the presence of ordi- nary bacteria in the soil causes no formation of nitrites so long as the | special bacilli are withheld. Reduction of nitrates can be determined experimentally by the use of a nitrate broth, made by dissolving in 1000 cc. of water 1 gram of peptone and o.2 gram of potassium nitrate. The ingredients are dissolved, filtered, then filled into tubes, and sterilized. The tubes are inoculated and the results noted. As nitrites and ammonia are, however, commonly present in the air and are taken up by fluids, it is always well to control the test by an uninoculated tube tested with the reagents in the same manner as the culture. Two solutions are employed} for testing the culture: I. Naphthylamin, 0.1 gram, Boil, cool, filter, and add 156 cc. of Distilled water, 20.0 grams, dilute (1:16) hydric acetate. II. Sulphanilic acid, 0.5 gram. Hydric acetate, diluted, 150.0 cc. Keep the solutions in glass-stoppered bottles and mix equal parts for use at the time of employment. About 3 cc. of the culture and an equal quantity of the uninocu- lated culture fluid are placed in test-tubes and about 2 cc. of the test fluid slowly added to each. The development of a red color indicates the presence of nitrites, the intensity of the color being in proportion to the quantity of nitrites present. If a very slight pinkish or reddish color in the uninoculated culture fluid and a deeper red in the culture develop, it shows that a small amount of nitrites * Ann, de l’Inst. Pasteur,” 1891; ‘‘La Semaine médicale,” 1892. + “Journal of the American Public Health Association,” 1888, p. 92. 64 Biology of Micro-organisms was already present, but that more have been produced by the growth of the bacteria. The presence of ammonia in either fluid is easily determined by the immediate development of a yellow color or precipitate when a few drops of Nessler’s solution* are added. Failure to determine either ammonia or nitrites may not mean that the nitrates were not reduced, but that they were reduced to N. It is, therefore, necessary to test the solutions for nitrates, which is done by the use of phenolsulphonic acid and sodium hydroxid, which in the presence of nitrates give a yellow color. Combination of Nitrogen.—Not only do bacteria destroy or re- duce nitrogen compounds, but some of them are also able to assimi- late nitrogen from the air and so combine it as to be useful for the nourishment of vegetable and animal life. The most interesting — organisms of this kind are found upon the roots of the leguminous plants, peas, clover, etc., and have been studied by Beyerinck.{ It seems to be by the.entrance of these bacteria into their roots that the plants are able to assimilate nitrogen from the atmosphere and enrich sterile ground. Every agriculturist knows how sterile soil is improved by turning under one or two crops of clover with the plough. Peptonization of Milk.—Numerous bacteria possess the power of digesting—peptonizing—the casein of milk. The process varies with different bacteria, some digesting the casein without any appar- ent change in the milk, some producing coagulation, some gelatiniza- tion of the fluid. In some cases the digestion of the casein is so complete as to transform the milk into a transparent watery fluid. Milk invariably contains large numbers of bacteria, that enter it from the dust of the dairy, many of them possessing this power and ultimately spoiling the milk. In the process of peptonization the milk may become bitter, but need not change its original reaction. The phenomena of coagulation and digestion of milk can be made practical use of to aid in the separation of similar species of bacteria. Thus, the colon bacillus coagulates milk, but the typhoid bacillus © does not. Production of Disease.—Micro-organisms that produce disease are known as pathogenic; those that do not, as non-pathogenic. Be- tween the two groups there is no sharp line of separation, for true pathogens may be cultivated under such adverse conditions that their virulence may be entirely lost, while those ordinarily harmless may be made virulent by certain manipulations. In order to determine that a micro-organism is possessed of pathogenic powers, the committee of bacteriologists of the American Public *Nessler’s solution consists of potassium iodid, 5 grams, dissolved in hot water, § cc. Add mercuric chlorid, 2.5 grams, dissolved in 10 cc. of water, then to the mixture add potassium hydrate, 16 grams, dissolved in water, 40 cc. and dilute the whole to 1000 cc. ’ t “Centralbl. f. Bakt.,” etc., Bd. vir, p. 338. Production of Enzymes 65 Health Association* recommends that: (t) When a given form grows only at or below 18° to 20°C., inoculation of about 1 per cent. of the body-weight with a liquid culture seven days old should be made into the dorsal lymph-sac of a frog. (2) When a species grows at 25°C. and upward, an inoculation should be made into the peritoneal cavity of the most susceptible (in general) of warm- blooded animals—i.e., the mouse, either the white or the ordinary house mouse. The inoculation should consist of about 1 per cent. of the body-weight of the mouse of a four- to eight-hour standard bouillon culture, or a broth or water suspension of one platinum loop from solid cultures. When such intraperitoneal injection fails, it is unlikely that other methods of inoculation will be successful in causing the death of the mouse. If the inoculations of the frog and mouse both prove negative, the committee think it unnecessary to insist upon any further tests of pathogenesis as being requisite for work in species differentiation. Production of Enzymes.—Some of these have already been men- tioned as causing fermentation and putrefaction, coagulating milk, dissolving gelatin, etc. There are, however, others which have interesting and important actions upon both animal and vegetable substances. Emmerich and Léwf observed that in old cultures of Bacillus pyocyaneus the bacteria become transformed into a gelatinous mass, and were led to experiment with old and degenerating cultures con- densed to }{9 volume in a vacuum apparatus. The bacteriolytic powers were then found to be much increased, and they were sub- sequently able to precipitate from the concentrated culture an enzyme, which they called pyocyanase. -The authors reached the rather hasty conclusions that the cessation of growth of bacteria in cultures depends upon the generation of enzymes; that the enzymes destroy the dead bacteria; that the enzymes will kill and dissolve living bacteria and destroy toxins, and, therefore, are useful for the treatment of infectious diseases, and that antitoxins are simply accumulated enzymes which the immunized animals have received during treatment, and which, appearing in the serum, produce the effects so well known. It is probable that many of the toxic effects of bacteria and their cultures depend upon enzymic substances, the nature of which we do not yet understand. * “Jour. Amer. Public Health Assoc.,” Jan., 1898. } “Zeitschrift fiir Hygiene,” 1899. CHAPTER III INFECTION InFEcTION is the successful invasion of an organism by micro- parasites. Unfortunately custom has sanctioned the use of the word in other and sometimes confusing senses, thus, a table or knife upon which micro-organisms are known to be or are even supposed to be; the mouth and intestine, which naturally harbor bacteria of various forms, or a splinter penetrating the skin and carrying harm- less bacteria into the deeper tissues, are all said by the surgeon to be “infected,” when, in fact, it would be more correct to describe them as infective. The term infection should imply an abnormal state resulting from the deleterious action of the parasite upon the host. The colon bacillus is a harmless commensal of the intestine of every human being, and of most of the lower animals. The intestine is not “in- fected,” but infested with it, and it is only when abnormal or un- natural conditions arise that infection can take place. This form of association of certain bacteria with certain parts of the body to which they do no harm, but into which they may rapidly invade when appropriate conditions arise, is described by Adami as sub- infection. The possibility of infection is always there, though it is but rarely that conditions arise under which it can be accomplished. There are two inseparable factors to be considered in all infections: the organism infecting and the organism infected. The first is the parasite, the second, the host. Infectivity and infectability may depend upon peculiarities of either parasite or host. Organisms that have lived together as commensals, that is, in a state of neutral relationship for an almost indefinite period, may suddenly cease their customary association, because of newly acquired power of invasion on the one hand, or diminished vital resistance on the other, and infection take place where it had previously been impossible. Bacteria are commonly called saprophytic when they live in nature apart from other living organisms, and parasitic when they livein or upon them. Saprophytic bacteria when accidentally transplanted from their natural environment to the body of some animal, for example, may or may not be capable of continuing life under the new conditions. In the greater number of cases they die, but sometimes the new environment seems better than the old, and they multi- ply rapidly, invade the tissues in all directions, eliminate their met- 66 Sources of Infection 67 abolic products into the juices, and occasion varying morbid conditions. The parasitic bacteria live in habitual association with higher or- ganisms. Sometimes, and indeed most commonly, it is a harmless association, like that of certain cocci upon the skin, but occasionally it results in the destruction of the tissues and the death of the host, as- in tuberculosis, leprosy, etc. The group of pathogenic organisms has no well-defined limits, for it is frequently observed that micro-organisms well known under other conditions, and not known to have been engaged in pathogenic processes, turn up unexpectedly as the cause of some morbid condi- tion. Indeed, although we are acquainted with a large number of organisms that have never been observed in connection with disease, we are scarcely justified in concluding that they are incapable of producing injury should proper conditions arise. SOURCES OF INFECTION The sources of infection may be exogenous or endogenous,’ that is, they may arise through the admission to the tissues of micro-organ- isms from sources entirely apart from the individual infected, or through the admission of some of those parasitic and usually harmless organisms constantly associated with him. Exogenous infections arise through accidental contact with infective agents belonging to the external world. A polluted atmosphere may carry into the respiratory passages micro-organisms capable of colonizing there. From the respiratory passages, minute drops of secretion may be coughed or sneezed into the atmosphere to be inhaled by neighboring persons and infect them. Such ‘‘drop infection” has been studied in reference to tuberculosis and diphtheria, and doubtless explains the transmission of whooping-cough, pneumonia, and other respiratory disturbances. Polluted water or food may carry into the intestine micro-organisms whose temporary residence may entirely change the functional and structural integrity of the parts, as in typhoid fever, cholera and dysentery. Wounds inflicted by the teeth of animals, by weapons, by imple- ments, or by objects of various kinds, carry into the tissues micro- organisms whose operations, local or general, may variously affect the organism to its detriment. Examples are to be found in rabies, tetanus, anthrax, malignant and gaseous cedema, suppuration, etc. Fomites, or objects made infective through contact with individu- als suffering from smallpox, scarlatina, and other contagious or actively infectious diseases, become the means through which the specific micro-organisms may be conveyed to the well with resulting infection. Contact with unclean objects of various kinds—spoons, knives, cups, 68 Infection blow-pipes, catheters, syringes, dental instruments, etc.—may serve to transfer disease-producing organisms from one person to another who might otherwise never come in contact with them. Attention should be called to the facility with which the diseases of childhood may be spread through the thoughtless or ignorant custom of many adults and children of using handkerchiefs, napkins, forks, cups, spoons, etc., in common; in having wash-rags, towels, hair-brushes and combs in common; cultivating the habit of putting lead-pencils, etc.,in the mouth, and then passing them on to others who will do the same, and to many other relations of every-day life by ‘which infectious agents may be spread.- Scarlatina, measles, mumps, acute anterior poliomyelitis, ophthalmia, tuberculosis, ringworm, fevers, syphilis, etc., may all be spread through such means. Suctorial insects seem occasionally to act as the medium by which micro-organisms withdrawn in blood from one person may be in- troduced into other persons so that they become infected. The flea thus brings about the spread of plague; the mosquito, of malaria; the tsetse fly, of trypanosomiasis; the tick, of relapsing fever, the louse of typhus fever, etc. Endogenous infections arise through the activity of micro-organ- isms habitual to the body. They indicate morbid conditions of the body by which the defensive mechanisms are disturbed, so that or- ganisms harmless under normal conditions become invasive. All normal animals are presumably born free of parasitic micro- organisms, but it is impossible for them to remain so because of the universal distribution of micro-organismal life. The air, the water, the soil, and the food, as well as the associates of the young animal, all act as means by which micro-organisms, and especially bacteria, are brought to the surface and cavities of its body, and but a short time elapses after birth before it harbors the customary commensal and parasitic forms. BACTERIAL TENANTS OF THE NORMAL HUMAN BODY The Skin and Adjacent Mucous Membranes.—The slightly moist warm surface of the skin is well adapted to bacterial life, and its un- avoidable contact with surrounding objects determines that a variety of organisms shall adhere to it. Of these, we can differentiate be- tween forms whose presence is unexpected and temporary; others whose presence may be expected; and still others whose presence is invariable. Elaborate investigations upon the bacterial flora of the skin have been made by Unna;* Mittman,} who studied the finger-nails, under which he found no less than seventy-eight different species; Maggiora,t *“Monatshefte fur prakt. Dermatol.,” 1888, vit, p. 817; 1889, VIII, pp. 293, 562; 1889, Ix, p. 49; 1890, X, p. 485; 1890, XI, p. 471; 1891, XII, p. 240. { “Archiv. f. path. Anat. u. Phys. u. f. klin. Med.,” 1888, CXII, p. 203. } “Giornale della R. Societé d’Igiena,” 1889, Fasc. 5, p. 335. Bacterial Tenants of the Human Body 69 who isolated twenty-nine forms from the skin of the foot; and Prein- delsberger,* who found eighty species of bacteria on the hands. Undoubtedly many of these organisms were accidentally present, and were at least only semi-parasitic. Not a few were met but once and were in no sense bacteria of the skin. The skin may also be temporarily contaminated with bacteria from other portions of the patient’s body, as, for instance, from his intestine; thus Winslow} has found the colon bacillus upon the hands of ten out of one hundred and eleven persons examined. Wigurat also examined the hands of forty persons in hospitals, finding tubercle bacilli in two out of ten persons from phthisical wards, colon bacilli six times and typhoid bacilli once on the hands of nine attendants in the typhoid wards. He found streptococci and staphylococci many times. Welch§ and Robb and Ghriskey|| seem to have been the first to make a clear differentiation between the accidentally present bacteria and the permanently parasitic organisms of the skin, and to show that cer- tain cocci, producing white and yellow colonies upon agar-agar, were invariable in occurrence and penetrated to the lowest epidermal layers. These cocci, of which Welch describes the most common as Staphylococcus epidermidis albus, are universally and invariably present upon the human skin, and must be regarded as habitual parasites. Where the skin is peculiar in its moisture and greasiness, however, additional forms arefound. ‘Thus, in preputial smegma, in the axille, and sometimes about the lips and nostrils, a bacillary organism, Bacillus smegmatis, is invariable, and the recent work by Schaudinn and Hoffmann** has shown that the skin of the genitalia harbors a spiral organism which they call Spirocheta refringens. In the external auditory meatus a coccus, Micrococcus cereus flavus, is almost always to be found in the waxy secretion. Upon the conjunctiva as many accidental organisms may be found as shall have been caught by its moist surface, though the researches of Hildebrand and Bernheim and others seem to show that the tears. have some antiseptic power and prevent the organisms from growing, so that in health there are very few permanent residents of the sac, certain cocci seeming to be the only constant forms. The mouth has been carefully studied bacteriologically by Miller, tf who found six organisms—Leptothrix innominata, Bacillus buccalis *“Samml. medic. Schriften,” herausg. von der ‘Wiener klin. Wochenschrift,” 1891; xxuI, Wien, “Rev. Jahresbericht tber die Fortschritten in der Lehre von den pathogenen Mikroorganismen,”’ 1891, VII, p. 619. t “Jour. Med. Research,” vol. x, p. 463. t Wratsch,” 1895, No. 14. 5 § “Transactions of the Congress‘of American Physicians and Surgeons,” 1891, I, p. 1. . [Bulletin of the Johns Hopkins Hospital,” 1892, 111, p. 37. * “Deutsche med. Woch.,” May 5, 1905. : tt “Micro-organisms of the Human Mouth,” Phila., 1890. 70 Infection maximus, Leptothrix buccalis maxima, Iodococcus vaginatus, Spiril- lum sputigenum and Spirocheta dentinum (denticola)—in every mouth. Practically the same conclusions were reached by Vin- centini.* These organisms are peculiar in that they will not grow in artificial culture. In addition to this permanent flora, Miller culti- vated fifty-two other species, some of which were harmless, some well- known pathogens. - From the mouth these organisms may be traced into the pharynx and esophagus. In studying the micro-organisms of dental caries Goodby} found a large number of organisms which he divided into three groups: A. Those that produce acids, including Streptococcus brevis, Ba- cillus :necrodentalis (Goodby), Sarcina alba, Sarcina lutea, Sarcina aurantiaca, Staphylococcus pyogenes aureus, and Staphylococcus pyogenes salivarius (Biondi). B. Those that liquefy blood-serum: Bacillus mesentericus rubra, B. mesentericus vulgatus, B. mesenteri- cus fuscus, Bacillus fuscus, a yellow bacillus, probably B. gingive pyogenes (Miller), and Bacillus liquefacium motilis. C. Those that produce pigment, including the same organisms as group B. In ca- rious dentine two organisms, Streptococcus brevis and Bacillus necrodentalis, were invariably present. The extinction of the great number of bacteria entering the mouth is referred by most bacteriologists to a bactericidal action of the saliva. The stomach seems to retain very few of the many bacteria that must enter it, its persistently acid contents being inimical to their development. Certain sarcina, especially Sarcina ventriculi, may be found without any considerable departure from the normal state. In carcinoma and other forms of pyloric obstruction with dilatation, the bacterial flora increases, and in achlorhydria micro-organisms of fermentation make their appearance. They are, however, acci- dental and not permanent tenants of the organ. In carcinoma of the stomach a bacillus, probably one of the lactic acid groups, early makes its appearance and is of some diagnostic im- portance. It is called after its discoverer the Oppler-Boas bacillus,} also on account of angulations found in its threads, Bacillus gen- iculatus. It is a large bacillus, tending to form long threads easily seen without an oil-immersion lens. It is probably non-motile, does not form spores, stains by Gram’s method, and is said by Emory$ to divide longitudinally as well as transversely. This, as he says, will, if proved to be correct, be a most important means of identifying the species. Cultures are easily made in media acidified with lactic acid. The intestine receives such micro-organisms as have survived what- ever destructive influences the gastric juices may have exerted, and * “Bacteria of the Sputa and Cryptogamic Flora of the Mouth,” London, 1897" + Transactions of the Odontological Society, June, 1899. ft “Deutsche med. Wochenschrift,” 1905, No. 5. § “Bacteriology and Hematology,’ p. 114. Bacterial Tenants of the Normal Human Body qI its alkaline contents, rich in proteins and carbohydrates in solution, are eminently appropriate for bacterial life. The flora of the intes- tine is, therefore, increased in number and variety of organisms as we descend from its beginning to its end. In the small intestine there may be no bacteria in the upper part of the jejunum, but in most cases Bacillus lactis aérogenes and bacilli of the colon groups are found. These increase in number as the iliocecal valve is reached. The cecum shows large numbers of colon bacilli. The rectum con- tains, in addition, many putrefactive organisms, such as Bacillus putrificus, Bacillus proteus vulgaris, members of the Bacillus subtilis group, and acid-producing organisms, such as Bacillus acidophilus. An interesting and thorough study of these organisms of the bowel and their distribution has been made by Kohlbrugge.* The total number of permanent residents is not known. During in- fancy the predominating organism seems to be Bacillus lactis aerogenes; during adult life, Bacillus coli. Streptococci, especially Streptococcus coli gracilis, are also very common, if not invariable, inhabitants of the intestine. The total bacteria that finally appear in the feces, according to the studies of Strasburgerf and Steele, may reach the enormous figure of 38 per cent. of the total bulk. MacNeal, Latzer, and Kerr,§ in an elaborate work upon the “Fecal Bacteria of Healthy Men,” found that they furnished 46.3 per cent. of the total fecal nitrogen. Rettger|| found the Bacillus enteritidis sporogenes regularly pres- ent in the human feces and believes it to be responsible for some of the putrefactive processes that occur there. The vagina, on account of its acid secretions, harbors but few bacteria. In a study of the vaginal secretions of 40 pregnant women who had not been subjected to digital examinations, douches, or baths, Bergholm** found but few organisms of limited variety. The uterus harbors no bacteria in health, and but few in disease. The intervening acidity of the vagina makes it difficult for bacteria from the surface to penetrate so deeply, and the tenacious alkaline mucus of the cervix is an additional barrier to their progress. Care- ful studies of the bacteriology of the uterine secretions have been made by Gottschalk and Immerwahr{{ and Déderlein and Winterintz.t{t The urethra harbors a few cocci which enter the meatus from the surface and remain local in distribution. The normal bladder is free from bacteria. The nose constantly receives enormous numbers of bacteria in the *“Centralbl. f. Bakt.,”’ etc., 1901, Bd. xxx, pp. Io and 70. } “Zeitschrift fiir klin. Med.,” 1902, XLIv, 5 and 6; 1903, XLVIII, 5 and 6. t “Jour. Amer. Med. Assoc.,” Aug. 24, 1907, Pp. 647. § “Journal of Infectious Diseases,”’ 1909, VI, pp- 132, 571. [| “Jour. of Biological Chemistry,” Aug., 1906, 11, 1 and 2, p. 71. ** “ Archiv f. Gynak.,” Bd. Lxiv, Heft 3. Tt Ibid., 1896, Bd. L, Heft 3. . tt “Beitrage fur Geburtshilfe und Gynidkologie,” Bd. 10, Heft 2. 72 % Infection dust of the inspired atmosphere. These organisms are too numer- ous and too various to enumerate, and might, indeed, comprehend the entire bacterial flora. But in spite of the large numbers of organ- isms received, the nose retains scarcely any, its mucous membranes seeming to be provided with means of disposing of the organisms. Among those best able to withstand the destructive influences, and, therefore, most apt to be found in the deeper passages, are the pseudo- diphtheria bacillus, streptococci, pneumococci, staphylococci, Ba- cillus pneumoniz (Friedlinder), Bacillus subtilis and sarcina. A complete review of the subject with references to the literature has been made by Hasslauer.* The larynx and trachea contain very few bacteria and probably have no permanent parasitic flora. The lungs harbor no bacteria. A few micro-organisms doubtless reach them in the inspired air, but the defensive mechanisms soon dispose of them. AVENUES OF INFECTION The skin seems to form an effectual barrier against the entrance of bacteria into the deeper tissues. A few higher fungi—Tryco- phyton, Microsporon, Achorion, etc.—seem able to establish them- selves in the superficial layers of the cells, invade the hair-follicles, and so reach the deeper layers, where morbid changes are produced. The minute size of the bacteria makes it possible for them to enter through lesions too small to be noticed. Garré applied a pure culture of Staphylococcus pyogenes aureus to the skin of his fore- arm, and found that furuncles developed in four days, though the skin was supposed to be uninjured. Bockhart moistened his skin with a suspension of the same organism, gently scratched it with his finger-nail, and suffered from a furuncle some days later. _ The greater number of surgical infections result from the entrance of bacteria through lesions of the skin. It makes but little difference to what depth the lesion extends—abrasions, punctures, lacerations, incisions—the protective covering is gone and the infecting organ- isms find themselves in the tissues, surrounded by the tissue lymph, under conditions appropriate for growth and multiplication, provided no inhibiting or destructive mechanism be called into action. The digestive apparatus is the portal through which many infec- tions take place. The Bacillus diphtheria, finding its way to the pharynx, speedily establishes itself upon the surface, producing , pseudomembranous inflammation there. Typhoid bacilli, dysentery ameeba and bacilli, cholera spirilla and related organisms, finding their way to the intestine, where the vital conditions are appropriate, take up temporary residence there, to the injury of the host, who may suffer from the respective infections. *“Centralbl. f. Bakt. u. Parasitenk. I. Abt. Referata,”’ Bd. xxxvu, Nos. I-3, p. 1, and Nos. 4-6, p. 97. Avenues of Infection 73 Various organisms pass from the pharynx to the tonsils and so to the lymph-nodes and deeper tissues of the neck, where their first operations may be observed. It is supposed by some pathologists that the digestive tract isa constant menace to health in that it regularly admits bacteria, through the lacteals, and perhaps through its capillaries, to the blood, where under slightly abnormal conditions they might do harm. According to Adami,* the intestine is responsible for a condition of sub-infection depending upon the constant entrance of colon bacilli into the blood. He finds the colon bacillus in the blood, and traces it to the liver, where its final dissolution takes place in the fine dumbbell-like granules enclosed in the cells. Nichollst confirms Adami by finding similar dumbbell or diplococcoid bodies in the epithelial denuded tissues of the mesentery of normal animals. Nicholas and Descos{ and Ravenel§ fed fasting dogs upon a soup containing quantities of tubercle bacilli, killed them three hours later, and examined the contents of the thoracic duct, where tubercle bacilli, some alive and some dead, were found in large numbers. van Steenberghe and Grysez|| found that carbon particles readily passed through the intestinal mucosa, entered the lymphatics, were thrown into the venous circulation, and so carried to the lung, where anthracosis was produced. In a subsequent paper** they believe that they have demonstrated that the tubercle bacillus like the carbon particles may also pass through the normal intestinal wall, and follow the same course to the lungs. They believe that pulmonary tuberculosis thus depends upon ingested and not inhaled micro-organisms. Montgomery fj re- peated the work of van Steenberghe and Grysez at the Henry Phipps Institute, Philadelphia, but though many attempts were made by various methods, no carbon particles seemed to be transported from the alimentary to the pulmonary tissues. But there are enough experiments recorded to make it probable that the wall of the intestine is permeable to bacteria, and that in small numbers they constantly enter the blood of healthy animals, to be disposed of by mechanisms yet to be described. Many of the bacteria penetrating the intestine must be retained in the lymph nodes; others, as in the experiment with the tubercle bacilli, meet destruction before they reach the blood; the remainder must reach the blood alive. The presence of colon bacilli in the greater number of the organs * “Jour. of the American Medical Association,” Dec. 16 and 23, 1899, vol. xxxin, Nov. 25 and 26. ft “Jour. Med. Research,” vol. x1, No. 2. t “Jour. de Phys. et Path. gén.,”’ 1902, Iv, 910-912. § “Jour. Med. Research,” 1904, X, p. 460. al “Ann, de l’Inst. Pasteur,” Dec. 25, 1905, Tome xix, No. 12, p. 787. Ibid., 1310, XxIV, 316. tt “Jour. of Med. Research,” Aug., 1910, vol. xxi, No. 1. 74 Infection shortly after death has led some pathologists to assume that they readily pass through the intestinal walls during the death agony, but although experiments have been made to prove and to disprove it, the matter is still controversial. Undoubtedly in the final dis- solution some change takes place in the constitution of the individual by which general invasion by bacteria is made more easy than under normal conditions. The respiratory apparatus affords admission to a few micro-organ- isms whose activities seem more easily carried on there than else- where. Although it is still controversial whether the inhalation of tubercle bacilli is as frequent a mode of conveying that organism into the body as was once supposed, it cannot be denied that its inhalation will account for the far greater frequency with which tuberculosis affects the lungs than other organs of the body. Pneumonia, caused in an immense majority of cases by the pneu- mococcus of Fraenkel and Weichselbaum, probably results from the entrance of the organism into the respiratory tissues directly. The entrance of the unknown infectious agents causing measles, German measles, smallpox, and scarlatina can best be accounted for by supposing that they are inhaled into the lungs and thus enter the blood. The genital apparatus is the portal of entry of micro-organisms whose early or chief operations are local. Among these are the gonococcus, which causes urethritis, vaginitis, balanitis, posthitis, endometritis, orchitis, salpingitis, vesiculitis, cystitis, odphoritis, sometimes peritonitis, and rarely endocarditis; the bacillus of Ducrey, that causes the chancroid or soft sore; and the treponema of syphilis. In more rare cases other organisms, such as the common cocci of suppuration and the tubercle bacillus, may also be transmitted from individual to individual by sexual contact. The placenta usually forms a barrier through which infectious agents find their way with difficulty. A study of this subject by Neélow* shows that the non-pathogenic organisms do not pass from the mother through the placenta to the fetus. Some patho- genic micro-organisms, however, readily pass through, and a few diseases, such as syphilis, are well known in the congenital form. Pregnant women suffering from smallpox may be delivered of in- fants with marks indicative of prenatal disease. Some common in- fectious agents, such as the tubercle bacillus, seem to infect unborn animals with difficulty. The frequency of antenatal tuberculous infection is, however, somewhat controversial at present, Baum- garten having reached the opinion, exactly the opposite of what is commonly believed, that many children are subject to antenatal infection, though the bacilli subsequently develop and cause disease in only a few of them. *“Centralbl. f. Bakt.,” etc., Aug., 1902, I. Abt., Bd. xxx, Orig., p. 691. Pathogenesis 75 PATHOGENESIS This subject can be understood only through a broad knowledge of the metabolic products of micro-organisms. In general it may be said that the ability of micro-organisms to do harm depends upon the injurious nature of their products. This alone, however, will not explain the phenomena of infection, for inmany cases the in- toxication is subsidiary in importance to the invasive power of the micro-organisms. Some bacteria having but limited toxic powers possess extraordinary powers of invasion, as Bacillus anthracis, and the intoxication becomes important only after the organisms have penetrated to all the tissues of the body. Others, with more active toxic properties, have but limited invasive powers, and a few organisms, growing with difficulty in some insignificant focus, ex- cite actively destructive reactions in the tissues with which they come in contact. Still others, with limited invasive powers, eliminate active toxic substances, soluble in nature, that enter the circulation and act upon cells remote from the bacteria themselves, as in diphtheria and tetanus. The invasive power of the organisms depends upon their ability to overcome the body defenses. This may indicate activity of the infecting organism, or weakness of the defensive mechanism. The relation of these factors is exceedingly complex, only partly under- stood, and will be fully discussed in the chapter upon Immunity. For convenience toxins may be described as intracellular or in- soluble, and extracellular or soluble. The intracellular toxins. Until the investigations of Vaughan, Cooley and Gelston,* and later Vaughan and his associates, Det- weiler,} Wheeler,{ Leach,§ Marshall and Gelston,|| Gelston,** J. V. Vaughan,tt Wheeler,tt Leach,§§ McIntyre,|||| and others, it seemed remarkable that micro-organisms whose filtered cultures contained little demonstrable toxic substance are sometimes able to produce active pathogenic effects. By means of special apparatus in which the micro-organisms could be cultivated in enormous quan- tities, and the disintegration of the micro-organismal masses secured by subjecting them to high temperatures, to the action of mineral acids or autolysis, it was discovered that the colon bacilli, typhoid bacilli, and many supposedly harmless bacteria contain intensely active toxic substances. In all probability some of the toxic sub- stances produced by such means are artefacts, but enough work has been done to prove that insoluble toxic substances are present in such organisms, and the toxic substances obtained by the com- * “Journal of the American Medical Association,” Feb. 23, 1901; “Trans. Assoc. Amer. Phys.,” 1901; ‘“‘American Medicine,” ay Igol. t ‘Trans Asso. Amer. Phys.,” 1902. : Ibid. § Ibid. || Ibid. ** Toid. tt Ibid. tt “Jour. Amer. Med. Assoc.,” 1904, XLII, p. 1000. : §§ Ibid., p. 1003. \||| Ibid., p. 1073. 76 Infection minution of culture masses made-solid and brittle by exposure to liquid air, as suggested by Macfadyen and Rowland; the autolytic digestion of bacteria washed free of their culture fluids and suspended in physiological salt solution, and the dissolution of bacteria by bacteriolytic animal juices clearly prove that endotoxins exist. It seems probable that there is considerable difference in the readiness with which these intracellular toxic substances are given up by the bacteria. From some they seem never to be set free in the bodies of animals into which the bacteria are injected; thus, Bacillus prodigiosus is usually harmless for animals, no matter what quantity is injected, yet active toxic substances can be extracted from the bodies of these organisms by appropriate chemical means. From others they are given off in small quantities either during the life of the organism or at the moment of death and dissolution, as in the case of the typhoid bacillus and streptococci, whose filtered cultures are almost harmless, though both organisms are pathogenic. The intracellular toxins are limited in action by the distribution of the bacteria producing them. When these organisms are but slightly invasive, more or less local reaction is produced; when they are actively invasive, general reactions of varying intensity result. The extracellular toxins, of which those of Bacillus tetani and Bacillus diphtherie can be taken as types, have been known since the early work of Brieger and Frankel and Roux and Yersin. They seem to be excretions of the bacteria, not retained in the cells, but eliminated from them as rapidly as they are formed. ‘Thus, in appropriate bouillon cultures of the diphtheria bacillus, the toxin is present in large quantity and is highly virulent, but if the fluid be removed from the bacteria by porcelain filtration and the remaining bacilli carefully washed, their bodies are found to be devoid of toxic powers. The poison is most concentrated where its diffusion is most restricted, thus, agar-agar cultures of the tetanus bacillus are much more toxic than bouillon cultures because the soluble principle readily diffuses through the fluid, but is held by the agar- agar. The soluble toxin is but.one of numerous metabolic products of the bacteria. Thus in culture filtrates of the tetanus bacillus there are at least two very different active substances, the tetano-spasmin that acts upon the nervous system with convulsive effect, and the tetano-lysin that is solvent for erythrocytes. In all probability all of the culture filtrates of bacteria are highly complex because of the addition of the various metabolic products —toxins, lysins, enzymes, pigments, acids, etc.—of the bacteria, as well as because of changes produced in the medium by the ab- straction of those molecular constituents upon which the bacteria have fed. This complexity makes it difficult to accurately study the toxins, which we scarcely know apart from their associated products. we Specific Action of Toxins 77 The chemic nature of the toxins differs. Undoubtedly some are tox-albumins, but others are of different composition and fail to give the reactions belonging to the compounds of this group. The variations observed in toxicogenesis under experimental conditions in the test-tube indicate that similar variations occur in the bodies of animals, and a few experiments conducted with slight variations in the composition and reaction of the media in which the bacteria grow will suffice’ to show that the exact effect of toxicogenic bacteria in the bodies of different animals cannot always be accurately prejudged. The physiologic and pathogenic action of the extracellular soluble toxins differs from that of the intracellular and difficultly soluble toxins in that it is more easily diffused throughout the animal juices, and that.its diffusion is independent of the invasiveness of the bac- teria, so that a few organisms growing at some focus of unimportant magnitude, and causing but little local manifestation, may be able to produce a profound impression upon remote organs. This is best exemplified in the case of the Bacillus tetani, which, finding its way into the tissues under proper conditions, produces scarcely any local reaction—indeed, the lesion may be undiscoverable— yet may cause the death of the animal through the intensity of its action upon the central nervous system. SPECIFIC ACTION OF TOXINS The metabolic products of the greater number of injurious bacteria are characterized by irritative action upon those body cells with which they come into contact. If through the intracellular nature of the poisons and the mildly invasive character of the micro- organisms this action is restricted to the seat of original infection, a local manifestation will result. Its exact nature will, however, be modified to some extent by other qualities of the bacterial products. Thus, when in addition to their irritative action which, when mild, occasions multiplication of the cells of the connective and lymphoid tissues, and, when extreme, effects the death of the cells, the products are strongly chemotactic, suppuration will occur. Fever and suppuration are, therefore, non-specific actions, because numerous micro-organisms share in common the qualities produc- tive of these conditions. If the bacteria. are rapidly invasive, but still have injurious products of the intracellular variety, they are apt to share certain qualities, such as the swelling of the lymph-nodes, etc., in common, so that such lesions cannot be considered as specific. So soon as any one of the products is discovered to give some single lesion peculiar to that organism by which it is produced, or so soon as the total effect of the activity of the various products of any micro- organism produces a typical effect, differing from the total effect 18 Infection of the operation of other micro-organisms, and a recognized type of disease results, it becomes possible to say that the micro-organism in question is specific. The most striking examples of the specific action of bacterio- toxins is, however, seen in those cases where soluble extracellular metabolic products of bacterial energy are liberated into the body - juices so as to be conveyed by the circulatory system to all parts of the body. ‘Those cells most susceptible to its action are then first or most profoundly impressed by it, and definite responses brought about. Thus, the soluble toxin of tetanus causes no visible reaction in the cells with which it first comes into contact at the seat of primary infection, because these cells are either less sus- ceptible to its influence, or are less well able to show its effects, than the cells of the nervous system to which it is secondarily carried by the blood. SPECIFIC AFFINITY OF THE CELLS FOR THE TOXINS The cells of the connective tissue in which the tetanus bacillus is living show little reaction, but the motor cells of the central nervous system, having a greater affinity for it, are profoundly impressed, so that convulsions of the controlled muscular system are brought about. This special excitation of the nerve cells is specific because no other bacterio-toxin is known to produce it and it is attributed to special selective affinities of the nerve cells for the poison. This affinity has its analogue among the poisons of higher plants, thus, strychnin has a similar selective affinity and is also said to be specific in action upon the motor cells. The venoms of various serpents, especially the cobra, also have specific reactions, the cells of the respiratory centers seeming to be most profoundly affected by them. The diphtheria bacillus, when observed in ordinary throat in- fections, is seen to produce a pseudomembranous angina which results in part from an irritative local action of the organism, which it shares in common with many others, and in part from some coagulating product which it shares in common with a few— pheumococcus, streptococcus, etc. Neither of these reactions is specific, but subsequent to these early manifestations comes de- pressant action on the nervous cells with palsy, peculiar to the prod- ucts of the diphtheria bacillus, and therefore specific. It is upon the peculiar specific reactions of the bacterio-toxins and the peculiar susceptibility of certain cells to this action that the production of distinct clinical manifestations depend. THE INVASION OF THE BODY BY MICRO-ORGANISMS Some bacteria whose invasiveness is insufficient to enable them successfully to maintain life in healthy tissues, occasionally get a The Cardinal Conditions of Infection 79 foothold in diseased tissues and assist in morbid changes. This is seen in what is described as sapremia, in which various sapro- phytic bacteria, possessing no invasive powers, by growing in the putrefying tissues of a gangrenous part, give rise to poisonous sub- stances which when absorbed by the adjacent healthy tissues produce such constitutional disturbances as depression, fever, and the like. Bacteria with limited invasive powers and intracellular toxins can at best occasion local effects. Such organisms not infrequently vary, however, and when of unusual vitality may survive entrance into the blood and lymph circulations and occasion bacteremia, or, as it is more frequently called, septicemia, a morbid condition characterized by the presence of bacteria in the circulating blood. When bacteria entering the circulation are unable to pervade the entire organisms, they may collect in the capillaries of the less re- sisting tissues, producing local metastatic lesions, usually purulent in character. This results in what is surgically known as pyemia. The mode by which the entrance of bacteria into the circulation is effected differs in different cases. Kruse* believes that they some- times are passively forced through the stomata of the vessels when the pressure of the inflammatory exudate is greater than that of the blood within them; that they may sometimes enterinto the bodies of leukocytes that have incorporated them; that they may actually grow through the capillary walls, or that they reach the blood cir- culation indirectly by first following the course of the lymphatics. Toxemia results from the absorption of the poisonous bacterial products from non-invasive bacteria, as in tetanus. THE CARDINAL CONDITIONS OF INFECTION Infection can take place only when the micro-organisms are sufficiently virulent, when they enter in sufficient number, when they enter by appropriate avenues, and when the host is susceptible to their action. Virulence.—Virulence may be defined as the disease-producing power of micro-organisms. It is a variable quality, and depends upon the invasiveness of the micro-organisms, or the toxicity of their products, or both. A few bacteria are almost constant in virulence and can be kept under artificial conditions for years with very little change. Other bacteria begin to diminish in virulence so soon as they are introduced to the artificial conditions of life in the test-tube. Still others, and perhaps the greater number, can be modified, and their virulence increased or diminished according to the experimental manipulations to which they are subjected. Variation in virulence is not always a peculiarity of the species, * Fligge, “Die Mikroorganismen,” vol. 1, p. 271. 80 Infection for the greatest differences may be observed among individuals of the same kind. Thus, the streptococcus usually attenuates rapidly when kept in artificial media, so that special precautions have to be taken to maintain it, but Holst observed a culture whose virulence was unaltered after eight years of continuous cultivation in the laboratory without any particular attention having been devoted to it. What is true of different cultures of the same organisms, is equally true of the individuals in the same culture. To determine such individual differences is quite easy among chromogenic bacteria. If these are plated in the ordinary wayit will be found that some colonies are paler and some darker than others. Conn found that by repeating the plating a number of times and always selecting the palest and darkest colonies he was eventually able to produce two cultures, one brilliant yellow, the other colorless, from the same original ‘stock of yellow cocci from milk. Decrease of virulence under artificial conditions probably depends upon artificial selection of the organisms in transplantation from culture to culture. When planted upon artificial media, the vege- tative members of the bacterial family proceed to grow actively and soon exceed in number their more pathogenic fellows. Each time the culture is transplanted, more of the vegetative and fewer of the pathogenic forms are carried over, until after the organism is accustomed to its new environment, and grows readily upon the artificial media, it is found that the pathogenic organisms have been largely or entirely eliminated and the vegetative forms alone retained. Increase ot virulence can be achieved by artificial selection so planned as to preserve the more virulent or pathogenic organisms at the same time that the less virulent and more vegetative organisms are eliminated. In cases in which no virulence remains, the experi- mental manipulation of the culture is directed toward gradual im- munization of the micro-organisms to the defensive mechanisms of the body of the animal for which the organism is to be made virulent. A number of methods are made use of for this purpose. Passage Through Animals—Except in cases where the virulence of the micro-orgainsm is invariable, it is usually observed that the transplantation of the organism from animal to animal without intermediate culture in vitro greatly augments its pathogenic power. Of course, this artificially selects those members of the bacterial family best qualified for development in the animal body, eliminating the others, and the virulence correspondingly increases. The increase in virulence thus brought about is, however, not so much an increase in the general pathogenic power of the organism for all animals, as toward the particular animalorkind of animal used in the experiments. Thus, in general, the passage of bacteria through mice increases their virulence for mice, but not necessarily The Cardinal Conditions of Infection 81 for cats or horses; passage through rabbits, the virulence for rabbits,. but not necessarily for dogs or pigeons, etc. This specific character of the virulence can be explained by the “lateral-chain theory of immunity,” where it will again be con- sidered. The Use of Collodion Sacs——When cultures of bacteria are en- closed in collodion sacs and placed in the abdominal or other body cavities of animals, and kept in this manner through successive generations, the virulence is usually considerably increased. This is one of the favorite methods used by the French investigators. It keeps the bacteria in constant contact with the slightly modified body juices of the animal, which transfuse through the collodion, and thus impedes the development of such organisms as are not able to endure their injurious influences. Thus it becomes only another way of carrying on an artificial selection of those members of the bacterial family that can endure, and eliminating those that cannot endure the defensive agencies of those juices with which the organ- isms come in contact.* The addition of animal fluids to the culture-media sometimes enables the investigator to increase, and usually enables him to maintain, the virulence of bacteria. A series of generations in gradually increasing concentrations of the body fluid should be employed, until the organism becomes thoroughly accustomed to it. In some cases it may be sufficient to use a single standard mixture, thus: Shawt found that he could exalt the virulence of anthrax bacilli by cultivating them upon blood-serum agar for fourteen generations, after which they were three times as active as cultures similarly transferred upon ordinary agar-agar. The increase of virulence under such conditions probably depends upon the immunization of the bacteria to the body juices of the animals, and this whole matter will be understood after the subject “Immunity”’ has been considered. Number.—The number of bacteria entering the infected anil has a very important bearing upon infection. The entrance of a single micro-organism of any kind is scarcely ever able to cause infection because of the uncertainty of its being able to withstand the changed conditions to which it is subjected. In most cases a considerable number of organisms is necessary in order that some may survive. Park points out that when bacteria are transplanted from culture to culture, under conditions supposed to be favorable, many of them die. It seems not improbable, there- fore, that when they are transplanted to an environment in which are present certain mechanisms for defending the organism against them, ‘many more must inevitably die. The more virulent an organism is, the fewer will be the number required to infect. Marmorek, * Directions for making and using the capsules are given in the chapter upon Animal Experimentation. t “Brit. Med. Jour.,’’ May 9, 1903. 6 82 Infection -in his experiments with antistreptococcic serum, used a streptoccocus whose virulence was exalted by passage through rabbits and in- termediate cultivation upon agar-agar containing ascitic fluid, until one hundred thousand millionth of a cubic centimeter (um cent milliardieme) was fatal for a rabbit. In this quantity it is scarcely probable that more than a single coccus could have been present. Single anthrax or glanders bacilli may infect rabbits and guinea- pigs. Roger found that 820 tubercle bacilli from the culture with which he experimented were required to infect a guinea-pig, when introduced beneath the skin. Herman found that it required 4 or 5 cc. of a culture of Staphylococcus pyogenes to produce suppura- tion in the peritoneal cavity of an animal; 0.75 cc. to produce it beneath the skin; 0.25 cc. in the pleura; 0.05 cc. in the veins and 0.0001 cc. in the anterior chamber of the eye. In experimenting with Bacillus proteus vulgaris, Watson Cheyne found that 5,000,000 to 6,000,000 organisms injected beneath the skin did not produce any lesion; 8,000,000 caused the formation of an abscess; 56,000,000 produced a phlegmon from which the animal died in five or six weeks and 225,000,000 were required to cause the death of the animal in twenty-four hours. In studying Staphylococcus aureus upon rabbits he found that 25,000,000 would cause an abscess, but 1,000,000,000 were necessary to cause death. The Avenue of Infection.—The successful invasion of the body by certain bacteria can be achieved only when they enter it through appropriate avenues. Even when invasion is possible through several channels, the parasite most commonly invades through one that may, therefore, be regarded as most appropriate, and furnishes the typical picture of the infection. Thus, gonococci usually reach the body through the urogenital mucous membranes, where they set up the various inflammatory reactions collectively known as gonorrhea—.e., urethritis, vaginitis, prostatitis, orchitis, cystitis, etc. These constitute the typical picture of the infection. The organism may also successfully invade the conjunctiva, producing blennorrhea, but there is no evidence that gonococci can successfully invade the body through the skin, the respiratory, or alimentary mucous membrane. Typhoid and cholera infections seem to take place through the alimentary mucous membrane, and the evidence that infection takes place by inhalation is slight. It is not known to take place through the urogenital system, the conjunctiva, or the skin. The avenue of entrance not only determines infection, but may also determine the form that it takes. Thus, tubercle bacilli rubbed into the deeper layer of the skin produce a chronic inflammatory disease, called lupus, that lasts for years and rarely results in generalized tuberculosis. Bacilli reaching the cervical or other lymph-nodes by entrance through the tonsils, may remain localized, The Cardinal Conditions of Infection 83 producing enlargement and softening of the nodes, or passing through them reach the circulation, in which they may be carried to the bones and joints and occasion chronic inflammation with necrosis and ultimate evacuation or exfoliation of the diseased mass, after which the patient may recover. Bacilli entering the intestine in many cases produce implantation lesions in the intestinal walls; bacilli inhaled into the lung, or conveyed to it from theintestine by the thoracic duct and veins, produce the ordinary pulmonary tuberculosis known as phthisis or consumption. Inhaled pneumococci colonizing in the pharynx have been known to produce pseudomembranous angina; in the lungs, pneumonia; implanted upon the conjunctiva, conjunctivitis. In these cases we can look upon the type of infection as depending upon the portal through which the invading organism found its way into the tissues. The avenue of entrance is, for obvious reasons, less important when the micro-organism is of some rapidly invasive form, whose chief operation is in the streaming blood or in the lymphatics. Anthrax in most animals is characterized by a bacteremia regardless of the point of primary infection. Bubonic plague rapidly becomes a bacteremia regardless of the entrance of the Bacillus pestis by in- halation into the lungs, or by way of the lymphatics through super- ficial lesions. The failure of the micro-organisms to colonize successfully when introduced through inappropriate avenues may be explained by a consideration of the local conditions to which they are subjected. When they are introduced beneath the skin, bacteria are, in most cases, delayed in reaching the circulation, and are in the meantime subjected to the germicidal action of the lymph and exposed to the attacks of phagocytes. Many succumb to these and never penetrate more deeply into the body. Should any survive, they may be trans- ported to the lymph-nodes and there destroyed, or, passing through these barriers without destruction, and reaching the venous channels, they have next to pass through the pulmonary capillaries, where they are apt to be caught and destroyed. Finally, should any es- cape all these defenses and reach the general circulation, it is to find the endothelium of the capillaries prone to collect and detain them until destruction is finally effected. The systemic circulation is also defended against such micro-organisms as might reach the veins through lesions or accidents of the abdominal viscera, by the inter- position of the portal capillary network of the liver, where the bac- teria are caught and many of them destroyed, or passing which, the pulmonary capillary system acts as a second barrier against them. The deeper the penetration, the more active the defense becomes, the blood itself furnishing agglutinins, bacterio-lysins, and phago- cytes for the destruction of the micro-organisms and the protection of the host. These defenses, however, are of no avail against actively invasive 84 Infection organisms provided with the means of overcoming them all through aggressins that destroy the germicidal humors or éoxins that kill or paralyze the cells. When these are injected directly into the streaming blood they produce their effects more rapidly than when injected beneath the skin or elsewhere, because the field of operation is immediately reached instead of through a roundabout course in which so many defenses have to be overcome. Taking anthrax bacilli, whose invasiveness has already been dwelt upon, as an example, Roger* found that when the orginisms were injected into the aorta, animals died more quickly than when they were injected into the veins and obliged to find their way through the pulmonary capillaries to the general circulation. If the injections were made into the portal vein, the animals stood a good chance of recovery, the liver possessing the power of destroying sixty-four times as many anthrax bacilli as would prove fatal if introduced through other channels. The conditions differ, however, in different infections, for when Roger experimented with streptococci instead of anthrax bacilli, he found that if the bacilli were inoculated into the portal vein the animals died more quickly than when they were injected into the aorta, and that when the bacilli were injected into the peripheral] ‘veins the animals lived longest, the liver seeming to be far less destructive to streptococci than the lungs. The Susceptibility of the Host——Susceptibility is liability to in- fection. It is a condition in which the host is unable to defend itself against invading micro-organisms. Unusual or unnatural suscep- tibility is also spoken of as predisposition or dyscrasia. Many animals and plants are naturally without any means of overcoming the invasiveness of certain parasitic micro-organisms, and are, therefore, naturally susceptible; others naturally resist their inroads, but through various temporary or permanent physio- logic changes may lose the defensive power. In general, it is true that any condition that depresses or diminishes the general physiological activity of an animal diminishes its ability to defend itself against the pathogenic action of bacteria, and so predisposes to infection. These changes are often so subtile that they escape detection, though at times they can be partly understood. The inhalation of noxious vapors. It has long been supposed that sewer gas was responsible for the occurrence of certain in- fectious diseases, and when the nature of these diseases was made clear by a knowledge of their bacterial causes, the old belief still remained and many sanitarians continued to believe that defective sewage is in some way connected with their occurrence. It is difficult to prove or disprove the matter experimentally. Men who work in sewers and plumbers who breathe much sewer gas are not apparently affected by it. Alessif found that rats, rabbits, and **Tntroduction to the Study of Medicine,” p. 151. t “Centralbl. f. Bakt.,” etc., 1894, xv, p. 228. The Cardinal Conditions of Infection 85 guinea-pigs kept in cages some of which were placed over the open- ing of a privy, while in others the excreta of the animals were allowed to accumulate, suffered from a pronounced diminution of the resisting powers. This would seem to be inconsistent with the habits of rats, many of which live in sewers. Abbott* caused rabbits to breathe air forced through sewage and putrid meat infusions for one hundred and twenty-nine days, and found that the products of decomposition inhaled by the animals played no part in producing disease, or in inducing susceptibility to it. Fatigue is a well-recognized clinical cause of susceptibility to disease, and experimental evidence of its correctness is not wanting. Charrin and Rogert{ found that white rats, which naturally resist infection with anthrax, succumbed to the infection if compelled to turn a revolving wheel until exhausted before inoculation. Exposure to cold seriously diminishes the resisting power of the warm-blooded animals. It is an everyday experience that chilling the body predisposes to “cold”? and may be the starting-point of pneumonia.: Pasteur found that fowls, which resist anthrax under normal conditions, succumbed to infection if kept, for some time, in a cold bath before inoculation. The reverse seems to be true of the cold-blooded animals, for Gibier{ found that frogs, naturally resistant to the anthrax bacillus, would succumb to infection if kept at 37°C. after inoculation. Diet produces some variation in the resisting powers. The tendency of scorbutics to suffer from infectious disordersof the mouth, the frequency with which epidemics of infectious disease follow famines, and the enterocolitis of marasmatic infants, illustrate the effects of insufficient food in predisposing to disease. We also find that the infectious diseases of carnivorous animals are not the same as those of herbivorous animals, and that the former are exempt from many disorders to which the latter quickly succumb. Hankin was able to show experimentally that meat-fed rats resisted anthrax infection far better than rats fed upon bread. Intoxication of all kinds predisposes to infection. Platania§ found that such animals as frogs, pigeons, and dogs became sus- ceptible to anthrax when under the influence of curare, chloral, andalcohol. Leo|| found that white rats fed upon phloridzin became susceptible to anthrax. Wagner** found that pigeons become sus- ceptible to anthrax when under the influence of chloral. Abbotttt found the resisting powers of rabbits against Streptococcus pyogenes and Bacillus coli diminished by daily intoxication with 5 to 15 c.c. *“Trans. Assoc. Amer. Phys.,”’ 1895. t Compte rendu Soc. de Biol de Paris,” Jan. 24, 1890. ¢ “Compte rendu Acad. des Sciences de Paris,” 1882, t. a P. 1605. § See Sternberg’s “Immunity and Serum Therapy,” p. “Centralbl. f. Bakt.,” etc., Bd. vu, p. 405. | ‘Zeitschrift fiir Hyg.,” mae Bd. vu, p. 505. *“Wratsch,” 1890, 30, 40- tt “Jour. of Exp. Med.,”’ 1896, vol. 1, No. 3. 86 Infection of alcohol introduced into the stomach through a tube. Salant* found that alcohol was disadvantageous in combating the infectious diseases because it diminished the glycogen content of the liver which Collat had found an important adjunct in supporting the resisting power. It is a common clinical observation that excessive indulgence in alcohol predisposes to certain infections, notably pneumonia, ‘and every surgeon knows the danger of pneumonia after anesthetiza- tion with ether. Traumatic injury and mutilation of the body are not without effect upon infection. The more extensive the damage done to the tissues, the greater the danger of infection, and the more serious the consequences of infection when it takes place. The mutilation of the body by the removal of certain organs is of disputed importance. There is much literature upon the effect of the spleen in overcoming infectious agents, but the experimental evidence seems about equally divided as to whether an animal is more or less susceptible after the removal of this organ than it was before. Morbid conditions in general predispose to infection. The fre- quency with which diabetics suffer from furuncles, carbuncles, and local gangrenous lesions of the skin; the increased susceptibility of phthisics to bronchopneumonia of other than tuberculous origin; the apparent predisposition of injured joints and pneumonic lungs to tuberculosis; the extensive streptococcus invasions accompany- ing scarlatina and variola; the presence of Bacillus icteroides and various other organisms in the blood and tissues of yellow fever patients, and the presence of Bacillus suipestifer in the bodies of hogs suffering with hog cholera, all show the diminution in the gen- eral resisting power of an individual already diseased. MIXED INFECTIONS The general prevalence of bacteria determines that few can enter and infect the body of a host without the association of other kinds. Therefore their operation in the body is subject to modifica- tions produced in them or in the host by these associated organisms. In experimental investigations this fact is not infrequently for- gotten, and it is often remarked with surprise that the results of inoculation with pure cultures of a micro-organism may be clinically different from those observed under natural conditions. The tetanus bacillus, which endures with difficulty the effects of uncombined oxygen, flourishes in association with saprophytic organisms by which the oxygen is absorbed. The same thing is probably true of other obligatory anaérobic organisms. oC Jour. Amer. Med. Assoc.,”’ 1906, xtvit, 18, Nov. . 1467. t Archiv. Ital. de Biologie,” xxvr.’ - eos Mixed Infections 87 The metabolic products of one species may intensify or accelerate the action of those of an associated species, or the reverse may be true, and the products of different organisms, having different chemical composition, may neutralize one another, or combine to form some entirely new substance which is entirely different from its antecedents. Such conditions cannot fail to influence the type and course of infection. CHAPTER IV IMMUNITY ImmUNITY is ability to resist infection. It is the ability of an organism successfully to antagonize the invasive powers of parasites, or to annul the injurious properties of their products. The mech- anism of immunity is complicated or otherwise according to cir- cumstances. When the invasive action of non-toxicogenic bacteria is to be overcome, certain reactions, mostly on the part of the phago- cytic cells, are called into action; when the toxic products of bacteria are to be deprived of injurious effects, the reaction seems to take place between the toxin and certain combining and neutralizing substances contained in the body juices; when bacterial invasion and intoxication are both to be antagonized, both mechanisms are engaged in the defenses, comparatively simple or exceedingly com- plex, according to the conditions involved. The more involved the conditions of infection become, the more complicated the defensive reactions become, until it may no longer be possible accurately to analyze them. Some have endeavored to refer all of the phenomena of im- munity to the ability of the animal to endure the bacterio-toxins, and have sought to relegate the reactions against invasion to a subsidiary place. This is undoubtedly an error, as the mechanisms are different and the prompt action of one may make the action of the other unnecessary. Metschnikoff* found that frogs injected with 0.5 cc. of cholera toxin died promptly, but that frogs injected with cultures of the cholera spirillum recovered. without illness. This would suggest that the recovery of the infected frog depended upon some defensive mechanism combating the invasiveness of the bacteria and so preventing the production of the toxin to which the frog was susceptible. Immunity must not be conceived as something inseparably. associated with infection. The reactions of the body toward bacteria in the infectious diseases are identical with those toward other minute irritative bodies, and the reactions toward bacterio- toxins are identical with those toward other toxic substances, so that the only way by which a satisfactory understanding of the . phenomena can be reached is by carefully comparing the reactions produced by bacteria and their products with those produced by other active bodies. *“Tmmunite dans les Maladies Infectieuses,” Paris, 1901, p. 150. 88 Natural Immunity 89 Immunity is called active when the animal protects itself through its own activities, passive when the protection depends upon defen- sive substances prepared by some other animal entering into it. Thus, if a frog be injected with anthrax bacilli, its leukocytes de- vour the bacteria, destroy them, and so protect the frog from in- fection; the immunity is active because it depends upon theactivity of the frog’s phagocytes. But if a guinea-pig previously given anti- tetanic serum be injected with tetanus toxin, and so recovers from the toxin, the resisting power, conferred by the antitoxin previously injected, does not depend upon any activity of the animal, which -remains entirely passive. Immunity is largely relative. Fowls are immune against tetanus, that is, they can endure, without injury, as much toxin as tetanus bacilli can produce in their bodies, and suffer no ill effects from in- oculation. If, however, a large quantity of tetanotoxin produced in a test-tube be introduced into their bodies, they succumb to it. Mongooses and hedgehogs are sufficiently immune against the venoms of serpents to resist as much poison as is ordinarily injected by the serpents, but by collecting the venom from several serpents and injecting considerable quantities of it, both animals can be killed. Rats cannot be killed by infection with Bacillus diphtherie, and Cobbett* found that they could endure from 1500 to 1800 times as much diphtheria toxin as guinea-pigs, though more than this would kill them. Carl Frankel has expressed the whole matter very forcibly when hesays: ‘‘A white ratisimmune against anthrax in doses sufficiently large to kill a rabbit, but not necessarily against a dose sufficiently large to kill an elephant.”’ NATURAL IMMUNITY Natural immunity is the natural, inherited resistance against infection or intoxication, peculiar to certain groups of animals, and common to all the individuals of those groups. Few micro-organisms are capable of infecting all kinds of animals; indeed, it is doubtful whether any. known organism possesses such universally invasive powers. The micro-organisms of suppuration seem able to infect animals of many different kinds, sometimes producing local lesions, some- times invading rapidly with resulting bacteremia. The tubercle bacillus is known to be pathogenic for mammals, birds, reptiles, batrachians, and fishes, though it is still uncertain whether the infecting organisms in these cases are identical or slightly differing species. As a rule, however, the infectivity of bacteria and other micro- organisms is restricted to certain groups of animals which usually * “Brit. Med. Jour.,” April 15, 1899. go Immunity have more or less resemblance to one another; thus, anthrax is essentially a disease of warm-blooded animals, though certain exceptions are observed, and Metschnikoff has found that hippo- campi (sea-horses), perch, crickets, and certain mussels are sus- ceptible. Among the warm-blooded animals anthrax is most fre- quent among the herbivora, though some carnivora may also be infected. Close relationship is not, however, a guarantee that animals will behave similarly toward infection. The rabbit, guinea-pig, and the rat are rodents, but though the rabbit and guinea-pig are susceptible to anthrax, the rat is immune. This is still better exemplified in the susceptibility of mice to glanders. The field- mouse seems to be the most susceptible of all animals to infection with Bacillus mallei; the house mouse is much less susceptible, and the white mouse is immune. Mosquitos, though closely related, are different in their immunity to the malarial parasite. The culex does not harbor the parasite at all, and of the anopheles, two very similar species seem to behave very differently. Anopheles maculipennis being the common definitive host of the parasite, “while Anopheles punctipennis is not known to be susceptible to it. The same differences may exist among the members of the human species. It has been asserted that Mongolians, and especially Japanese, are immune against scarlatina, and that negroes are ‘immune against yellow fever, but increasing information is to the contrary. Human beings suffer from typhoid, cholera, measles, scarlatina, yellow fever, varicella, and numerous other diseases unknown among the lower animals, even those domestic animals with which they come in close contact. They also suffer from Malta fever, anthrax, rabies, glanders, bubonic plague, and tuberculosis, which are common among the lower animals. Animals, in turn, suffer from distemper, septicemia, etc., the respective micro-organisms of which are not known to infect man. It has already been pointed out that mongooses and hedgehogs are immune against the venom of serpentsfrom which other animals quickly die. The tobacco-worm lives solely upon tobacco-leaves, the juice of which is intensely poisonous to higher animals, and is also a good insecticide. Boxed cigars and baled tobacco are often ruined by the larve of a small beetle that feeds upon them, and a glance over the poisonous vegetables will show that few of them escape the attacks of insects immune against their juices. These facts are sufficient to show that many animals are by nature immune against the invasion of microparasites of certain kinds, and that they are also at times immune against poisons. Immunity against one kind of infection or intoxication is, however, entirely independent of all other infections and intoxications. Im- munity against infection usually guarantees exemption from the Acquired Immunity gt toxic products of that particular micro-organism, though experi- ment may show the animal to be susceptible to it. Immunity against any form of bacterio-toxin usually, though not necessarily, determines that the micro-organism, though it may be able to invade the body, can do very little harm. ACQUIRED IMMUNITY Acquired immunity is resistance against infection or intoxica- tion possessed by certain animals, of a naturally susceptible kind, in consequence of conditions peculiar to them as individuals. It isa peculiarity of the individual, not of his kind, and signifies a subtile change in physiology by which latent defensive powers are stimulated to action. The reactions in general correspond with those of natural immunity, and comprise mechanisms for overcoming the invasion of pathogenic organisms, for neutralizing or destroying their toxins or for both. As an acquired character and an individual peculiarity it is not transmitted to the offspring, though these sometimes also acquire immunity through the parents. Thus in studying im- munity of mice against ricin, Ehrlich found that the newly born offspring of an immune mother were not immune, though they subsequently became so through her milk. Acquired immunity differs from natural immunity in being more variable in degree and duration. The animal may be immune to-day, but lose al! power of defending itself a month hence. Natural immunity is always active, but certain forms of acquired immunity are passive. Immunity may be acquired through infection or intoxication, and in either case may be accidental or experimental. (A) Active Acquired Immunity.—1. Immunity Acquired through Infection.—(a) Accidental Infection——The most familiar form of acquired immunity follows an attack of an infectious disease. Every one knows that an attack of measles, scarlatina, varicella, variola, yellow fever, typhoid fever, and other common infectious maladies, is a fairly good guarantee of future exemption from the respective disease. Immunity thus acquired is not transmissible to the off- spring. Almost everybody has had measles, yet almost all children . are born susceptible to it. It is not necessarily permanent, as is shown by the not infrequent cases in which second attacks of measles occur. In some cases, as after typhoid fever, the immunity is not at first observable and the patient may suffer from relapses. Later it becomes well-established and no repetition of the disease is possi- ble for years. Sometimes the infection, by which immunity is acquired, is not exactly similar to the disease against which it affords protection, as in the case of vaccinia, which protects against variola. It is still controversial, however, whether cow-pox is variola of the cow 92 Immunity or an entirely different disease. Cow-pox, was, however, common in the days when smallpox was frequent, and has now become extremely rare. (b) Experimental Infection—1. Inoculation: This is an attempt to prevent the occurrence of a fatal attack of an infectious disease, by inducing a mild attack of the same disease when the individual is in good health, and at his maximum resisting power. The oldest experiments date from unknown antiquity and were practised in China and other Oriental countries for the purpose of preventing smallpox. The Chinese method of experimentally producing variolous infection was very crude and consisted in introducing crusts from cases of variola into the nose, and tying them upon the skin. The Turkish method was much more neat, in that a small quantity of the variolous pus was introduced into a scarification upon the skin of the individual to be protected. The following extract is from a letter of Lady Montague,* wife of the British Ambassador to Turkey, who brought the so-called ‘‘inoculation” method from Turkey in the early part of the eighteenth century (1718): “« . , . . Apropos of distempers, I am going to tell you a thing that I am sure will make you wish yourself here. The smallpox, so fatal, and so general amongst us, is here entirely harmless by the invention of ingrafting, which is the term they give it. There is a set of old women who make it their business to perform the operation every autumn, in the month of September, when the great heat is abated. People send to one another to know if any of their family has a mind to have the smallpox; they make parties for this purpose, and when they are met (commonly fifteen or sixteen together), the old woman comes with a nut-shell full of the matter of the best sort of smallpox, and asks what vein you please to have opened. She immediately rips open that you offer to her with a large needle (which gives you no more pain than a common scratch), and puts into the vein as much venom as can lie upon the head of her needle, and after binds up the little wound with a hollow bit of shell; and in this manner opens four or five veins. The Grecians have commonly the superstition of opening one in the middle of the forehead, in each arm, and on the breast, to mark the sign of the cross; but this has a very ill effect, all these wounds leaving little scars, and is not done by those that are not superstitious, who choose to have them in the legs, or that part of the arm that is concealed. The children of young patients play together all the rest of the day, and are in perfect health to the eighth. Then the fever begins to seize them, and they keep their beds two days, very seldom three. They have very rarely above twenty or thirty [pocks] in their faces, which never mark; and in eight days’ time they are as well as before their illness. Where they are wounded, there remain running sores during the distemper, which I don’t doubt is a great relief to it. Every year thousands undergo this operation; and the French embassador says pleasantly, that they take the smallpox here by way of diversion, as they take the waters in other countries. There is no example of any one that has died in it; and you may believe I am very well satisfied of the safety of this experiment, since I intend to try it on my dear little son. “T am patriot enough to take pains enough to bring this useful invention into fashion in England; and I should not fail to write to some of our doctors very particularly about it, if I. knew any one of them that I thought had virtue enough to destroy such a considerable branch of their revenue for the good of mankind. But that distemper is too beneficial to them not to expose to all their resentment the hardy wight that should undertake to put an end to it.” * See the “Letters of Lady Mary Wortley Montague;” letter to Miss Sarah Chisives dated Adrianople, April 1 (O. S.), 1717. Vaccination 93 By both methods the very disease, variola, against which protec- tion was desired, was induced, the only advantage of the experi- mental over the accidental infection being that by selecting the infective virus from a mild case of variola, by performing the operation at a time when no epidemic of the disease was raging, and by doing it at a time when the person infected was in the most perfect physical condition, the dangers of the malady might be mitigated. There was always danger, however, that the induced disease being true variola might prove unexpectedly severe, or even fatal, and that each inoculated individual, suffering from the contagious dis- ease, might start an epidemic. 2. Jennerian vaccination: In 1791 a country schoolmaster named Plett, living in the town of Starkendorf near Kiel in Germany, seems to have made the first endeavor to subject the oft-repeated observation, that persons who had acquired cow-pox did not subse- quently become infected with smallpox, to experimental demon- stration, by inserting cow-pox virus into three children, all of whom escaped smallpox. The father of vaccination, and the man to whom the world owes one of its greatest debts, was Edward Jenner, who performed his first experiment on May 14, 1796, when he transferred some of the contents of a cow-pox pustule on the arm of a milkmaid named Sarah Nelmess to the arm of a boy named John Phips. After the lad had recovered from the experimental cow-pox thus produced, he subsequently introduced smallpox pus into his arm and found him fully immunized and insusceptible to the disease. This led Jenner to perform many other experiments, and record his ob- servations in numerous scientific memoirs. The success of his work immediately attracted the attention of both scientific investi- gators and sanitarians, and its outcome has been the establishment of compulsory vaccination by legal enactment in nearly all civilized countries, with the result that smallpox, instead of being one of the most prevalent and most dreaded diseases, has become one of the most rare and least feared. The immunity acquired through vaccination is active and usually of prolonged duration. It is subject to the same variations ob- served in other experimentally acquired immunities, these varia- tions explaining the occasional failures which constitute the “stock in trade” of those who still remain unconvinced of the scientific basis and efficacy of the procedure. Though a thorough analysis of the irregularities and exceptions of vaccination would be of much interest, a brief mention of the most important must suffice for the present argument. The first controversial point is the nature of the “vaccine,” or virus used in the operation. It is obtained from calves or heifers suffering from experimental cow-pox, and is a virus descended from © 94 Immunity various spontaneous cases of cow-pox observed in places remote from one another. Experts are undecided whether cow-pox is variola modified by passage through the cow so that the transplanted micro-organisms are only capable of inducing a local instead of a general disease, or whether it is an independent affection natural to the cow. In reality the matter is unimportant, so long as the desired effect is accomplished, and the true lineage of the virus is only a matter of scientific curiosity. As immunity is almost invariably a specific effect resulting from infection, it would seem most likely that cow- pox and smallpox were originally identical. The advantage of “vaccination” over “inoculation” is that the induced disease is local and not dangerous except in rare cases, and that it is not contagious. The natural variations in the sus- ceptibility of different vaccinated individuals determine that afew ‘persons cannot be successfully vaccinated, being immune to the mildly invasive organisms of vaccinia, though perhaps susceptible to the actively invasive organisms of variola; that a few individuals shall prove abnormally susceptible to vaccinia so that the disease departs from its usual local type and generalizes, but that in nearly all cases the disease will follow the well-known type of a local lesion characterized by definite periods of ineubanon, vesiculation, pustulation, and cicatrization. The occasional variations in immunity of different individuals also determine that having been vaccinated once an individual may not again become susceptible to vaccination, though he may become susceptible to the more actively invasive organisms of variola, or that he may soon become again susceptible to both diseases, or that in very rare cases no immunity against variola will result from vaccination. In most cases successful vaccination can be repeated once or twice at intervals of seven or ten years, and experience shows that the immunity against smallpox conferred by vaccination is of longer duration and usually becomes permanent after vaccination has been repeated once or twice. Sanitarians are accustomed to speak of efficient and inefficient vaccination. ‘These are vague terms and do not seem to be under- stood by the laity. Efficient vaccination is vaccination repeated as often as is necessary. It has already been shown that individual variations determine that a few individuals never become immune, hence never can be efficiently vaccinated. Other persons are efficiently vaccinated by a single operation. The term is usually interpreted to indicate that which experience has shown to be efficient in average cases. Failures not uncommonly result from causes having nothing to do with the problems of immunity. That an operation of scarifica- tion has been performed upon a child, and that a scar has remained thereafter may mean nothing. It is not the operation but the dis- Vaccination 95 ease that achieves the result, and if the operation be improperly done, poor—i.e., old or inert—matter introduced, or if after intro- duction it be destroyed by the application of antiseptics, no effect can be expected. Hence all persons that have been vaccinated may not have had vaccinia, the essential condition leading to immunity. Nor does the occurrence of a local lesion act as a guarantee that vaccinia has been induced. Careful examination of the resulting lesions should always be made, that the type of the infection may be studied. It is the disease, vaccinia, that must occur—three days’ incubation, three days’ vesiculation, three days’ pustulation, and subsequent cicatrization with the formation of a punctate scar. An arm may be made very sore, may suppurate or even become gangrenous, without vaccinia having occurred or the desired benefit attained. The accidents of vaccination were formerly numerous and some- times disastrous because of the general inattention to the quality of the materials used, the mode of inserting them, the condition of the patient’s skin, and the careless treatment of the resulting lesions. When human virus was used, that is, matter taken from a vaccinia lesion from a human being, the transmission of human diseases, such as syphilis and erysipelas, occasionally took place; now these are rare accidents indeed, because no virus is employed except that taken from carefully selected and treated calves or heifers. When no attention was paid to the quality of the bovine virus, and no governmental inspection of laboratories required, the accidental contamination of the virus occasioned a small number of accidental infections of the wound. There are a good many cases of phlegmon, gangrene and tetanus in the older literature. But these evils are becoming less and less as greater attention is given to the selection and preparation of the virus. Some accidents and some few deaths there will probably always be, just as there are occasional accidents and occasional fatal results following all kinds of trivial injuries, though care will eliminate them as the sources of accident are bet- ter understood. 3. Pasteurian vaccination or bacterination: Although the word vaccination is derived from the Latin vacca, “a cow,” and was first employed in connection with Jenner’s. method of introducing virus modified by passage through a cow, Pasteur, in honor of Jenner, applied it to every kind of protective inoculation, and the word bacterination is only introduced for the purpose of indicating certain differences ia the method. In 1880 Pasteur* observed that some hens inoculated with a sei ture of the bacillus of chicken cholera that had been on hand for some time did not die as was expected. Later, securing a fresh and virulent culture, these and other chickens were inoculated. The former hens did not die, the new hens did. Quick to observe and * “Compte rendu de la Soc. de Biol., 1880, 239; 315 et seq. 96 Immunity study phenomena of this kind, he investigated and found that when chickens were inoculated with old and non-virulent cultures they acquired immunity against virulent cultures. This led him to the recommendation of the employment of attenuated cultures as vaccines against the disease, and to the achievement of great success in preventing epidemics by which great numbers of the barnyard fowls of France were being destroyed. In 1881 Pasteur,* in experimenting with Bacillus anthracis, ob- served that if the organism were cultivated at unusually high tem- peratures it lost the power of producing spores, and diminished in virulence. He also found that when the organisms had been so attenuated, they could not regain virulence without artificial manipu- lation. It occurred to him that such organisms, possessing feeble virulence, might be able to confer immunity upon animals into which they were inoculated, and he continued to investigate the subject until he found that by using three “vaccines” or modified cultures of increasing virulence, it was possible to render animals immune against the unmodified organisms. This method was put to practical test with great success, and has since been extensively practised in different parts of the world. Arloing, Cornevin and Thomas, and Kitt{ found that exposure of the Bacillus anthracis symptomatici to a high temperature in the dry state modified its virulence and devised a practical method of protecting cattle against symptomatic anthrax by inoculating them with powdered muscle tissue containing the bacilli attenuated by drying and exposure to 85°C. This method has since been in use in many countries, and has given excellent satisfaction. In 1889 Pasteur,§ continuing his researches upon the experimental modification of the germs of disease and their use as prophylactics, published his famous work upon rabies, and showed that, although the micro-organism of that disease had so far eluded discovery, it was contained in the central nervous system of diseased animals, where it could be modified in virulence by drying. By placing spinal cords removed from rabid rabbits in a glass jar containing calcium chlorid, he was able to diminish the virulence of the contained micro-organisms according to the duration of the exposure. The introduction of the attenuated virus was followed by the development of a certain degree of immunity. By repeated inoculation of more and more active viruses animals acquired complete immunity against street virus. These experiments formed the basis of the ‘Pasteur method” of treating rabies, which is nothing more than immuniza- tion with the modified germs of the disease during the long incubation period of the disease. *“Compte rendu de la Soc. de Biol. de Paris,” 1881, xcrt, pp. 662-665. 1 “Le Charbon Symptomatique du Beeuf,” Paris, 1887. ; t“Centralbl. f. Bakt.,” etc., 1, p. 684. §‘‘Compte rendu de la Soc. de Biol. de Paris,” 1881, cviu, p. 1228. Immunity Acquired by Intoxication 97 Haffkine* found that the introduction of killed cultures of virulent cholera spirilla produced immunity against the living micro-organ- isms, and used the method with considerable success for preventing the disease. Latert he applied the same method, also with consider- able success, for the prevention of bubonic plague, and A. E. Wrightt followed pretty much the same method for the prevention of typhoid fever. In all these cases the immunity induced by the experimental manipulations is specific in nature,-and variable in intensity, ac- cording to the method of treatment adopted and the thoroughness with which it is carried out. 2. Immunity Acquired by Intoxication.—Bacterio-toxins form a miscellaneous group of active bodies of entirely different chemical composition and physiologic activity. Some are toxalbumins, some are enzymes, some are bacteric-proteins, The true nature of the greater number of these bodies is unknown, but study of their physiologic action has brought forth the important fact that their behavior toward the body cells is in no way different from the behavior of the same cells toward other chemical compounds of similar constitution, and that nearly all physiologically active bodies introduced into living organisms produce definite, though not necessarily visible, reactions. Such reactions are now known as antigenic, and the substances by which they are induced have been called by Deutsch antigens.§ Since its introduction the precise meaning given the word by Deutsch has been slightly changed. An antigen is any substance which when injected into the body of a living organism is capable of pro- ducing a chemicophysiologic reaction resulting in the appearance of a neutralizing, precipitating, agglutinating, dissolving, or other- wise antagonizing substance known as an antibody. The antigens are, so far as known, all colloidal substances. They may be harmful or harmless, active or inert, living or dead, organized or unorganized. The reactions are specific and the antibody has specific affinity for that antigen alone by which its formation has been excited. All poisonous substances are not antigens, even though a certain immunity—in the sense of habituation or tolerance—may follow their repeated administration. One may become habituated or tolerant to a certain quantity of mercury or arsenic, and to certain alkaloids, such as morphin, caffein, nicotin, cocain, etc., but he does not react as to them as to antigens and no antibodies an- tagonistic to them are formed. To these various substances he really acquires only a slight degree of tolerance; to the effects of * “Brit, Med. Jour.,” 1891, Il, p. 1278. t ‘* Brit. Med. Jour.,” 1895, 11, p. 1541. { Ibid., Jan. 30, 1897, 1, p. 256. ; — . § Deutsch und Feistmantel, ‘‘ Die Impfstoffe und Sera,” 19¢3, Leipzig, Thieme. 7 * 98 Immunity injurious antigens he may acquire an almost unlimited degree of immunity through the formation of the antibodies. From remote antiquity it has been known that those who regularly consume small quantities of poisons become irresponsive to their action, and it is well known that Mithridates attempted this mode of defending himself from his enemies. _ Chauveau* believed that the immunity conferred by inoculations of bacteria was due to the presence of their soluble products, but the first direct demonstration of the fact was by Salmon and Smith, } who, as early as 1886, showed that it was possible to immunize pigeons against the hog-cholera bacillus by means of repeated injection with cultures exposed to 60°C., and containing no living organisms. Charrin{ found it possible to immunize rabbits against Bacillus pyocyaneus by injecting them with the filtered products of cultures of that organism, and Bonome§ similarly to immunize animals against Bacillus proteus, B. cholera gallinarum and the pneu- mococcus. Roux and Chamberland|| and Roux** were able by the use of boiled cultures of the bacilli of malignant edema, and of quarter evil, similarly to immunize animals against these respective infections. The subject was much further elaborated by Roux and Yersinf{ in their experiments with diphtheria toxin; by Behringt{ in his early studies of diphtheria, and by Kitasato§§ in his experiments with tetanus. These early experiments opened a wide field, through the investiga- tion of which we now know that the products as well as the living or dead bacteria of most of the infectious diseases, when properly introduced into animals, can induce immunity. (B) Passive Acquired Immunity.—Passive immunity is always acquired, never natural. It depends upon defensive factors not originating in the animal protected, but artificially or experimentally supplied toit. Thefundamental principleis simpleand has become the basis of serum therapeutics. If the immunized animal generates factors by which the infecting bacteria can be destroyed or the activity of their products overcome in its body, cannot these factors be removed and the benefit they confer transferred to another animal? The first experiments in this direction seem to have been made by Babes and Lepp,|||| who found that the blood-serum of animals *“ Ann. de l’Inst. Pasteur,” 1888, 2. t “Centralbl. f. Bakt.,” etc., 1887, 1, No. 18, p. 543. t “Compte rendu,” de la Soc. de Biol., cv, p. 756. § “Zeitschrift £. Hyg.,” v, p. 415. I “Ann. de l’Inst. Pasteur,” 1887, 12. ** Ibid., 1888, 2. Tt Ibid., 1888, 1, p. 269. tt “Deutsche med. Wochenschrift,” 1890, No. 50. §§ “ Zeitschrift fiir Hygiene,” 1891, x, p. 267. |||| “Annales de l’Inst. Pasteur,” 1889, vol. 1. Passive Acquired Immunity 99 immunized to rabies showed a defensive power when injected into other animals. Ogata and Jasuhara* found that the subcutaneous injection of blood-serum from an animal immunized against anthrax enabled the injected animals successfully to resist infection. Behring and Kitasatot found that the blood-serums of animals immunized against diphtheria and tetanus, when mixed with cultures of these respective bacilli, neutralized their power to produce disease. Kitasatot found that if mice were inoculated with tetanus bacilli, they could be saved from the fatal infection by the intra-abdominal injection of some blood-serum from a mouse immunized against tetanus, even after symptoms of the disease had appeared. Ehrlich§ showed that the blood-serums of animals immunized against abrin and ricin could save other animals from the fatal effects of these respective toxalbumins; Phisalix and Bertrand,|| and, later, Cal- mette** found the blood-serum of animals, immunized against the venoms of serpents, similarly possessed the power of neutralizing the poisonous effects of the venoms. Kossel{f found that the blood- serum of animals, immunized against the poisonous blood-serum of eels, contained a body which destroyed or neutralized the effects of the eels’ serum. Thus, it is shown that in each case in which defensive reactions are stimulated in experiment animals, the reactions are accompanied by the appearance in the blood-serum of those animals of factors that can be utilized to defend other animals in whose bodies no similar reactions have taken place. Passive immunity may also be brought about in a few cases by the injection into the intoxicated animal of substances, other than immunity products, that have a specific affinity for the poison. - Thus Wassermann and Takakift found that when the crushed spinal cord of a rabbit was mixed im vitro with tetanus toxin, the poison was quickly absorbed by the nerve-cells, so that the mixture became inert and could be injected into animals without harm. Wasser- mann also found that the same effects could be produced in the bodies of animals, and that when the crushed spinal cord was injected into an animal a few hours previously, or a few hours after a fatal dose of tetanus toxin, enough of the combining elements re- mained in the blood to fix the toxin before it anchored itself to the central nervous system of the intoxicated animal. Myers§§ found that the ground-up tissue of the adrenal bodies was able to fix and thus annul the poisonous effects of cobra venom in vitro. *“Centralbl. f. Bakt.,” etc., 1890, Ix, p. 25. Tt “Deutsche med. Woch.,” 1890, No. 49. t “Zeitschrift fiir Hygiene,” 1892, x11, p. 256. § “Deutsche med. Wochenschrift,”’ 1891, Nos. 32 and 44. al * Compte rendu Acad. des Sciences de Paris,”’ CXVIII, p. 556. Ann. de l’Inst. Pasteur,” 1894, VIII, p.. 275. tt “Berliner klin. Woch.,” 1898, p. 152. tt “Berliner klin. Wochenschrift,” Jan. 3, 1898. §§ “Lancet,” July 2, 1898. 100 Immunity In all these cases the neutralizing effects are either accomplished or initiated by factors prepared experimentally, and forced upon the animal in whose body their activities are manifested. EXPERIMENTAL INVESTIGATION OF THE PROBLEMS OF IMMUNITY Very important contributions were made by Ehrlich,* in his work upon the vegetable toxalbumins, ricin, abrin, and robin, . that were found to be antigens capable of producing anti-ricin, anti-abrin and anti-robin respectively, each antibody being capable of neutralizing the effect of its specificantigen. Kosself investigated the reactions produced by toxic eels’ blood and found that im- munity could be established against their hemolytic action, and that specific antibodies were formed. Phisalix and Bertrand{ showed that immunity could also be produced in guinea-pigs against the action of viper venom, and that a specific antibody, “antivenene” was the source of the immunity. The investigation of other active bodies was soon begun. In 1893 Hildebrand§ studied emulsin and found that it produced a definite reaction with the formation, in animals injected, of an anti- emulsin. v. Diingern|| studied proteolytic enzymes of various bacteria, and showed that when gelatin-dissolving enzymes were repeatedly injected into animals, definite reactions took place, and in the serum a body appeared that inhibited the action of the ferment in a test-tube. Gheorghiewski** immunized animals to cultures of Bacillus pyocyaneus, and found that the reaction pro- voked caused the appearance in the serum of some body that pre- vented the formation of the blue pigment so characteristic of the . organism. Morgenrothtt applied the same principle to rennet, finding that it produced definite reactions, with the formation of an antibody inhibiting the coagulation of milk. Bordet and Gengoutt found that the fibrin ferment of the blood of one animal was active in the body of another animal, producing an inhibiting substance by which the coagulation of the blood of the first animal could be delayed. The studies of Kraus§§ showed a new fact, that when filtered cul- tures of the cholera spirillum were introduced into animals, the serum of these animals, added to the filtered culture in a test-tube, caused the appearance of a delicate flocculent precipitate, specific precipitate. *“Teutsche med. Woch.,” 1891, Nos. 32 and 44. | t ‘Berliner klin Wochenschrift,” 1898. { Atti d XI Congr. med. internaz. Roma, 1894, 11, 200-202. “Virchow’s Archives,” Bd. cxxxt. | Manchener med. Woch.,” Aug. 15, 1898. **“ Ann, de l’Inst. Pasteur,” 1899. tt “Centralbl. f. Bakt.,” etc., 1899, xxv1, p. 349. tt “Ann. de l’Inst. Pasteur,” 1903, xvII, p. 822. §§ “Wien. klin. Woch.,” 1897. Experimental Investigation of the Problems of Immunity roz Wassermann and Schiitze* found that when cow’s milk was repeatedly injected into rabbits, their serum acquired the property of occasioning a precipitate when added to cows’ milk, but not when added to goats’ or any other milk. If, however, the rabbit had been repeatedly injected with goats’ milk or human milk, its serum would precipitate with those milks respectively, and not with cow’s milk. The reaction was thus shown to be specific. Myerst found that the repeated intraperitoneal injection of egg-albumen into rabbits caused their serum to give a dense pre- cipitate when added to solutions of egg-albumen. Tchistowitch{ found that eels’ serum injected into animals produced a reaction in which immunity to its poisonous action was associated with the ability of their serum to produce a precipitate when added to the eels’ serum. Closely connected with these various reactions are certain others variously spoken of as cytotoxic, cytolytic, hemolytic, bacteriolytic, etc. The first observation bearing upon these was made by R. Pfeiffer,§ who found that when guinea-pigs received frequent intraperitoneal injections of cholera spirilla and became thoroughly immunized, their serum behaved very peculiarly toward the bacteria in the peritoneal cavity of freshly infected animals, in that it caused them to become aggregated into granular masses and subsequently to disappear. This became known as “Pfeiffer’s phenomenon.” The serum of the immunized animal was devoid of action by itself, the serum of the infected animal was inactive, but the combination of the two brought about dissolution of the micro-organisms. Later it was shown by Metschnikoff|| that the living animal was not a factor in the process, but that what was seen in the peritoneal cavity could be reproduced in a test-tube, though not quite as well. Bordet** made frequent injections of defibrinated rabbits’ blood into guinea-pigs, and obtained a serum that had a solvent action upon the rabbit’s corpuscles im vitro, and showed that the induced hemolysis resembled in all points the bacteriolysis. Ehrlicht{ and Morgenroth studied the hemolytic action of the serum of goats that had been frequently injected with the de- fibrinated blood of sheep and goats, and were able to point out the mechanism of the corpuscle solution or hemolysis. It was found to depend upon two associated factors, one of which, the lysin or solvent, was present in normal blood, and was called ‘‘addiment”’ or “complement,” and another present only in the serum of the reactive animals, called the “immune body” or ‘intermediate body.” The former was labile and easily destroyed by heat, the latter * “Deutsche med. Woch.,’’ 1900. t “Lancet,” 1900, II. t “Ann. de l’Inst. Pasteur,” vol. xr, 406. § “Deutsche med. Wochenschrift,” 1896, No. 7. || Ann. de l’Inst. Pasteur,” 1895. ** Thid., 1898, XII. tt ‘Berliner klin. Wochenschrift,” 1899. 102 Immunity stabile and not affected by heat up to the point of coagulation. The experiments were confirmed by von Diingern and many others. It is to be observed in passing that this reaction differs from the direct solution of the corpuscles im vitro by cobralysin, which was studied by Myers,* and tetanolysin, studied by Madsen, in that it is intermediate, and only brought about by the codperation of two factors, while the action of the lysins of venom, the tetanus bacillus, the streptococcus, Bacillus pyocyaneus, and other micro-organisms, is direct and immediate. Myers found, however, that the hemolytic substance of venom, and Madsen that the hemolytic products of Bacillus tetani, also. produce reactions in animals, and that when successful immuniza- tion against them was accomplished, the serums of the experiment animals became antidotal or inhibiting to the action of the respective lysins. Von Diingernt found that by injecting dissociated epithelial cells from the trachea of oxen into the peritoneal cavity of guinea- pigs, it was possible to produce efitheliolysins; Lindemann,§ that emulsions of kidney substance injected into animals caused them to form nephrolysins or nephrotoxins; Landsteiner|| and Metschnikoff** in the same manner successfully prepared spermatoxin by injecting the spermatozoa of one animal into the peritoneal cavity of another. Metalnikoff{{ found that if he introduced the spermatozoa of a guinea-pig into the peritoneum of another, the spermatoxic serum produced was solvent for the spermatozoa of both. Both Metsch- nikoff and Metalnikoff also found that the spermatoxin when introduced into animals was active in producing anti-spermatoxin by which the destructive action of the serum upon spermatozoa could be inhibited. Metschnikoff{{ and Funck§§ found that animals treated with emulsions of the spleen, and mesenteric lymph-nodes of one kind of animal, produced sera whose action was agglutinative and solvent for leukocytes and lymph-cells. Delezenel||| found that dissociated liver cells injected into animals similarly caused the formation of a specific cytotoxic serum. All of these reactions are indirect and intermediate, and take place under appropriate conditions both in the bodies of animals and in the test-tube. Thus the number of antigenic reactions that can be brought about in the bodies of animals seems to be limitless, and, strange Sore g ee of London,” Lr. “‘Zeitschr. f. Hyg.,” 1899, XXXII, p. 230. t “Miinchener med. Wadhéaschnift,> soy. § ‘Ann. de I’Inst. Pasteur,” 1900. || ““Centralbl. f. Bakt.,” etc., 1899, xxv. ** “Ann. de I’Inst. Pasteur,” 1899. tt Ibid., 1900. tt Ibid., 1899. ii “Centralbl. f. Bakt.,” etc., 1900, XxvII. [Ill ‘ Compte rendu de l’Acad. des Sciences,” 1900, CXXX, pp. 938, 1488. Allergia or Anaphylaxis 103 as it may seem, the antibodies produced in the body of one animal may act as antigens when introduced into another. Thus, Ehrlich and Morgenroth in their studies of hemolysis found that serums rich in immune bodies produced reactions yielding anti-immune bodies, which inhibited the activities of the respective immune bodies by whose stimulation they were produced. The reactions which when repeated may lead to immunity and to the formation of antibodies seem to be followed by con- stitutional disturbances much more profound than would be sup- posed from the apparent freedom from symptoms manifested by the animal. As early as 1839 Magendie observed that if a rabbit was given an injection of albumin, and then, some days later, a second injection, it was made very ill and might die. About 1900 Mattson in private conversation called the author’s attention to the fact that when guinea-pigs used for testing antitoxic serums were subsequently injected with another dose of serum, they commonly died. Not being understood, the matter was not thought worthy of publication. Otto* speaks of this fatal action of serums as the “Theobald-Smith phenomenon,” the fact having first been pointed out to him by Smith. The first to realize the importance of the condition seem to have been Portier and Richet,} who studied the effect of extracts of the poisonous tentacles of actiniens upon dogs which were found to die more quickly and from smaller doses given at a second injection thanatthe first. To thisincreaseof sensitivity to the poison brought about by the initial dose they gave the name anaphylaxis (av nega- tive, puAaés protection, destroying protection or breaking down the defenses). The therapeutic employment of diphtheria antitoxic serum was scarcely popularized before the medical profession was shocked by the sudden death of the healthy child of a noted German pro- fessor after a prophylactic injection, and in 1896 Gottsteint was able to collect eight deaths following the use of theserum, four of them being persons not ill with diphtheria. von Pirquet and Schick§ also pointed out that in a certain proportion of cases the injection of horse-serum in man is followed by urticarial eruptions, joint-pains, fever, swelling of the lymph-nodes, edema and albuminuria, these symptoms usually appearing after an incubation period of eight to thirteen days, and constituting what they call the ‘‘serum disease,” or allergia. Sometimes these reactions are immediate; sometimes death appears imminent, and, as has been observed, death some- times occurs. The investigation of the subject was taken up in 1905 by Rosenau * von Lenthold, ‘‘Gedenkschrift,” Bd. 1, pp. 9, 16, 18. t ‘“Compte rendu de la Soc. de Biol. de Paris,” 1902. { “Therap. Monatschrift,”” 1896. - § “Die Serumkrankheit,” Leipzig and Wien, 1905. 104 Immunity and Anderson,* who pursued it with great interest and industry, by Gay,f Gay and Southard,{ and others. Experimental study shows that when an animal is injected with an alien protein of almost any kind, a reaction takes place that usually is not completed under six days. If a second injec- tion is given before the reaction is perfected, the mechanism of immunity is set in action, and the animal proceeds to defend itself through the various means described. 1f the second administration be deferred, however, until the first reaction is completed, it seems to find the animal in a state of disturbed biologic equilibrium, the nature of which is not understood, but which is characterized by a profound disturbance that may terminate in death. The reaction is quite specific; the sensitization, once effected, may continue throughout the remainder of the life of the animal and be trans- mitted from the mother to her offspring through her blood. The reaction can be brought about by feeding the protein or by injecting it. It has an important bearing upon infection and immunity, the chief example being seen in the tuberculin reaction. The symptomatology of anaphylaxis is interesting and char- acteristic. When it is desirable to study it, a guinea-pig is first given a sensitizing dose of horse-serum. This may be very small. Rosenau and Anderson found one guinea-pig to be sensitized by one-millionth of a cubic centimeter. In most of their work they used less than 1459 cc. It is necessary to wait until the effects of this first injection are completely over before giving the poisoning dose. This period of incubation lasts about twelve days. After the lapse of this time, the second dose, usually about {09 cc., is given. Both doses are given by injection into the peritoneal cavity. The symptoms come on almost immediately after the second dose. The animal is profoundly depressed, extremely uneasy, pants for breath, and suffers from intense itching of the face. It soon falls, continues to gasp for breath, and dies within an hour. The disturbances in the body of the animal are sufficient to account for the symptoms. Extensive lesions exist, the first to be described by Rosenau§ affecting the mucous membrane of the stomach, which appeared ecchymotic and ulcerated. Gay and Southard|| found hemorrhages in most of the organs, and believe anaphylaxis to depend upon the presence, in the blood of the sensitized animal, of a substance to which they have given the nameanaphylactin. Bes- redka and Steinhardt** found that by the repeated injection of * Journal of Medical Research,” 1906, xv, p. 207; “Bull. No. 29 of the Hygienic Laboratory,” Washington, D. C., 1906; “Bull. No. 36,” 1907, Ibid.; “Jour. Med. Research,” 1907, xv1, No. 3, p. 381; ‘Jour. Infectious Diseases,” 1907, Iv, No. 1, p. 1, “Jour. Infectious Diseases,” 1907, vol. Iv, p. 552. } “Jour. Med. Research,” May, 1907, xvi, No. 2, p. 143. Tt Ibid., June, 1908, xvi, No. 3, p. 385. er No. 32 of the Hygienic Laboratory,” Washington, D. C., October, 1906. : || “Jour. Med. Research,” July, 1908, xx, No. 1 2, 5). 27: ** “Ann. de l'Inst. Pasteur,” February 25, cone ce No. oe II7-127. Explanation of Immunity 105 horse-serum into guinea-pigs, the intervals being too short to permit anaphylaxis, antianaphylactin could be prepared. It seems difficult, however, to imagine how such a substance could remain in the blood throughout the entire subsequent life of the animal. Vaughan has endeavored to explain anaphylaxis by assum- ing that when the strange protein in the blood reaches the cells it is slowly broken down by enzymic action, but that the cells, having once acquired the property of destroying it, seize eagerly upon the protein the next time it is offered, disintegrate it rapidly, and so disseminate throughout the body the degradation products, some of which may be toxic and account for the reaction. Anaphylaxis is not a disturbance of the cells of the body, as some have thought, but is at least in part a disturbance of the composition of the blood, as can be shown by the occurrence of what is known as passive anaphylaxis. If the blood-serum of a sensitized animal be withdrawn and injected into a normal animal of the same kind, it carries the sensitization with it. The new animal, however, does not become sensitized at once, but only after some days, hence it is equally true that the disturbance is not solely in the blood, else why should not the sensitization be immediately present upon the injection of the serum? Anaphylaxis may, furthermore, be local. Thus, when certain substances like tuberculin are dropped in the eye there is no effect, but when a second application is made, after some weeks, the eye may be reddened. Anaphylaxis may play a réle in : infection, In cases where an attack of an infectious disease leaves no immunity, the body may be left hypersensitive to subsequent attacks. EXPLANATION OF IMMUNITY Before the facts now at our disposal had been gathered together, and before the phenomena of immunity against infection had been compared with those of intoxication, Pasteur* and Klebst en- deavored to explain acquired immunity by supposing that micro- organisms living in the infected animal used up some substance essential to their existence, and so died out, leaving the soil unfit for further occupation. This was known as the “exhaustion theory.” Wernicht and Chauveau§ thought it more probable that the micro-organisms after having lived in the body left behind them some substance inimical to their further existence. This was known as the ‘retention theory.” These hypotheses are of historic interest only, and deserve no more than passing men- tion, as they both fail to explain natural Henatnihy or immunity against intoxication. * “‘Compte rendu de la Soc. de Biol. de Paris,” xct. + “Arch. f. experimentelle Path. u. Pharmak., hs XII. t “Virchow’s Archives,” Bd. Lxxvitl. § “‘Compte rendu de la Soc. de Biol. de Paris,” xc and xct. 106 Immunity Karl Roser* observed that the leukocytes of the bodies of higher animals sometimes enclosed bacteria in their cytoplasm. Koch, Sternberg, and others, confirmed the observation, but no attention was paid to it until Metschnikofff correlated it with other known facts and original observations, and came to the conclusion that the enclosed bacteria had been eaten by the leukocytes in which they were killed and digested, and that the behavior of the cells toward the bacteria afforded an explanation of the mechanism by which recovery from the infectious diseases takes place. The original conception upon which this “‘theory of phagocytosis” was founded, refers recovery in many, if not all of the infectious diseases, to the successful destruction of the invading bacteria by the body cells, especially the leukocytes. These devouring cells Metschnikoff called phagocytes, and of them he recognized two classes, the micro- phages, which are white blood-corpuscles, and the macrophages, _ which are larger cells derived from the endothelial and other tissues. Fig. 17.—Phagocytosis; the omentum immediately after injection of typhoid bacilli into a rabbit. Meshwork showing a macrophage, intermediate forms and a trailer, all containing intact bacilli (Buxton and Torry). Metschnikoff, his associates, and his pupils soon collected evidence sufficient to show that phagocytosis, if not the chief factor in de- fending the body from infectious organisms, is at least an important: one. Many of the most interesting facts are described in Metschnikoff’s books, “Etudes sur l’Inflammation” and “Im- munite dans les Maladies Infectieuses,”’ which every interested student of the subject should read. These studies show that in nearly all cases in which animals are naturally immune against infection, the leukocytes are active in their phagocytic behavior toward them; that in acquired immunity, the leukocytes previously inactive, become active toward: them; *“Beitrige zur Biologie niederster Organismen,”’ Inaugural Dissertation, Marburg, 1881. t “Virchow’s Archives,” Bd. xcv1, p. 177; “Ann. de l’Inst. Pasteur,” 1887, te £ Be Sar, Phagocytosis—Opsonins : 107 that the enclosure of bacteria within the cells sometimes results in the death of the cells, sometimes in the death of the bacteria; that phagocytosis is much more active in diseases in which the bacteria have limited toxicogenic powers, and in-which they probably exert a positively chemotactic influence upon the cells, than in cases in which the bacteria are strongly toxicogenic and probably exert an injurious and negatively chemotactic influence upon them, and that when the toxicogenic power of the bacteria is great, many of the phagocytes are killed and dissolved—phagolysis. Study of the primitive forms of animal life shows that amebe constantly feed upon smaller organisms, some almost exclusively upon bacteria, which they are able to kill and digest through an intracellular enzyme demonstrated by Mouton,* and called amebadiastase, and regarded as a form of trypsin. The intracellular digestion of coelenterate animals is accomplished by means of actinodiastase, an enzyme discovered by Fredericq, and studied by Mesnil. It seems to be related to papine and digests albuminoids. The digestion of erythrocytes and tissue fragments is accomplished through an enzyme of the macrophages, which Metschnikoff calls macrocytase, that of bacteria through an enzyme of the microphages, which he calls microcytase. In phagolysis these respective ferments are liberated into the plasma, imparting to it a bactericidal and bacterio- lytic action similar to that normally peculiar to the cytoplasm of the cells. The dissemination of the enzymes in phagolysis, with re- sulting bacteriolytic power of the blood plasma and serum, is a later modification of the original conception of Metschnikoff, that the invading parasites were eaten up by the phagocytes, and was made necessary by the investigation of the bactericidal property of the body juices. The experiments of Wright and Douglasf indi- cate that the action of the phagocytes upon the bacteria is not immediate, but only subsequent to a preparative action upon the organisms by substances contained in serum, to which they have given the name “Opsonins” (Lat. opsono, “I prepare a meal for”). Long before Metschnikoff began his studies of the phagocytes Traube and Gscheidelf observed that the blood-plasma possessed the power of destroying the vitality of bacteria. Grohman§ next observed that not only the intravascular, but also the extravascular blood possessed this property. Further studies of the subject were made by von Fodor.|| The systematic investigation of the bac- tericidal activity of blood-serum im viiro was next taken up by Fliigge,** and more particularly by Nuttall,{{+ who found that dif- *“Compte rendu de l’Acad. des Sciences de Paris,’ 1901, CXXXIII, p. 244. t “Proc. Royal Society of London,” 1904, LXXXII, p. 357. ¢ “Jahresberichte der schles. Ges. f. vaterl. Kultur,” 1874. § “Untersuchungen aus dem physiol. Institut zu Dorpat,” Dorpat, 1884; Kriiger. all “Centralbl. f. Bakt.,” etc., 1890, VIL, p. 753- “Zeitschrift fiir Hygiene,” Bd. rv, S. 208. tt Ibid, Bd. 1v, 353. 108 Immunity ferent blood-serums possessed the power of killing bacteria in large numbers, but that the bactericidal! power of the serum soon disappeared, after which the serum became a good culture-medium for the very bacteria it had formerly destroyed. Metschnikoff objected to the observations, declaring that all the phenomena were ultimately referable to the leukocytes, so Nuttall investigated peri- cardial fluid and the aqueous humor of the eye, which were also found to possess bactericidal powers. The matter was next taken up by Buchner and his associates,* who showed that the blood-plasma and blood-serum possessed exactly the same bactericidal effects as the total blood. Buchner and Nuttall both showed that the exposure of the bactericidal fluids to a temperature of 56°C. for a few hours entirely destroyed their activity, though low temperatures were without effect upon them. Buchner found that the exposure of the serum to sunlight and oxygen also destroyed the bactericidal power. Neutralization of alkaline serum did not destroy its activity, but when the serum was dialyzed and the NaCl removed from it, the germicidal power was lost, to return again when it was restored. Buchner called the bactericidal principle alexin. Many interesting facts were collected bearing upon the bactericidal substance or alexin. Thus Moro} showed that it was proportionally more active in sucking infants than in adults, and Ehrlich and Briegert found that it passed from mother to offspring in the milk. At first Buchner regarded alexin as an albumin, but later§ he came to look upon it as a proteolytic enzyme, this view no doubt resulting from an endeavor to explain the relation of alexin to im- munity against intoxication, in which it was necessary to show that alexin not only killed bacteria, but also destroyed toxins. Hankin|| endeavored to show that there were differences between the substances destroying the bacteria and those acting upon their toxic products. To the whole group he applied the term defensive proteins. ‘Those present in natural immunity he called sozins, those found in acquired immunity phylaxins. Sozins with bacteri- cidal activity he further described as mycosozins, those with toxin- destroying activities as .toxosozins. Phylaxins with bactericidal action were called mycophylaxins; those with toxin-destroying properties toxophylaxins. Metschnikoff found it unnecessary to modify his ideas, but per- sisted in referring all the phenomena to the phagocytes or to enzymes derived from them. At this point it will be evident to the reader that the phagocytic *“Centralbl. f. Bakt.,” etc., 1889, Bd. v, 817; vi, 1; “Archiv fiir Hygiene,” 1891, xX, S. 727; “Centralbl. f. Bakt.,” etc., 1890, vil, 76. } ‘‘Jahresb. f. Kinderheilkunde,” v, 396. t “Zeitschrift fiir Hyg.,”’ 1893, x11, 336. I cane med. Woch.,” 1899. || “Centralbl. f. Bakt.,” etc., x11, Nos. 22, 23; xtv, No. 25. Defensive Proteins, etc. 109 theory and the humoral theory contain indubitable evidence that both the body cells.and humors are important factors in defending the body against invading organisms, and that in each we see mechan- isms operative in certain cases. But we have seen that both Metschnikoff and Buchner are obliged to strain a point in order to meet the requirements of increasing knowledge of the subject of immunity. . Thus, when we come to analyze Buchner’s theory of alexins, we find that if natural immunity depends upon the ability of the alexins to destroy bacteria, that which takes place in vitro should correspond with that which takes place i vivo, and that the invasion of the animal’s body by bacteria should be accompanied by diminu- tion of the bactericidal substance in its blood, which should be used up before the bacteria can be successful in their invasion. Experi- mental evidence is, however, at hand to show that this is not always true. Behring and Nissen* found that there was a definite relation be- tween the bactericidal power of the blood in vitro and the resisting powers of a large number of animals studied, but Lubarscht showed the remarkable exceptions of the rabbit, which is highly susceptible to anthrax, though its blood is highly bactericidal to the anthrax bacillus, and the dog, which is scarcely susceptible to anthrax, though its blood is scarcely bactericidal to the bacillus. Fliigget found the bactericidal power of the blood greatly lessened in thirty-six hours after anthrax infection, and Nissen that a definite number of bacteria could be killed by a bactericidal serum, after which the alexin became inactive. The diminution of the bac- tericidal power was shown to occur both in the animal and in the test-tube. He also showed that the reactions of the bactericidal serums were specific, and that when a culture of one kind of bacteria was injected into an animal, the immediate effect was to diminish the activity of the serum for that species, though not necessarily for other species. The diminution of bactericidal energy was shown by him to depend upon the presence of the bacteria, as the injection of filtrates of bacterial cultures did not affect the bactericidal properties of the serum. This was a very important observation. There is a correspondence between the behavior of the phagocytes and the body juices. When the activity of the phagocytes toward the bacteria is increased, the bactericidal activity of the serum is usually intensified. But immunity is only partly explained by alexins and bacteriolysis, for it embraces the ability of the organ- ism to endure the effects of toxins some of which are in no way connected with bacteria. Tolerance to certain toxins is, of course, natural to many animals, * “Zeitschrift fiir Hygiene,’ 1890, VIII, 412. + “Centralbl. f. Bakt.,” etc., 1889, v1, 481. t “Zeitschrift fiir Hygiene,” 1v,208. 110 Immunity and tolerance to usually destructive toxins natural toa few. This toxin-neutralizing or annulling factor cannot be identical with the bacteria-destroying mechanism. Cobbett,* Roux and Martin,{ and Bolton{ have shown that horses that cannot be supposed ever to have come into contact with diphtheria bacilli, vary considerably in their resistance to diphtheria toxin, and that the serum of the resisting horses contains something that destroys or neutralizes the toxin in vitro, as well as exerts a protective influence upon animals into which it is injected. This substance exerts no inimical action upon the diphtheria bacilli, beyond what a normal serum would do, therefore cannot be alexin, but must be antitoxin. Abel§ found that the blood of healthy men occasionally contained some substance capable of neutralizing diphtheria toxin; Stern found one normal serum capable of protecting against typhoid infection and Met- schnikoff one that protected against cholera infection. Fischel and Wunschheim|| found newly born babies immune against diph- theria, presumably because of the presence of a small quantity of demonstrable protective substance in the blood. These are, ‘however, peculiar and exceptional cases. The most suggestive and fascinating theory of immunity is that of Ehrlich, and is known as the “‘Seitenkettentheorie” or the “ Lateral-Chain Theory.’’** He began his studies by an investigation into the nature of toxins and their mode of action. The discovery that there was no con- stant relation between the intoxicating and antitoxin combining powers of diphtheria toxic bouillon led him to the conclusion that the toxin molecules possessed two different affinities, which he de- scribed as haptophorous or combining, and toxophorous or poisoning. The former were constant, the latter variable. The deterioration in the strength of the toxic filtrates of bouillon cultures of diph- theria bacilli was shown to depend upon the transformation of the *“Lancet,’”’ Aug. 5, 1899, I, Dp. 532. yj “Ann. de l’Inst. Pasteur,” 1894, vit, p. 615. { “Jour. of Experimental Medicine,” July, 1896, 1, No. 5. § “Centralbl. f. Bakt.,” etc., 1895, xv, p. 36. | “‘Zeitschr. fiir Heilkunde,” 1895, xvi, p. 429-482. : ** The writings of Ehrlich and his associates are so numerous and scattered, and often so fragmentary, that instead of referring to tleliterature according to the method adopted in other parts of this work, the reader who desires to consult the original articles can best do so by making use of the following: Ehrlich, “Die Werthbemessung des Diphtherie Heilserums,” Klinisches Jahrbuch, 1897; Ehrlich, ‘‘Die Konstitution des Diphtheriegiftes,”” Deutsche med. Woch., 1898; “‘Gesammelte Arbeiten zur Immunitdtsforschung,’’ August Hirschwald, Berlin, r904—this work contains the collected papers of Ehrlich and his associates; Aschoff, “Ehrlich’s Seitenkettentheorie und ihre Anwendung auf die Kiinst- lichen Immunusirungs-prozesse,” Jena, 1902, and the chapter upon “ Wirkung und Entstehung der Aktiven Stoffe im Serum noch der Seitenkettentheorie,” by Ehrlich and Morgenroth in Kolle and Wassermann’s ‘‘ Handbuch der Patho- gene Mikroorganismen,” Jena, 1904, Gustav Fischer. Readers unacquainted ° with the German language may find the essential facts in Ehrlich’s Croonian Lecture, Proceedings of the Royal Society of London, 1900, LXvI, p. 424, and in Welch’s “‘ Huxley Lecture,” Medical News, 1902, LXXXI, 2, p. 721. The “Lateral-chain Theory” of Immunity III toxin into toxoids which were not poisonous, and was shown to be quite independent of the antitoxin combining affinity of the filtrate which remained unaltered. The inevitable interpretation seemed to be the existence in the bouillon of the haptophorous and toxo- phorous groups described. Similar toxophorous and haptophorous groups were shown to exist in other toxins—tetanolysin by Madsen, venoms by Myers, and milk-curdling ferments by Morgenroth. The neutralizing action of the antibodies produced in the blood of animals immunized to these various substances depends upon the immediate and direct combination or union of haptophorous groups in the antibodies with corresponding haptophorous groups of the respective toxins or active bodies. The physiological activities of toxins differ from those of alkaloids and other poisons in three fundamentals: first, in their ability to produce antibodies in the bodies of animals into which they are injected; second, the manifestation of poisonous action only after a definite incubation period, and third an extremely labile com- position, by which the toxin becomes quickly transformed to toxoids. Heplophile shee Maple ee Toxophore ee Group. ae group. Fig. 18.—Diagram to represent the combining groups of the cell and of the toxin respectively (after Ehrlich) desist): Study of the physiological action of toxins upon the cells resulted in showing that certain definite specific affinities existed, and that the union of the toxin with the cell antedated the production of symptoms. In some cases it was even found possible to disconnect the anchored toxin by bringing to the cells haptophorous groups for which the haptophorous elements of the toxin molecule were known to have an active affinity. Dénitz determined the quantity of tetanus antitoxin which, injected into the circulating blood imme- diately after the toxin, absolutely neutralized it and rendered all of the circulating toxin innocuous. If the same quantity of antitoxin was given seven or eight minutes after the injection of the toxin, death occurred from tetanus, exactly as if no antitoxin had been given. Evidently the toxin had anchored itself to the nerve-cells too quickly for the antitoxin to reach and combine with it. Hey- mans found that if an animal was injected with tetanus toxin and its entire blood withdrawn immediately afterward and replaced by 112 Immunity transfusion, it died of typical tetanus because in the brief interval between the toxin injection and the transfusion, the toxin molecules became anchored to the cell. The ability of the cells thus to anchor the toxin is supposed by Ehrlich to depend upon the existence of haptophorous combining affinities, which he describes as receptors.. He views the mode of toxin reception as depending upon a mechanism either identical with or analogous to that by which cellular nutrition is maintained, and points out that in the case of methylene-blue and other colored - substances, which afford an opportunity to make ocular observations upon the absorption of the pigment by the cells, only certain cells absorb the colors. Cell nutrition is therefore probably carried on through the agency of receptors by which appropriate nutrient haptophorous groups are apprehended and utilized. The following somewhat lengthy quotation from his ‘Croonian Lecture upon the Lateral Chain Theory of Immunity,” delivered before the Royal Society of London, March 22, 1900, explains the theory in Ehrlich’s own words: ‘“‘We now come to the important question of the significance of the toxophile groups in organs. That these are in function especially designed to seize on toxins cannot be for one moment entertained. It would not be reasonable to suppose that there were present in the organism many hundreds of atomic groups destined to unite with toxins, when the latter appeared, but in function really playing no part in the processes of normal life, and only arbitrarily brought into. relation with them by the will of the investigator. It would, indeed, be highly . superfluous, for example, for all our native animals to possess in their tissues atomic groups deliberately adapted to unite with abrin, ricin, and crotin, sub- stances coming from far-distant tropics.” “One may, therefore, rightly assume that these toxophile protoplasmic groups in reality serve normal functions in the animal organism, and that they only incidentally and by pure chance possess the capacity to anchor themselves to this or that toxin.” “The first thought suggested by this assumptien was that the atom group referred to must be concerned in tissue change; and it may be well here to sketch roughly the laws of cell metabolism.. Here we must, in the first place, draw a clear. line of distinction between those substances which are able to enter into the composition of the protoplasm, and so are really assimilated, and those which have no such capacity. To the first class belong a portion of the food- stuffs, par excellence; to the second almost all our pharmacological agents, alkaloids, antipyretics, antiseptics, etc.’’ ‘How is it possible to determine whether any given substance will be assimi- lated in the body or not? There can be no doubt that assimilation is in a special sense a synthetic process—that is to say, the molecule of the food-stuff concerned enters into combination with the protoplasm by a process of condensation in- volving loss of a portion of its water. To take the example of sugar, in the union with protoplasm, not sugar itself as such, but a portion of it, comes into play, the sugar losing in the union some of its characteristic reactions. The sugar - behaves here as it does; ¢.g., in the glucosids, from which it can only be obtained _through the agency of actual chemical cleavage. The glucosid shows no traces of sugar when extracted in indifferent solvents. Ina quite analogous manner the sugar entering into the composition of albuminous bodies (glycoproteids) cannot be obtained by any method of extraction, at least not until chemical composition has previously taken place. It is, therefore, generally easy by means of extrac- tion experiments to decide whether any given combination in which the cells take part is, or is not, a synthetic one. If alkaloids, aromatic amines, anti- pyretics, or anilin dyes be introduced into the animal body, it is an easy matter, The “Lateral-chain Theory” of Immunity 113 by means of water, alcohol, or acetone, according to the nature of the body, to remove all these substances quickly and easily from the tissues.” “This is most simply and convincingly demonstrated in the case of the anilin dyes. The nervous system stained with methylene-blue or the granules of the cells stained with neutral red at once yield up the dye in the presence of alcohol. We are, therefore, obliged to conclude that none of the foreign bodies just mentioned enter synthetically into the cell complex, but are merely con- tained in the cells in their free state.” ... . ‘‘Hence with regard to the pharmacologically active bodies in general, it is not allowable to assume that they possess definite atom groups, which enter into combination with correspond- ing groups of the protoplasm. This corresponds, as I may remark beforehand, with the incapacity of all these substances to produce antitoxins in the animal body. We must, therefore, conclude that only certain substances, food-stuffs, par excellence, are endowed with properties admitting of their being, in the previously defined sense, chemically bound by the cells of the organism. We are obliged to adopt the view that the protoplasm is equipped with certain atomic groups, whose function especially consists in fixing to themselves certain food- stuffs of importance to the cell-life.” We may assume that the protoplasm consists of a special executive center, in connection with which are nutritive side-chains, which possess a certain degree of independence and which may differ from one another according to the requirements of the different cells. And as these side-chains have the office of attaching to themselves certain food-stuffs, we must also assume an atom-grouping in these food-stuffs them- selves, every group uniting with a corresponding combining group of a side-chain. Fig. 19.—Shows how the haptophores having united, the toxophores find a sec- ondary adaptation to the cell, and so can poison it (after Ehrlich) (Hewlett). The relationship of the corresponding groups, i.e., those of the food-stuff and those of the cell, must be specific. They must be adapted to one another, as, e.g., male and female screw (Pasteur),.or as lock and key (E. Fischer). From this point of view, we must contemplate the relation of the toxin in the cell.” ‘We have already shown that the toxins possess for the antitoxins an attaching haptophore group, which accords entirely in its nature with the conditions we have ascribed to the relation existing between the food-stuffs and the cell side- chains. And the relation between toxin and cell ceases to be shrouded in mystery if we adopt the view that the haptophore groups of the toxins are molecular groups fitted to unite not only with the antitoxins, but also with the side-chains a at ai and that it is by their agency that the toxin becomes anchored to the cells. “We do not, however, require to suppose that the side-chains, which fit the haptophore group of the toxins, that is, the side-chains which are toxophile, represent something having no function in the normal cell economy. On the contrary, there is sufficient evidence that the toxophile side-chains are the same as those which have to do with the taking up of the food-stuffs by the protoplasm. The toxins are, in opposition to other poisons, of extremely complex structure, standing in their origin and chemical constitution in very close relationship to the profeids and their nearest derivatives. It is, therefore, not surprising that they possess a haptophore group corresponding with that of a food-stuff. Along- side of the binding haptophore group, which conditions their union to the protoplasm, the toxins are possessed of a second group, which in regard to the cell is not only useless but actually injurious. And we remember that in the case of the diphtheria toxin there was reason to believe that there existed along- 8 II4 Immunity side of the haptophore group another and absolutely independent toxophore group.” . .. . ‘As has been said, the possession of a toxophile group by the cell is the necessary preliminary and cause of the poisonous action of the toxin,” 3 . “Tf the cells of these organs [organs essential to life] lack side-chains fitted to unite with them, the toxophore group cannot become fixed to the cell, which therefore suffers no injury, i.e., the organism is naturally immune. One of the most important forms of natural immunity is based upon the circumstance that in certain animals the organs essential to life are lacking in those haptophore groups which seize upon definite toxins. If, for example, the ptomaine occurring in sausages, which for man, monkeys, and rabbits is toxic in excessively minute doses, is for the dog harmless in quite large quantities, this is because the binding haptophore groups being wanting, the ptomaine cannot, in the dog, enter into direct relation with organs essential to life.” . . . . “The haptophore group exercises its activity immediately after injection into the organism, while in all toxins—with the perhaps solitary exception of snake-venom—the toxophore group comes into activity after the lapse of a longer or shorter incubation period which may, e.g., in the case of diphtheria toxin, extend to several weeks.” “The theory above developed allows of an easy and natural explanation of the origin of antitoxins. In keeping with what has already been said, the first stage in the toxin action must be regarded as the union of the toxin by means of its haptophore group to certain ‘side-chains’ of the cell protoplasm. This union is, as animal experiments with a great number of toxins show, a firm and enduring one. The side-chain involved, so long as the union lasts, cannot Fig. 20.—Cells with various receptors or haptophorous groups of the first order (a), adapted to combination with the haptophorous groups (8) of various chemical compounds brought to them. It will be noted that there is no mechan- ism by which the toxophorous elements of the molecules (c) can be brought to the cell. exercise its normal nutritive physiological function—the taking up of food-stuffs. It is, as it were, shut out from participating, in the physiological sense, in the life of the cell. We are, therefore, now concerned with a defect which, according to the principles so ably worked out by Professor Carl Weigert, is repaired by regeneration. These principles, in fact, constitute the leading conception of my theory. If after union has taken place new quantities of toxin are administered at suitable intervals and in suitable quantities, the side-chains, which have been reproduced by the regenerative process, are taken up anew into union with the toxin, and so again the process of regeneration gives rise to the formation of fresh side-chains. In the course of the progress of typical systematic immuni- zation, as this is practised in the case of diphtheria and tetanus toxin especially, the cells become, so to say, educated or trained to reproduce the necessary side- chains in ever-increasing quantity. As Weigert has confirmed by many ex- amples, this, however, does not take place by the simple replacement of the defect; the compensation proceeds far beyond the necessary limit; indeed, overcom- pensation is the rule. Thus the lasting and ever-increasing regeneration must finally reach a stage at which such an excess of side-chains is produced that, to use a trivial expression, the side-chains are present in too great a quantity for the cell to carry and are, after the manner of a secretion, handed over as needless ballast to the blood. Regarded in accordance with this conception, the anti- toxins represent nothing more than side-chains reproduced in excess during re- gencration and therefore pushed off from the protoplasm and so coming to exist in the free state,” The “‘Lateral-chain Theory” of Immunity 115 “Tn the first place, our theory affords an explanation of the specific nature of the antitoxins, that tetanus antitoxin is only caused to be produced by tetanus toxin, and diphtheria antitoxin through diphtheria toxin. This very spccific nature of the affinity between toxin and cell is the necessary preliminary and cause of the toxicity itself. Further, our theory makes it easy to understand the long-lasting character of the immunity produced by one or several administra- tions of toxin, and also the fact that the organism reacts to relatively small Figs. 21 and 22.—Show the regeneration of the cell-haptophores or receptors to compensate for the loss of those thrown out of service. quantities of toxin by the production of very much greater quantities of anti- toxin. By the act of immunization, certain cells of the organism become con- verted into celJs secreting antitoxin at the same rate as this is excreted. New quantities of antitoxin are constantly produced, and so throughout a long period the antitoxin content of the serum remains nearly constant. The secretory nature of the formation of antitoxins has been very strikingly illustrated by the beautiful experiments of Salmonson and Madsen, who have shown that pilo- Fig. 23.—Shows the number of Fig. 24.—Explains what antitoxins haptophores regenerated by the cell are and how they are formed. The becoming excessive; they are thrown liberated receptors in the tissue juice off into the tissue juice. and in the blood, possess identical com- bining affinities with those upon the cell, and meeting the adapted hapto- phorous elements in the blood, com- bine with them, thus keeping them from the cells. carpine, which augments the secretion of most glands, also occasions in immu- nized animals a rapid increase in the antitoxin content of the serum.” “The production of antitoxins must, in keeping with our theory, be regarded as a function of the haptophore group of the toxin, and it is easy therefore to understand why, out of the great number of alkaloids, none are in a position to cause the production of antitoxins. Conversely, indeed, I recognize in this incapacity of the alkaloids, in opposition to the toxins, to produce antitoxins a further and salient proof of the truth of the deduction I have previously based on chemical grounds, that the alkaloids possess no haptophore group which 116 Immunity anchors them to the cells of organs. To formulate a general statement, the capacity of a body to cause the production of antitoxin stands in inseparable connection with the presence of a haptophore atomic group. In the formation of antitoxin the toxophore group of the toxin molecule is, on the contrary, of absolutely no moment. But the toxoid modification of the toxins, in which the haptophore group of the toxin is retained, while the toxophore group has ceased to be active, possesses the property of producing antitoxins. Indeed, in some cases of extremely susceptible animals, immunity can only be attained by means of the toxoids, and not by the too strongly acting toxins.” . ... “The symptoms of illness due to the action of the toxophore group, therefore, play no part in the production of antitoxin.” The effect of enzymes upon the organism with the production of antibodies, and the “‘specific precipitins”’ caused by the injection of milk, albumin, and peptones into animals may be looked upon as ‘having their origin in the most widely diverse organs, and representing nothing more than nutritive side-chains, which in the course of the normal nutritive processes have been developed in excess and pushed off into the blood.” “Much more complex than in the cases hitherto discussed are the conditions when, instead of the relatively simple metabolic products of microbes, the living micro-organisms themselves come to be considered, as in immunization against cholera, typhoid, anthrax, swine-fever, and many other infectious diseases. Thus there come into existence, alongside of the antitoxins produced as a result of the action of the toxins, manifold other reaction products. This is because the bacterium is a highly complicated living cell of which the solution in the organism yields a great number of bodies of different nature, in consequence of which a multitude of ‘antikérper’ are called into existence. Thus we see, as a result of the injection of bacterial cultures, that there arise alongside of the specific bacteriolysins, which dissolve the bacteria, other products, as, for example, the ‘coagulins’ (Kraus, Bordet), i.e., substances which are able to cause the precipitation of certain albuminous bodies contained in the culture fluid injected; also the much-discussed agglutinins (Durham, Gruber, Pfeiffer), the antifer- ments (von Diingern), and no doubt many other bodies which have not yet been recognized. It is by no means unlikely that each of these reaction products finds its origin in special cells of the body; on the other hand, it is quite likely that the formation of any single one of these bodies is not of itself sufficient-to confer immunity. Thus, in the case of the introduction of bacteria into the body we have to do with a many-sided production of different forms of ‘anti- korper,’ each of which is directed only against one definite quality or metabolic product of the bacterial cell. Accordingly, in recent times, the practice of using for the production of immunization definite toxic bodies isolated from the bacterial cells has been more and more given up, and for this purpose it is now regarded as important to employ the bacterial cells as intact as possible.” . “The most interesting and important substances arising during such an immuniz- ing process are without doubt the bacteriolysins.” . . . . “Belfanti and Car- bone first discovered the remarkable fact that horses which had been treated with the blood-corpuscles of rabbits contain in their serum constituents which are poisonous for the rabbit, and for therabbit only.” . . . “‘Bordet showed shortly thereafter that in.the case quoted there was present in the serum a specific hemolysin which dissolved the corpuscles of the rabbit. He also proved that these hemolysins—as had already been shown by Buchner and Daremberg in the case of similarly acting bodies which are present in normal blood—lost their solvent property on being maintained during half an hour at a temperature of 55°C. Bordet added, further, a new fact, that the blood-solvent property of those sera which had been deprived of solvent power by heat, the solvent action could be restored if certain normal sera were added to them. By this important observation an exact analogy was established with the facts of bacteriolysis as elicited by the work of Pfeiffer, Metschnikoff, and Bordet.” . “In collaboration with Dr. Morgenroth, I have sought in regard to this question, for which hemolysis offered prospects favorable to experimentation, to make clear the mechanism concerned in the action of these two compounds— the stable, which may be designated ‘immune body,’ and the unstable, which may be designated ‘complement’—which acting together effect the solution of the red blood-corpuscles. For this purpose, in the first place, solutions containing either only the ‘immune body’ or only the ‘complement’ were brought in contact with suitable blood-corpuscles, and after separation of the fluid and the corpuscles The “‘Lateral-chain Theory” of Immunity 117 by centrifugalization, we investigated whether these substances had been taken up by the red corpuscles or remained behind in the fluid. The proof of its loca- tion in the one position or in the other was readily forthcoming, since to restore the hemolysin to its former activity, it was only necessary to add to the ‘immune body’ a fresh supply of ‘complement,’ or to the ‘complement’ a fresh supply of ‘immune body’ in order that the presence of the hemolysin in its integrity might be shown by the occurrence of solution of the red cells. The experiments proved that, after centrifugalizing, the ‘immune body’ is quantitatively bound to the red blood-corpuscles, and that the ‘complement,’ on the contrary, remains entirely behind in the fluid. The presence of the two components in contact with blood-corpuscles only occasions the solution of these at higher temperatures, and not at o°C. And an active hemolytic serum (with ‘immune body’ and ‘complement’ both present) having been placed in contact with red blood- corpuscles and maintained for a while at o°C., it was found after centrifugalizing that, under these circumstances also the ‘immune body’ had united with the red blood-corpuscles, but that the ‘complement’ remained in the serum. This experiment showed that both components must, at a tem- perature of o°C., have existed alongside of one another in a free condition.” ... . “But when analogous experiments were undertaken at a higher temperature it was found that both components were retained in the sediment. “These facts can only be explained by making certain assumptions regarding the constitution of the two compo- nents, z.e., of the ‘immune body’ and the ‘complement.’ In the first place, two haptophore groups must be as- cribed to the ‘immune body,’ one having affinity for a corresponding haptophore group of the red blood-corpuscles and with which at a lower temperature it quickly unites, Fig. 25.—Com- and another haptophore group of a lesser chemical affinity, which at a higher temperature becomes united with the ‘complement’ present in the serum. Therefore at the higher temperature the red blood-corpuscles will draw to themselves those molecules of the ‘immune body’ which in the fluid have previously become united to the ‘comple- ment.’ In this case the ‘immune body’ represents in a measure the connecting chain which binds the comple- ment to the red blood-corpuscles and so brings them under its deleterious influence. Since under the influence of the ‘complement ’—at least, in the case of the bacteria —appearances are to be observed (for example, in the Pfeiffer phenomenon) which must be regarded as analogous bination of cell (a), amboceptor (#), and complement (c). Theamboceptor may unite with the cell, but cannot af- fect it alone. The complement cannot unite with the cell except through the amboceptor, having no adaptation to the cell directly. to digestion, we shall not seriously err if we ascribe to this ‘complement’ a ferment-like character.” . . . . “Having obtained a precise conception of the method of action of the lysins of the serum—of the hemolysins, and thereby also of the bacteriolysins—it becomes possible for us to attempt to solve the mystery of the origin of these bodies.. I have in the begin- ning of this lecture fully developed the ‘side-chain theory,’ according to which the antitoxins are merely certain of the protoplasm ‘side-chain’ which have - been produced in excess and pushed off into the blood. “The toxins as secretion products of the cells are in all likelihood still relatively uncomplicated bodies; at least by comparison with the primary and complex albumins of which the living cell is composed. “Tf we now recognize that the different lysins arise only through absorption of highly complex cell material—such as red blood-corpuscles or bacteria—then the explanation, in accordance with what I have said, is that there are present in the organism ‘side-chains’ of a special nature, so constituted that they are endowed not only with an atomic group by virtue of the affinities of which they are enabled to pick up material, but also with a second atomic group, which, being ferment-loving in its nature, brings about the digestion of the material taken up. Should the pushing off of these ‘side-chains’ be forced, as it were, by immuni- zation, then the ‘side-chains’ thus set free must possess both groups, and will, therefore, in their characteristics entirely correspond with what we have placed beyond doubt as regards the ‘immune body’ of the hemolysin.” 118 Immunity An analysis of this theory shows complete natural immunity to depend upon the absence of haptophore groups (receptors) by which the toxins can be united to the cells. Extreme sensitivity or susceptibility probably depends upon the adapted haptophores being present or at least most numerous upon the cells of highly vital organs; comparative insensitivity or insusceptibility upon the fact that the greater number of haptophore groups are attached to comparatively unimportant cells whose combining affinities have to be satisfied before combination with more vital cells can be accomplished. In some cases natural immunity is increased by the presence of free haptophore groups (antitoxin) in the blood. Acquired immunity against toxins depends g ¢ upon the regeneration of the cellular hapto- y ~ Pphores or receptors which, being liberated s , 4 into the body juices, fix the haptophores of © the toxin molecules before they are able to reach the cells themselves. Antitoxins and 2 other anti-bodies, including the lysins, consist of liberated cellular haptophores or receptors, the former having a single combining affinity, the latter a double combining affinity, by : : . which they unite, on the one hand, with the conte oi {he “aerond Cell. to be dissolved, on the other with the order (a) by which the complement by which it is to be dissolved. cells fix useful molecules, Antibodies having this double combining of albumins, etc., on one : be 99 hand (5), and zymogen @ffinity have been called “‘amboceptors by molecules (c)ontheother Ehrlich. They are variously known in dif- hand,andmakeuseofthe ferent writings as “immune bodies,” ambo- one substance through Sees : , the action of the other. ceptors, substance sensibilisatrice, desmon, and fixateur. The “complement” or ‘“addi- ment” of Ehrlich is also called alexin and cytase. Ehrlich con- ceives every amboceptor and every complement to be specific, but Bordet and others, while admitting that the amboceptor is specific, hold that there is but one complement or cytase. It has already been said that Metschnikoff’s primitive con- ception of the body being defended against infection through the phagocytic incorporation and digestion of the microparasites, has had to be modified to conform to the increasing information upon the immunity reactions. He has persistently clung to the idea that the phagocytes are the essential factors, but has changed the con- ception of “phagocytosis” to make it applicable to the new require- ments. He now teaches that when invasive:micro-organisms enter the body, chemotactic influences determine that they shall be met by phagocytes. If the invading micro-organisms are too powerful and the phagocytes are killed, phagolysis or dissolution of the phago- cytes liberates their enzymes into the blood. These liberated enzymes still act deleteriously upon the invaders, tending to ag- The “Lateral-chain Theory” of Immunity 11g glutinate—aggregate them in clumps—and sensitize them to the future action of other phagocytes by which they may be taken up. Through extensive phagolysis, and the liberation of large quantities of the enzyme contents of the phagocytes into the blood, the plasma and serum acquire a “‘fixing” or “sensitizing” quality from the macrocytase of the macrophages, which is the “fixateur” or ‘‘substance sensibilisatrice,’ and a bacteria-dissolving quality forms another enzyme, microcyiase, from the microphages. Thus, we find that Metschnikoff is prepared to account for the “ambo- ceptor” or “immune body” of Ehrlich, which is the macrocytase, and the ‘‘complement,’’ which is the ‘“‘microcytase.”’ In cases where the bacteria exert a negatively chemotactic influence upon the leukocytes, no immunity exists. The antitoxins are similarly accounted for by Metschnikoff: the cellular digestive enzymes exert their action not only upon the microparasites, but also upon their products, fixing or otherwise altering them until they can be finally destroyed. It will thus be seen that the two chief theories of immunity, though _they appear discordant when explained independently of one another, can be fairly well harmonized. Ehrlich believes the im- mune bodies to be the products of those cells of the body with whose haptophile combining groups the haptophore groups of the antigen engaged, and does not attribute the function to any particular group of cells; Metschnikoff attributes all the activities to the phagocytes, and especially the leukocytes. Ehrlich looks upon the phenomena as chemical and pictures them as taking places inde- pendently of the cells; Metschnikoff looks upon them as vital and brought about by the agency of living cells. Both theories are ultimately chemical. The fundamental ideas embodied in the “‘lateral-chain theory” of immunity may, by reversing the hypothesis and considering the bacterial instead of the body cells to be upon the defensive, be made to explain other phenomena of immunity. Walker* seems to have been the pioneer in this field, and his researches show that it is possible to immunize bacteria against “immune serums”’ by cultivating them in media containing increasing proportions of the immune serums. The bacteria thus cultivated were of increased virulence. The idea was further amplified by Welch in his Huxley Lecture.t The micro- organismal cells must be regarded as endowed with receptors of their own, fitted for combination with adapted haptophorous elements in the juices reaching them, and therefore capable of reacting toward such substances exactly as do the cells of the host. As the host reacts toward the active products of the bacteria, so the bacteria react toward the defensive products of the host, and as the cells of the former are stimulated to the production of immune bodies that shall facili- tate bacteriolysis, so the latter are stimulated to antagonize their action by producing neutralizing bodies. These neutralizing bodies by which the defenses of the host are broken down are among those described by Bailf as “‘aggressins.’ Thus, as the cells of the host invaded are constantly reacting to the active *“Tour. of Path. and Bact.,” March, 1902, vit, No. 1, p. 3 t “British Medical Journal, 9 Oct. 11, 1902, p. 1105; Medical News,” Oct. 18, 1902. + “Wiener klin. Woch.,” 1905, Nos. 9, 14, 16, 17; “Berl. klin. Woch.,” 1905, No. 15; ‘“Zeitschr. f. Hyg. ’ 1905, Bd. 1, No. 3. 120 Immunity bodies produced by the invading parasites, so the latter are reacting toward the defensive products of the former. If the reactive processes of the host predomi- nate, immunity and the destruction of the parasites result; if those of the bacteria predominate, increased virulence, facilitated invasion, and death of the host may result. This hypothesis also serves to make clear why micro-organisms entering the body not infrequently show a marked tendency to colonize in certain organs and tissues in preference to others. ‘ poem oe : : Supposing accident to determine the tissue in which the primary infection has taken place, a longer or shorter residence in that tissue, with the resulting more or less marked acquired immunity against the defensive activities of that tissue, endow the organism with a higher degree of virulence for it than for other tissues, so that if at some future time the organism entering the circulation of a new host were able to colonize in any tissue of the body, its activities could be more easily and more successfully manifested in that to which it had already become accustomed, and to which it had acquired a peculiar adaptability. This adaptability has been made the subject of interesting experimental demonstra- tion by Forssner* in his work upon the intravenous injection of streptococci. SPECIAL PHENOMENA OF INFECTION AND IMMUNITY Certain phenomena which present themselves in the course of infection and immunity, to which reference has already been casually made, must now be considered in detail. SPECIFIC PRECIPITATION Specific precipitation is the coagulation or precipitation of an anti- gen by its specific antibody. In 1897 Kraus while studying the “specific reactions produced by homologous serums with germ- free filtrates of bouillon cultures, of cholera, typhoid and plague bacteria,” observed that immune serum brought into contact with the respective culture filtrate occasioned a precipitate specific in nature, to which he gave the name “‘specific precipitate.” Bordet{ and Tchistowitch§ showed that the phenomenon was of wide occurrence and had a broad significance, for they discovered that when the serum of one animal was injected into another ani- mal of different kind, some reaction took place in the injected ani- mal, which caused a precipitate to form whenever the serums of the two animals were being subsequently brought together in a test-tube. Thesame was found true of milk. When an animal was injected with the milk of a different kind of animal, its serum ac- quired the property of causing a precipitate to form when its serum and filtered milk were mixed together ina test-tube. Thesubstance or factor inducing the precipitation was called “‘precipitin” or “coagulin.” Myers,|| Jacoby,** Nolf,t}t and others showed that. the faculty of provoking specific precipitins was common to many albuminous bodies—albumen, globulin, albumose, peptone, ricin, etc. Kraus in his original communication dwelt upon the specific nature of the precipitation, and was corroborated by Fish, tt Wasser- *“Nordiskt Medicinskt Archiv,” 1902, Bd. xxxv, p. 1. t “Wiener klin. Woch.,” 1897, No. 32. ; i “Ann. de l’Inst. Pasteur,’ 1899, p. 173. § ‘‘Ann. de l’Inst. Pasteur,” 1899, p. 406. Ae Fig. 28.—Latapie’s instrument for preparing tissue pulp. Bacteriolysis.—The first observations upon bacteriolysis were made in 1874 by Traube and Gscheidel,t who found that freshly drawn blood was destructive to bacteria. The matter was pur- sued by numerous subsequent investigators and was explained by Buchner as depending upon alexines. Pfeiffert described the peculiar reaction known as “‘Pfeiffer’s phenomenon.” Ehrlich and Morgenroth§ and Bordet|| described the mechanism of cytolysis, explaining the “Pfeiffer phenomenon” and paving the way for future experiments. Direct destruction of bacteria by blood-serum and body juices is rare, and occurs only when the serum contains appropriate *“ Ann. de l'Inst. Pasteur,” 1902, XVI, p. 047. { “Jahresb. der schles. Ges. f. vaterl. Kultur,” 1874. { “ Deutsche med. Wochenschrift,” 1896, No. q. § “Berliner klin. Wochenschrift, a 1899. || “Ann. de l’Inst. Pasteur,” 1898, XII. 136 Immunity quantities of both factors involved—i.e., amboceptor and com- | plement. For the usual bacteriolytic investigations it is, therefore, necessary to consider three factors: 1, The bacteria to be destroyed; 2, the serum furnishing the complement; and 3, the serum furnish- ing the immune body. ; Technic.—1. The bacteria to be destroyed should be prepared in the form of a homogeneous suspension in physiological salt solution, similar to that employed for making the agglutination tests (g. v.). It is best to use the surface growths from agar-agar, well rubbed upon the side of a test-tube containing the fluid, which is permitted to contact with the mass from time to time by inclining the tube so that the fluid is able to carry away the bacteria.as they are distributed. If quantitative estimations are to be made, the number of bacteria in the sus- pension must be known or at least a standard quantity must be employed, as the destructive process is a chemical one,in which the destructive agents are themselves used up. 2. The serum furnishing the complement is a normal serum—that is, the serum from a healthy animal that has undergone no manipulation. The guinea- pig is the animal preferred. 3. The serum containing the amboceptor or the immune body is obtained from an animal that has been given a high degree of immunization against the bacterium to be destroyed or dissolved. The complement contained in this serum should be destroyed by heating for a short time to 55°C. These three having been prepared,an appropriate quantity of the bacterial suspension is placed in a small test-tube, and an appropriate quantity of the diluted normal serum added. To this mixture of two constants, varying quanti- ties of the immune serum are added and the tube stood away for twenty-four hours on ice. In almost every case it will be found that the immune serum con- tains a great quantity of agglutinating substance, so that the bacteria all fall to the bottom in a short time. This is independent of bacteriolysis. The bacterial destruction is gauged by the disappearance of the bacteria or by their failure to grow when transplanted to appropriate culture media. By making the bacterial suspension and complementary serum constant quan- tities (taking care that not too many bacteria be present), one is able to estimate the value of the immune serum. By using the bacterial suspension and a heated immune serum (containing no complement) as constants and varying theaddi- tion of complementary serum, one can estimate the respective values of several complementary serums. By using both serums as constant factors and varying the number of bacteria, one can determine the exact bacteriolytic value of the mixture. By taking out and planting drops from time to time the tapidity of bacteriolysis can be determined, and by plating out the drops and counting the colonies one may arrive at percentages of destruction and express the bacteriolytic process in the form of a curve. THE DEVIATION OF THE COMPLEMENT, OR THE “NEISSER-WECHSBERG PHENOMENON” A peculiar phenomenon has been observed and studied by Neisser and Wechsberg.* When an animal whose blood-serum is nor- mally possessed of. a high degree of germicidal power is immunized by repeated injections of a bacterial antigen, its serum when ex- amined by the usual methods fails to show the usual increase in the specific bactericidal action toward that particular organism, though it retains its general bacteria-destroying power. If, however, the serum be greatly diluted, its action is changed, so that it loses its general bacteria-destroying power and develops marked increase in the specific destructive action upon the particular bacteria used * “Miinch. med. Wochenschrift,” April 30, 1901, xtvii1, No. 13, p. 697. The Deviation of the Complement 137 in the experiment. Neisser and Wechsberg attribute the peculiar reaction to the fact that there being more amboceptors than com- plements in the serum, some of the former satisfy their combining affinities by attaching themselves to the bacteria, some by attach- ing themselves to the complement, instead of forming combinations of all three. If under these circumstances the serum containing an noe —“N{ seen nee onngmne g Sam maser sence ~ : yoyoa ose yabas : : mrSae yy *s0uad}sIsuot : : cadeys “IOJOD ae aie "aZIS "aanixay, 2 2 ‘mNUNS-aoo1g Yo OLyLOg “use a a -adeus & a 2921S as . 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A, Aérobic and facultative anaérobic. a. Gelatin not liquefied. * Decolorized by Gram’s method. { Obligate aérobic. AcEtTic FERMENT Group. tt Aérobic and facultative anaérobic. Gas generated in glucose bouillon. Gas generated in lactose bouillon. Bact. ArROGENES Group. Little or no gas generated in lactose bouillon. Friep- LANDER GROUP. No gas generated in glucose bouillon. Milk coagulated. Fowx CHOLERA GROUP. Milk not coagulated. Swine PLacuE Group. ** Stained by Gram’s method. { Gas generated in glucose bouillon. Lactic FERMENT Grovp. b. Gelatin liquefied. * Colonies on gelatin ameboid or proteus-like. Bact. RADIATUM Group. ** Colonies on gelatin round, not ameboid. Bact. AmpicuumM Group. II. Produce endospores. 1. No growth at room temperature, or below 22°-25°C. THERMOPHILIC Group. 2. Grow at room temperatures. : a. Gelatin liquefied. ANTHRAX GROUP. b. Gelatin not liquefied. Bact. F#cALis Group. BAcILLUS I. Without endospores. . A, Aérobic and facultative anaérobic. a. Gelatin colonies roundish, not distinctly ameboid. * Gelatin not liquefied. { Decolorized by Gram’s method. Gas generated in glucose bouillon. ' Milk coagulated. Coton Group. Milk not coagulated. Hoc CHoLerA Group. No gas generated in glucose bouillon. TypHorp Grove. tt Stained by Gram’s method. B. muRIPESTIFER GROUP. * ** Gelatin liquefied. } Gas generated in glucose bouillon. B.cLtoac& Grove. _ tft No gas generated in glucose bouillon. Include a large number of bacteria not sufficiently described to arrange in groups. 6. Gelatin colonies ameboid, cochleate, or otherwise irregular. *Gelatin liquefied. PROTEUS VULGARIS GROUP. ** Gelatin not liquefied. B. zopr1 GROUP. II. Produce endospores. A, Aérobic and facultative anaérobic. 1. Rods not swollen at sporulation. a. Gelatin liquefied. 232 - The Identification of Species * Liquefaction of the gelatin takes place slowly. Ferment urea, with strong production of ammonia. URo-Bacitius Group or MIQUEL. ** Gelatin liquefied rather quickly. ¢ Potato cultures rugose. Potato BAcitLus Group. tt Potato cultures not distinctly rugose. B. susritis Group. 6. Gelatin not liquefied. B. sorz Group. 2. Rods spindle-shaped at sporulation. B. LICHENIFORMIS GRoUP. 3. Rods clavate at sporulation. B. suBLANATUS GROUP. B. Obligate anaérobic. 1. Rods not swollen at sporulation. MALIGNANT EDEMA Group. 2. Rods spindle-shaped at sporulation. CLostripium Group. 3. Rods clavate-capitate at sporulation. TETANUS GRoUP. PsEupomonas (Migula) I. Cells colorless, without a red-colored plasma and without sulphur granules, A. Grow in ordinary culture-media. 1. Without endospores. a. Aérobic and facultative anaérobic. * Without pigment. { Gelatin not liquefied. Gas generated in glucose bouillon. Ps. MONADIFORMIS Group. No gas generated in glucose bouillon. Ps. ampicua Group. Tt Gelatin liquefied. Gas generated in glucose bouillon. Ps. coADUNATA Group. No gas generated in glucose bouillon. Ps. FAIRMONTENSIS Group. *Produce pigment on gelatin or agar. t Pigment yellowish. Gelatin liquefied. Ps. ocHRAcEA Group. Gelatin not liquefied. Ps. TturRcosA Group. tt Pigment blue-violet. Gelatin liquefied. Ps. JANTHINA GRoUupP. Gelatin not liquefied. Ps. BEROLINENSIS GROUP. ** Produce a greenish-bluish fluorescence in culture-media. { Gelatin liquefied. Ps. pyocyaANEa Group. tt Gelatin not liquefied. Ps. syNcyANEA GROUP. 2. With endospores, aérobic and facultative anaérobic. a. Non-chromogenic. * Rods not swollen at sporulation. Ps. ROSEA GROUP. ** Rods swollen at one end at sporulation. Ps. TROMMEL-: SCHLAGER GROUP. b. Produce a greenish-bluish fluorescence in culture-media. * Gelatin liquefied. Ps. virIDESCENS GROUP. ** Gelatin not liquefied. Ps. uNDULATA GRoUpP.. B. Do not grow in nutrient gelatin or other organic media. NuITRIMONAS Group. II. Cell plasma with a reddish tint, also with sulphur granules. CHROMATIUM Grovp. : Microsprra (Migula) I. Cultures show a bluish-silvery phosphorescence. PHOSPHORESCENT GROUP. II. Cultures not phosphorescent. A. Gelatin liquefied. 1. Cultures show the nitro-indol reaction. a. Very pathogenic to pigeons. Msp. METSCHNIKOVI GROUP. b. Not distinctly pathogenic to pigeons. CHOLERA GRovP. 2. Nitro-indol reaction negative or very weak, at least after twenty- four hours. CHOLERA NosTRAS GRoUP. B. Gelatin not liquefied or only slightly so. Msp. SAPROPHILA GROUP. Mycosacterium (Lehmann-Neumann) I. Stain with basic anilin dyes, and easily decolorized by mineral acids when stained with carbol-fuchsin. ‘Chester’s Synopsis of Groups of Bacteria 233 A, Grow ea) nutrient gelatin. Gelatin liquefied very slowly or merely softened. 1. Stain by Gram’s method. Swine Erysiprtas Group. 2. Not stained by Gram’s method. GLANDERS Group. B. Little or no growth in ordinary nutrient gelatin. 1. Grow well in nutrient bouillon at body temperatures. a. Stained by Gram’s method. Rods cuneate—clavate—ir- regularly swollen. DipHTHERIA GROUP. 2. No growth in nutrient bouillon or on ordinary culture-media. Rods slender, tubercle-like. a, Stain by Gram’s method. LrEprosy Grouvp. 6. Do not stain by Gram’s method. INFLUENZA Group. 3. No growth in nutrient bouillon or on ordinary culture-media. Rods variable. Root-TUBERCLE Group. II. Not stained with aqueous solutions of basic anilin dyes; not easily decolorized by acids. TUBERCLE GROUP. CoccacEx Cells in their free condition globular, becoming slightly elongated before division. Cell division in one, two, or three directions of space. A. Cells without flagella. 1. Division in only one direction of space. Streptococcus (Billroth). 2. Division in two directions of space. . Micrococcus (Hallier). 3. Division in three directions of space. Sarcina (Goodsir). B. Cells with flagella. 1. Division in two directions of space. Planococcus (Migula). 2. Division in three directions of space. Planosarcina (Migula). CHAPTER XII THE BACTERIOLOGY OF THE AIR Micro-ORGANISMS are almost universally suspended in the dust of the air, their presence being a constant source of contamination in our bacteriologic researches and occasionally a menace to our health. Such aérial organisms are neither ubiquitous nor uniformly disseminated, but are much more numerous where the air is polluted and dusty than where it is pure. The purity of the atmosphere bears a distinct relation to the purity of the surfaces over which its currents blow. The micro-organisms of the air are for the most part harmless saprophytes taken up and carried about by the wind. They are almost always taken up from dry materials, experiment having shown that they arise from the surfaces of liquids with much difficulty. Not all the micro-organisms of the air are bacteria, and a plate of sterile gelatin exposed to the air for a brief time will generally grow molds and didia as well. In some cases the bacteria are pathogenic, especially where dis- charges from diseased animals have been allowed to collect and dry. On this account the atmosphere of hospital wards and of rooms in which infectious diseases are being treated is more apt to contain them than the air of the street. However, because of the expectora- tion from cases of tuberculosis, influenza, and pneumonia, which is often ejected upon the sidewalks and floors of public places, the pres- ence of occasional pathogenic bacteria is far from uncommon in street-dust. Giinther points out that the greater number of the bacteria which occur in the air are cocci, sarcina being particularly abundant. Most of them are chromogenic and do not liquefy gelatin. It is unusual to find more than two or three varieties of bacteria at a time. To determine whether bacteria are present in the air or not, all that is necessary is to expose a film of sterile gelatin on a plate or Petri dish to the air for a while, cover, and observe whether or not bacteria grow upon it. To make a quantitative estimation is, however, more difficult. Several methods have been suggested, of which the most important may be briefly mentioned: Hesse’s method is simple and good. It consists in making a measured quantity of the air to be examined pass through a horizontal sterile glass tube about 70 cm. long and 3.5 cm. wide, the interior of which is coated with a film 234 Sedgwick’s Method 235 of gelatin in the same manner as an Esmarch tube. The tube is closed at both ends with sterile corks carrying small glass tubes plugged with cotton. When ready for use the tube at one end is attached to a hand-pump, the cotton removed from the other end, and the air slowly passed through, the bacteria hav- ing time to sediment upon the gelatin as they pass. When the required amount has passed, the tubes are again plugged, the apparatus stood away for a time, and subsequently, when they have grown, the colonies are counted. The number of colonies in the tube will represent pretty accurately the number of bacteria in the volume of air that passed through the tube. In such a tube, if the air pass through with proper slowness, the colonies will be much more numerous near the point of entrance than near that of exit. The first to fall will probably be those of heaviest specific gravity—i.¢., the molds. Petri’s Method.—A more exact method is that of Petri, who uses small filters of sand held in place in a wide glass tube by small wire nets. The sand used is made to pass through a sieve whose openings are of known size, is heated to incandescence, then arranged in the tube so that two of the little filters, held in place by their wire-gauze coverings, are superimposed. One or both ends Fig. 80.—Hesse’s apparatus for collecting bacteria from the air. of the tube are closed with corks having a narrow glass tube. The apparatus is sterilized by hot air, and is then ready for use. The method of employment is very simple. By means of a hand-pump 1oo liters of air are made to pass through the filter in from ten to twenty minutes, the contained micro-organisms being caught and retained by the sand. The sand from the upper filter is then carefully mixed with sterile melted gelatin and poured into sterile Petri dishes, where the colonies develop and can be counted. Petri points out in relation to his method that the filter catches a relatively greater number of bacteria in proportion to molds than the Hesse apparatus, which depends upon sedimenta- tion. Sternberg points out that the chief objection to the method is the presence of the sand, which interferes with the recognition and counting of the colonies in the gelatin. Sedgwick’s Method.—Sedgwick and Miquel have recommended the use of a soluble material—granulated or pulverized sugar—instead of the sand. The apparatus used for the sugar experiments differs a little from the original of Petri, though the principle is the same, and can be modified to suit the experimenter. A particularly useful form of apparatus, suggested by Sedgwick and Tucker, has an expansion above the filter, so that as soon as the sugar is dissolved in the 236 The Bacteriology of the Air melted gelatin it can be rolled out into a film like that of an Esmarch tube, This cylindric expansion is divided into squares which make the counting of the colonies very easy. ; Roughly, the number of germs in the atmosphere may be estimated at from 100 to 1000 per cubic meter. The bacteriologic examination of air is of very little importance because of the numerous errors that must be met. Thus, when the air of a room is quiescent it may contain very few bacteria; let some Fig. 81.—Petri’s sand filter for air- Fig. 82.—Sedgwick and Tucker’s ex- examination. panded tube for air-examination. one walk across the floor so that dust rises, and the number of bac- teria becomes considerably increased; if the room be swept, the in- crease is enormous. From these and similar contingencies it be- comes very difficult to know just when and how the air is to be ex- amined, and the value of the results is correspondingly lessened. The most sensible studies of the air aim rather at the discovery of some definite organism or organisms than at the determination of the total number per cubic meter. CHAPTER XIII BACTERIOLOGY OF WATER UNLEss water has been specially sterilized, and received and kept in sterile vessels, it always contains some bacteria, the number usually bearing a distinct relationship to the quantity of organic matter present. The majority of the water bacteria are bacilli, and are as a rule non-pathogenic. Wright,* in his examination of the bacteria of the water from the Schuylkill River, found two species of micrococci, two species of cladothrices, and forty-six species and two varieties - of bacilli. Pathogenic bacteria, such as the spirillum of Asiatic cholera, the bacillus of typhoid fever, and the bacillus of dysentery may occur in polluted water, but are exceptional. The method of determining the number of bacteria in water is very simple, and can be accomplished with very'little apparatus. The method depends upon the equal distribution of a measured quantity Fig. 83.—Wolfhiigel’s apparatus for counting colonies of bacteria upon plates. of the water to be examined in some sterile liquefied medium, whose _ subsequent solidification in a thin layer permits the colonies to be counted. The method originated with Koch, and may be performed with plates, Petri dishes, or Esmarch rolls. It is always best to make a number of cultures with different quantities of the water, using, for example, 0.01, 0.1, 0.5, and 1.0 cc., respectively, to a tube of liquefied gelatin, agar-agar, or glycerin agar-agar. The details of the method depend upon the quality of the water to be examined. If the number of bacteria per cubic centimeter be small, large quantities may be used; but if there be millions of bac- teria in every cubic centimeter, it may be necessary to dilute the water to be examined in the proportion of 1:10 or 1: 100 with sterile water, mixing well, and making the plate cultures from the dilutions. * “Memoirs of the National Academy of Sciences,” vol. vil, Third Memoir. 237 238 Bacteriology of Water It is best to count all the colonies developed upon the culture, if possible; but when hundreds of thousands are scattered over it, an estimate made by counting and averaging the number in each of the small squares of some counting apparatus, such as those devised by Wolfhiigel, Esmarch, or Frost. In counting the colonies a lens is indispensable. In some cases, where bacteria are exceedingly numerous, as badly contaminated waters, in the study of sewage, in inflammatory exu- dates, and in cultures intended for the preparation of bacterial vac- cines, it is expedient to directly enumerate the bacteria without resorting to the cultivation method, where all of the organisms may not grow. Excellent methods for the computa- tion of bacteria have been devised. That of Winslow and Willcomb* being as follows: “The cover-slips should be boiled in a 10 per cent. solution of potassium bichromate in 50 per cent. sulphuric acid and allowed to lie in this cleansing mixture. Just before using they may be rinsed in 50 per cent. alcohol and dried on a silk cloth, not in the flame. One-twentieth of a cubic centimeter of water placed on such a cover-slip spreads evenly and should be allowed to dry in the air without sudden heating. After drying it is fixed by Fig. 84.—Esmarch’s instru- passing through the flame, covered with Ziehl- ment for counting colonies of Neelson’s carbol-fuchsin, warmed until steam bacteria in Esmarch tubes. just rises, washed, dried, and mounted. For counting the bacteria we use a Sedgwick-Rafter eye-piece micrometer, made for the study of the larger micro-organisms in drinking water.” Very uni- form results have followed. I The method of Wright} was devised for the computation of bac- teria in suspensions used in making tests of the opsonic power of the blood and is given in the chapter upon ‘‘ The Opsonic Index.” The majority of the water bacteria rapidly liquefy gelatin, on which account it is better to employ both gelatin and agar-agar in making the cultures. In ordinary city hydrant-water the bacteria number from 2 to 50 per cubic centimeter; in good pump-water, 100 to 500; in filtered water from rivers, according to Giinther, 50 to 200; in unfiltered river- water, 6000 to 20,000. According to the pollution of the water the number may reach as many as 50,000,000. The waters of wells and springs are dependent for their purity upon the character of the earth or rock through which they filter, and the watersof deep wells are much more pure than those of shallow wells, unless contamination take place from the surface of the ground. : * “Tour. of Infectious Diseases,” Supplement, May, 1905, No. 1, p. 273 “ Y, 1995; t “Lancet,” July 5, 1902. Determination of Bacteria in Water 239 Ice always contains bacteria if the water contained them before it was frozen. In Hudson River ice Prudden found an average of 398 colonies in a cubic centimeter. A sample of water when collected for examination should be placed in a clean sterile bottle or in a hermetically sealed pre-ster- ilized glass bulb, and must be examined as soon as possible, as the bacteria multiply rapidly in water which is allowed to stand for a short time. If the water to be examined must be transported any considerable distance before the manipulations are performed, it should be packed in ice. The greatest care must always be exercised that the unnatural conditions arising from the bottling of the water, the changes of temperature, and the altered relationship to light and the atmosphere, do not modify the number of contained bacteria. VeaRun sei on a MSE aie Renmes a pI “a a _Fig. 85.—Frost’s plate counter, for counting colonies of bacteria on Petri dish or plate cultures. The cross-lines divide the figure into square centimeters. The numbers at the top of the figure indicate the area in centimeters of the various discs. The area of each sector (a and b) is one-tenth of the whole area. The detection of such important bacteria as the colon, typhoid and dysentery bacilli, and the cholera spirillum, will be considered in the chapters treating of those respective organisms. Drinking-water, especially that furnished to large cities, is not infrequently contaminated with sewage, and contains intestinal bacteria—Bacillus coli. For the ready determination of this organ- ism, which is an important indication that the water is polluted, Smith* has made use of the fermentation-tube in addition to the * “Amer, Jour. Med. Sci.,” 1895, cx, p. 301. — = ” pap poe Peet [=| + | = lt — = a re i fl + 4+) uueansuunz |: ss tt snaceiyso "g = isa MOTLPA =p om fb ie eR a be PL b= IIR A, ‘+ + +5 snoipisep -g *MOUPA—IdGA] DJueZoWIOIYD «= *Al dnosp : = = ” tHe JS et le ee Rt] ot Oo AERA] 4 poepteera sc: snoenueine "g = = » — J—|-H} 4+ f4)4+] + 4} -— |- [4+ — |+| wuemsomunz |-tte snosny ‘gq = = i ene EN ape | RE ae NN) Sg, |e tae — {4} uueusauiuiz }- SAIN} “q — _ Me —j4/—J-+} — J + +\+ 4+i-]+ 7 — 44) — |—/-4-f-4] — [4+]: °° puoaeag]e cc ce suaosaine "g = _ aduv1gQ —4\-/-| — |— hot} t+ i41— tf — l4l+] + | —-eit+l-l--l+] — [4]: > puepquery SED tee ee susodsaioqie *g | ‘eBuBig—adA] sJueZowosyD = *y] dnosp = — | pea xa [H — fo e+] + ie =| + FI¢] + is aa — |+)° ° Broquesiq | tt snpiqni “gq = — wos |) )— f+] + tit] + ltl + E+ 44) + oP — TIF I+ IR 4] — f+] +t Saequaryg fs te snsol3ipoid “gq 7 *pay—odA] opuesowosyy ‘Jy dnoup x - abe ee — Jere tei +] —- BIH ot J -IAtREREI - IFI- wsyM oyuZooUI suadsaiony “g{ Es + + = +4ljt] +f tp tP tt ftp td + elt] +] — fit ]4+ felt] — jt] ct pressed fo snaueho0Ad “g = — + = =] = eee ce eee De IRR) ee eee] yt Jouaaey fot sI[B@Ao suadsaiong “gq ae z = Seeley + Ht] +loe | plas + SNS eee bls aie a reg ee yee SIPIIA “@ iran ae — _ — |-— —| — — | — — | —|j-| —it]* * srequesiq js ccc ts suald ° -vjanbij-uou = suadsaiony “g > — + = —|+/—]+| — | + J4]/4)4+ lf4]—i - Alt + | —/+l4+b I+] — [4+] °* + e88nqy }: + suaioesenby suaosaiong ‘g Bo ‘adh BUDDSaJON,Yy °] dnoup = gadhes totes eas ad oes ° so5 St ESE [ot] mS lS|BEIZ) we lo FIRiS| aslo S| So [Eles 9) SlElelesis- 28 o Fag 188 £9 BIRO GS (S8ieikias 28zi 22 |sleeae| SF os ialSlr gl= »Y "3 0 gi og 0 S| ao (S151S516 sls/2e) ac lalalPasl © ali Jaleo’ ale oO pon ds 290 O}o| 2 Poa lB /Posai@lgay se lpi? ls ool o v|) Pe) ale 6 pes ° at oe lslz o . cre ree ag 3 ra o| =|" A a3 aigle a. Pepa? OP BT] js FS 9 2/8 /8) 5 c | BE) Sf os| se) ol] ez jez 8 oie. om le Q 0, B| | AOLVOLLSTAN a soe ey |e op | Be mle) 3 33 2s | 25 BE oe He} Isuld ! ‘WSINVDYOQ 40 SNVN TA qu Qing Bo ole] #8 5 [oo] es ea c oTtU MA, iesy younyN eo S QF TPs lo es 23 relies e Be ? ; ea oT” Eo ‘| F ig 8 8 SISHNGD ‘SHUNLVAY TWOINaHOOIg ‘SAUNLVAY IWaAnLing -OHLVg- *ADOIOHA : -40 “ADOT0I4 e 240 ‘OIHO ‘ILVNNIONIO LV YALVM UAAIY OIHO NI GNNOA ITTIOVA AO NOLLVOIAISSVIO 241 Water +) IL | la In Pttd PLItt [+ Il oUt Fl Determination of Bacter }t+ - =) | = SS = le = | = LL = | = LL. = ay Pee | eee SUBOTPUBS “g ‘odAL suBsipueg “TTX dnosn : = — |—H-} 4+ 14) —9 + 4] — | -— (Stl l+] — [4] ameqpsyqorm | * * > A snyeoqns sienbe “g eee — JjJ—-ey + i+ t+ + J—-lt+) — | — |-]4+)-F 4] — {4+ uneq[asyaiaM ‘+ + +] snzeomns sijenbe -g fas — }—-e 4s lele] + Gi] -— |--aie] leo eueaer fn Snleyos “g = Se) ae ease EL ae ote ise = —I+I+F i+] — |+ yueqy | °° oT snydAynus “g ‘adAL snsoyddy “WX dnosp = foes a eee ee a ee ee ee fe is le Ela _ | — f=|e eo. — |+lo: yomayssq] sc souadol0e “g = HIF I++) + ss [fe Se ey a iz fan” +i-|4+) — J4}° >) qoeyosay SIUNUWIWOS [OD “g uo] Y = +) — | — i+} 4+ J-| -— — EI] — | — J-4+[4+9-—l+] — [4+] woewrowunz]: > + + srmuuos sinenbe -g = —l+]—-+} — | —H44) 4h} —] -— I+} — J-—Hy4i4f-it}—J4i0 em snjeinotued “g _ —|]+/—'+} — |—J4]414+ +) - 4] = Oy AE) ate ek WS [oo snsonxay “g ay mettle ics] eee |e Re eh fob op — |---| — | — it] = epee: 8 SUM snjejnuue “g pl S| = ae Sie Ne = ite — [qe ess uepiof| esa ere syeisyaodns “g sodA reisaes ng *x dnoip — sefae feta] oe J a iz + | + + ee | _— Seles —ftls + + Jauaaey fe ccs SIWIojIuUaue “g - —|+j-|\-} — | — |-}+} + ears canta ae ean so —l+)— f+jo 0 puepueag ss snpimbiy “¢ = oe ee ee eee ee eed ee E is Te ig _— | — ete [aie —{4!+° Srequasrq * suaeyenbiy “g = +f4fti4} + | + f+l+) 4 i+) 4+ bo 4+ J4l4+l — | mle iti th lt+| — J+) 0 cc uepsof ps BIBOlD “FL cadAY VIVID “THA dnuin = ps| Se laa[se Po ee ite [st bl Se eal ea oh baea| ot Ua oF + ey * neve | Se ee eee sneies “gq — eet | ae fee ed a ee ye able |) ste Aa se lier) ob lee" AOU OT Ay rates wees Caen SIGNS “g. “oGAL sunans ‘I a ins! +y—-/—'-]} — | + lesa] + fey t+ + [+i+ — —I4+!- qesgef|* *- + * suasserong snajoid -g = —l+}+i+}) — + J+i+} + J+) 4+ + f+ 2 + + [+]° ° Saaquasig | * + + snjyes[na snotaquesour -g — —|+j-- +] — | + J4]4+]) 4 1414+ 004+ I4i4} 4+ J + itis assy ls ss seploodur “g ad A SN3}0Ig “IA aisih PIOTA —s+)-/4+) — | 4+ ]4/4)/4 44 - +)/+ +f—|+] — |4) °° puepjuerz SNSOFIOIA ‘g PIOIA Aleq +| — | 4 f4Fl4| + Ie = ies = [Flt Re ee + [it = Sah eee a jdoz snuryquel “g *yayorA—adA a omcamaaees ‘A dnoip ‘ ae eet ae spe ee + |-l4] + |-—/[4] —|l-| — |—-lo ot astorpog | ean], BuIdIE! iy A — |j-|—-} + | + —- -eY — — |J-l+/—F-]4+] — [+ “uueunauunty SP ot A ie enaeyana ‘a co “ —j+j-|4+}) — + l+l+l + = — — |4ti4+} + + J—j+j4+f-/-] — i+ * addny |* + * + sauago1y3A1a stoey] ‘a MOLPA = S ee SS ee SS eee ERI) Ute rahe ones ae re PIO SE Sy ae eres suaosaaEy “g 16 242 Bacteriology of Water plate. His method is to add to each of several fermentation-tubes containing 1 per cent. dextrose-bouillon a certain quantity of water, The evolution of 50-60 per cent. of gas by the third day is a strong indication that the colon bacillus is present. The presence of gas in a fermentation tube constitutes the “presumptive test” for the colon bacillus. It is not an infallible indication of their presence, A careful study of its usefulness has been made by Ruediger and Slyfield* who found that in making quantitative determination of B. coli in polluted waters by means of the fermentation tubes, the most accurate results were obtained by the use of neutral-red lactose bouillon. Gas appeared earlier in the neutral-red lactose tubes than in lactose bile broth tubes, and B. coli were more easily isolated, by plating, from the former than from the latter. The finding of B. coli in the fermentation tubes is greatly facilitated by making | plates soon after the appearance of the gas. When the fermenta- tion of the sugar and the appearance of gas in the tube occurs, some bacteriologists are satisfied that B. coli are present, and go no fur- ther, but a careful workman will always take pains to confirm the indications of their presence by plating and isolating the bacillus in pure culture. It was at one time thought that the occurrence of the colon bacillus in water was sufficient to condemn its potability, but the evidence accumulated in recent years, showing that this organism may reach streams from manured soil, may enter it with the dejecta of domestic animals, wild animals, birds, and perhaps even of fishes, makes it doubtful whether anything but an exceptionally large number of the organisms should be looked upon as indicative of sewage pollution and proof that the water is not potable. In determining the species of bacteria found in the water reference must be made to the numerous monographs upon the subject and to special tables. An excellent table of this kind, arranged by Fuller, is given on pages 240 and 241. Filtration with sand, etc., diminishes the number of bacteria for a time, but, as the organisms multiply in the filter, the benefit is not permanent and the filters must frequently be subjected to bacterio- logic tests and the sand washed, spread out to dry and the filters renewed. Porcelain filters seem to be the only positive safeguard, and even these, the best of which seems to be the Pasteur-Chamber- land, allow the bacteria to pass through if used too long without proper attention. For those whose special line of work is the bacteriology of water, the report of the Committee on Standard Methods of Water Analysis to the Laboratory Section of the American Public Health Association, published in Supplement No. 1 of the “Journal of Infectious Dis- eases,’ May, 1905, will prove indispensable. *Jour. of the American Public Health Association, 1911, 1, No. 11, p. 828. t “Public Health and Journal of Experimental Medicine.” CHAPTER XIV BACTERIOLOGY OF THE SOIL Tue upper layers of the soil contain bacteria in proportion to their richness in organic matter. Near the habitations of men, where the soil is cultivated, the excrement of animals, largely made up of bac- teria, is spread upon it to increase its fertility, this treatment not only adding new bacteria to those already present, but also enabling those present to grow much more luxuriantly because of the increased nourishment they receive. Where, as in Japan, human excrement is used to fertilize the soil, or as in India, it is carelessly deposited upon the ground, bacteria of cholera, dystentery, and typhoid fever are apt to become disseminated by fresh vegetables, or through water into which the soil drains. In such localities fresh vegetables should not be eaten, and water for drinking should be boiled. The researches of Fliigge, C. Frankel, and others show that the bacteria of the soil do not penetrate deeply, but gradually decrease . in number until the depth of a meter is reached, then rapidly di- minish until at a meter and a quarter they rather abruptly disappear. The bacteria of soil are, for the most part, harmless saprophytes, though a few highly pathogenic organisms, such as the bacilli of tetanus and malignant edema, occur. Many of them are anaérobic, and it is interesting to speculate upon their biology. Whether they develop and multiply in the soil in intimate association with strongly aérobic organisms by which the free oxygen is aborbed, or whether. they remain latent in the soil and develop only in the intestines of animals, is not known. The estimation of the number of bacteria in the soil seems to be devoid of any practicalimportance. C. Frankel has, however, origi- nated an accurate method of determining it. By means of a special boring apparatus earth can be secured from any depth without . digging and without danger of mixing with that of the superficial strata. A measured quantity of the secured soil is thoroughly mixed with liquefied sterile gelatin and poured into a Petri dish or solidified upon the walls of an Esmarch tube. The colonies are counted with the aid of a lens. Fltgge found in virgin earth about 100,000 colonies in a cubic centimeter. Samples of earth, like samples of water, should be examined. as soon as possible after being secured, for, as Giinther points out, the number of bacteria changes because of the unusual dryness, warmth, exposure to oxygen, etc. The most important bacteria of the soil are those of tetanus and 243 244 Bacteriology of the Soil malignant edema, in addition to which, however, there are a great variety of organisms pathogenic for rabbits, guinea-pigs, and mice. In the “Bacteriological Examination of the Soil of Philadelphia,” Ravenel* came to the conclusion that— 1. Made soils, as commonly found, are rich in organic matter and excessively damp through poor drainage. 2. They furnish conditions more suited to the multiplication of bacteria than do virgin soils, unless the latter are contaminated by sewage or offal. Fig. 86.—Tip of Frankel’s instrument tor obtaining earth from various depths for bacteriologic study. B shows the instrument with its cavity closed, as it appears during boring; A, open, as it appears when twisted in the other direction to collect the earth. 3. Made soils contain large numbers of bacteria per gram of many different species, the deeper layers being as rich in the number and variety of organisms as the upper ones. After some years the number in the deeper layers probably becomes proportionally less. Made soils are more likely than others to contain pathogenic bacteria. In seventy-one cultures that were isolated and carefully studied by Ravenel, there were two cocci, one sarcina, and five cladothrices; all the others were bacilli. * “Memoirs of the National Academy of Sciences,’ First Memoir, 1896. CHAPTER XV THE BACTERIOLOGY OF FOODS TuE relation of bacteria to foods is an important one and should be as thoroughly understood as possible by both the profession and the laity. The relationship may be expressed thus: I. Foods serve as vehicles by which infectious agents are con- veyed to the body. II. Foods are chemically changed and made unfit for use by the bacteria. I. Foods as Fomites.—In animal food the first source of infection is the animal itself, danger of infection always accompanying the employment of foods derived from diseased animals. Thus, milk apparently normal in appearance has been found to contain danger- ous pathogenic bacteria. The tubercle bacillus is one of the most important of these, and at the present time the consensus of opinion inclines toward the view that the great prevalence of tuberculosis among human beings depends partly upon the ingestion of tubercle bacilli in milk. It does not appear necessary that the udder of the cow be diseased in order that the organisms enter the milk, as they seem to have been found in milks derived from cows whose udders were entirely free from demonstrable tuberculosis. It is, therefore, imperative to retain only healthy cows in the dairy, and careful legislation should provide for the detection and destruction of all tuberculous animals. The detection of tubercle bacilli in milk can only be certainly accomplished by the injection of a few cubic centi- meters of the fluid into guinea-pigs and noting the results. In addition to the tubercle bacillus, pyogenic streptococci have been observed in enormous quantities and almost pure culture in milk drawn from cows suffering from mastitis. Stokes* has observed a remarkable case of this kind in which the milk contained so much pus that it floated upon the top like cream. Such seriously in- fected milk could not be used with safety to the consumer. In market milk one occasionally finds pathogenic organisms, such as the diphtheria bacillus, typhoid bacillus, streptococcus, etc., de- rived from human sources. Such polluted milks have been known to spread epidemics of the respective diseases whose micro-organisms are present. Bacteria may enter milk from careless handling, from water used to wash the cans or to dilute the milk, or from dust; and as milk is an excellent medium for the growth of bacteria, it should *“Maryland Medical Journal,” Jan. 9, 1897. 245 246 The Bacteriology of Foods always be treated with the greatest care to prevent such contamina- tion, as saprophytic bacteria produce chemical changes in the milk, such as acidity and coagulation, which destroy its usefulness or render it dangerous as food for infants and invalids. Where the necessary precautions are not or cannot be taken, Pasteurization of the milk as soon after its reception as possible may act as a safeguard. The student interested in the sanitary relations of milk cannot do better than refer to Bulletin No. 35 of the Hygienic Laboratory, Washington, D. C., 1907, “‘Upon the Origin and Prevalence of Typhoid Fever in the District of Columbia,” and to Bulletin No. 41 of the same laboratory, upon “ Milk and its Relation to the Public ’ Health” (1908); also to the “ Bacteriology of Milk,” by Swithinbank and Neuman, New York, E. P. Dutton & Co., 1903. Meat from tuberculous animals might cause disease if eaten raw or but partially cooked. As cooking suffices to kill the organisms, the danger under ordinary conditions is not great. Moreover, tuberculosis rarely affects the muscles, the parts usually eaten. Butter made from cream derived from tuberculous milk may also contain tubercle bacilli, as has been shown by the researches of Rabinowitsch.* Foods may become polluted with bacteria in a variety of ways that will suggest themselves to the reader. The common source is dust, which is more or less rich in bacteria according to the soil from which it arises. The readiness with which raw foods, such as meats, milk, etc., can be thus contaminated in the barnyard, dairy, slaughter- house, and shop, teaches but one lesson—that the greatest cleanli- ness should prevail for the sake of the dealer, whose goods may be spoiled by carelessness, and the consumer, who may be injured by the food. Any food may carry infectious organisms upon its surface, such organisms being derived from the hands of the dealer, from dust, from water, as when green vegetables are sprinkled with impure water to keep them fresh, or from other sources. The cleanliness of the merchant and the protection from contami- nation that he bestows upon his goods should be taken into consid- eration by his customers. Shell-fish, especially oysters, seem to be common carriers of infec- tion, especially of typhoid fever. The oysters seem to be contami- nated with infected sewage carried to their beds. It is not yet satisfactorily determined whether typhoid bacilli multiply in the juices in the shells of the oysters or not, but a number of epidemics of typhoid fever have been very conclusively traced to the consump- tion of certain oysters at a definite time and place. As cooking the oysters will kill the contained bacilli, the prophylaxis of disease in this case is very simple. * “Deutsche med. Wochenschrift,”” 1900, No. 26; abstract in the “Centralbl. f. Bakt.,” etc., 1901, XXIX, p. 309. Food Poisons 247 Il. Food Poisons.—The nomenclature, suggested by Vaughan and Novy,* contains the following terms: Bromatotoxism—food-poisoning; Galactotoxism—milk-poisoning; T yrotoxism—cheese-poisoning; Kreotoxism—meat-poisoning; Ichthyotoxism—fish-poisoning ; M ytilotoxism—mussel-poisoning; Sitotoxism—cereal-poisoning. The most important chemic alterations:effected by bactena occur in milk and meat. 1. Milk-poisoning (Galactotoxism).—Milk, even when freshly drawn from the cow, always contains some bacteria, whose numbers gradually diminish for a few hours, then rapidly increase until almost beyond belief. These organisms are for the most part harmless to the consumer, but ultimately ruin the milk. Although much attention has been paid to the subject, bacteriologists are not agreed whether the number of bacteria contained in milk is a satis- factory guide as to its harmfulness. The poisonous change in milk, cream, ice-cream, etc., has been shown by Vaughan to depend in part upon the presence of a ptomain known as ¢yrotoxicon, formed by the growth of bacteria in the milk, but whether by any particular bacterium is not known. The milk may become poisonous during any time of the year, but chiefly in the summer, when, because of the higher temperature, bacteria . develop most rapidly. The change takes place in stale milk, and it is supposed that many cases of what was formerly looked upon as “summer complaint” in infants were really poisoning by this toxic ptomain. Ice-cream poisoning depends upon the growth of the bacteria in the milk before it is frozen. In some cases the error made has been to prepare the cream for freezing and then keep or transport it, the freezing operation being delayed until the development of the bac- teria has led to the poisonous condition.. Cheese-poisoning (ITyrotoxism) is also thought to depend upon tyrotoxicon at times, though it has been shown that other cheese poisons exist. It is more or less a question whether cases of milk- and cheese-poisoning do not depend upon the toxic products of the colon bacillus growing in the foods. 2. Meat-poisoning (Kreotoxism).—Botulism or meat-poisoning depends upon the growth of certain bacteria, Bacillus botulinus of van Ermengem,{ in the meat. The symptoms following infection by the organism sometimes closely resemble those of typhoid fever, and are characterized by acute gastro-intestinal irritation, nervous * “Cellular Toxins,” Phila., 1902. } “Zeitschrift fiir Hygiene,” Bd. xxv1, Heft 1. 248 The Bacteriology of Foods disturbances, and, in case of death, by fatty degenerations in the organs and minute interstitial hemorrhages. 3. Fish-poisoning (Ichthyotoxism) sometimes follows the con- sumption of canned and presumably spoiled fish, sometimes the consumption of diseased fish. It is not known whether it depends upon ptomains or upon toxicogenic germs, though probably the latter, as Silber has isolated a Bacillus piscicidus that is highly toxicogenic. 4. Mussel-poisoning (MJytilotoxism) depends partly upon irri- tating and nervous poisons in the mussel substance, in part upon toxicogenic germs that they harbor. 5. Canned’ Goods.—Improperly preserved canned goods not in- frequently spoil because of the growth of bacteria, but the occur- rence of gas-formation, acidity, insipidity, etc., causes rejection of the product, and but few cases of supposed poisoning from canned goods can be authenticated. CHAPTER XVI THE DETERMINATION OF THE THERMAL DEATH-POINT OF BACTERIA SEVERAL methods may be employed for this purpose. Roughly, it may be done by keeping a bouillon culture of the micro-organism to be investigated in a water-bath whose temperature is gradually increased, transplantations being made from time to time until the fatal temperature is reached. It is economy to make the transplantations less frequently at first than later in the experiment, when the ascending temperature approaches a height dangerous to life. In ordinary determinations it is well to make a transfer at 40°C., another at 45°, another at 50°, still another at 55°, and then, beginning at 60°, make one for every additional degree. The day following the experiment it will be ob- served that all the cultures grow except those heated beyond a- ° certain point, say 62°C., when it can properly be concluded that 62°C. is the thermal death-point. If all the transplantations grow, of course the maximum temperature was not reached, and the ex- periment must be repeated and the bacteria exposed to still higher temperatures. When more accurate information is desired, and one wishes to know how long the micro-organism can endure some such tempera- ture as 60°C. without losing its vitality, a dozen or more bouillon- tubes may be inoculated with the organism to be studied, and stood in a water-bath kept at the temperature to be investigated. The first can be removed as soon as it is heated through, another in five minutes, another in ten minutes, or at whatever intervals the thought and experience of the experimenter shall suggest, the subsequent growth in each culture showing that the endurance of the organism had not yet been exhausted. By using gelatin, pouring each culture into a Petri dish, and subsequently counting the colonies, it can be determined whether many or only a few of the organisms in a culture possess the maximum resisting power. To determine the percentage, it is necessary to know how many bacteria were present in the tubes before exposure to the destructive temperature. Ap- proximately the same number can be placed in each tube by adding the same measured quantity of a fluid culture to each. In both of the procedures one must be careful that the temperature of the fluid in the test-tube is identical with that of the water in the bath. A sterile thermometer introduced into an uninoculated tube 249 250 The Thermal Death-point exposed under conditions similar to those of the experiment canbe used as an index for the others. Another method of accomplishing the same end is by the use of Sternberg’s bulbs. These are small glass bulbs blown on one end of a glass tube, drawn out to a fine point at the opposite end. If such a bulb be heated so that the air is expanded and partly driven out, its open tube, dipped into inoculated bouillon, will in cooling draw the fluid in, so as to fill it one-third or one-half. A number of these tubes are filled in this manner with a freshly inoculated culture medium and then floated, tube upward, upon a water-bath whose temperature is gradually elevated, the bulbs being removed from time to time as the required temperatures are reached. As the bulbs are already inoculated, all that is necessary is to stand them aside for a day or two, and observe whether or not the bacteria grow, determining the death-point exactly as in the other case. CHAPTER XVII DETERMINATION OF THE VALUE OF ANTISEPTICS, GERMICIDES, AND DISINFECTANTS Tue student must bear in mind that an antiseptic is a substance capable of restraining the growth of bacteria; a germicide, one ca- pable of killing them. All germicides are antiseptic in dilute solu- tions, but not all antiseptics are germicides. Disinfectants must be germicides. Antiseptics are chiefly employed for purposes of preservation, and are largely used in the industries to protect organic substances from the micro-organisms of fermentation and decomposition. The problem is to secure a satisfactory effect with the addition of the least possible preservative in order that its presence shall not chem- ically destroy the good qualities of the substances preserved. In the case of foods it becomes necessary to use preservatives free from poisonous properties. Disinfectants and germicides are employed for the purpose of destroying germs of all kinds, and the chief problem is to secure efficiency of action, rather than to endeavor to save on the reagent, which would be a false economy, in that the very object desired might be defeated. The following methods of determining the antiseptic and germi- cidal values of various agents can be elaborated according to the extent and thoroughness of the investigation to be made. I. The Antiseptic Value-—Remembering that an antiseptic is a substance that inhibits bacterial growth, the determination of its value can be made by adding varying quantities of the antiseptic to be investigated to culture-media in which bacteria are subse- quently planted. It is always well to use a considerable number of tubes of bouillon Containing varying strengths of the reagent to be investigated. If the antiseptic be non-volatile, it may be added before sterilization, which is to be preferred; but if volatile, it must be added by means of a sterile pipet, with the greatest precaution as regards asepsis, after sterilization and immediately before the test is made. Control experiments—i.e., bouillon cultures without the addition of the antiseptic—should always be made. The results of antiseptic action are two: retardation of growth and complete inhibition of growth. As the inoculated tubes containing the antiseptic are watched in their development, it will usually be observed that those containing very small quantities develop al- most as rapidly as the control tubes; those containing more, a little 251 \ 252 Value of Antiseptics more slowly; those containing still more, very slowly, until at last there comes a time when the growth is entirely checked. Sternberg points out that the following conditions, which must be avoided, may modify the results of experiment: 1. The composition of the nutrient media, with which the anti- septic may be incompatible (as bichloride of mercury and albumin). 2. The nature of the test-organism, no two organisms being ex- actly alike in their susceptibility. 3. The temperature at which the experiment is conducted, a Same rod immersed in broth after exposure to disinfectant. Fig. 87—Glass rod in test-tube, for use in testing disinfectants. Tube 6 in. by 34 in.;rod 9 in. by }4 in. Ring marked with diamond 1 in. from lower end, to show upper limit of area on which the organisms are dried. After cx- posure the rod is placed in a similar tube containing broth, to test development. a, Cotton plug wrapped around glass rod; b, broth; c, gummed label on handle of rod, for identification; d, ring marked by diamond; e, dried organisms. relatively greater amount of the antiseptic being necessary at tem- peratures favorable to the organism than at temperatures unfavorable. 4. The presence of spores which are always more resistant than the asporogenous forms. II. The Germicidal Value.—Koch’s original method of determin- ing this was to dry the micro-organisms upon sterile threads of linen or silk, and then soak them for varying lengths of time in the germi- cidal solution. After the bathin the reagent the threads were washed in clean, sterile water, transferred to fresh culture-media, and their Sa = Testing Germicidal Value of Liquids 253 growth or failure to grow observed. This method also determines the time in which a certain solution will kill micro-organisms, so is advantageous. | Sternberg suggested a method by which the dilution necessary to kill the bacteria could be determined, the time remaining constant (two hours’ exposure) in all cases. “Instead of subjecting test- organisms to the action of the disinfecting agent attached to a silk thread, a certain quantity of a recent culture—usually 5 cc.—is © mixed with an equal quantity of a standard solution of the germi- cidal agent, . . . and after two hours’ contact one or two loopfuls are transferred to a suitable nutrient medium to test the question of disinfection.” A very simple and popular method of determining the germicidal value is to make a series of dilutions of the reagent to be tested; add to each a small quantity of a fresh liquid culture, and at varying in- tervals of time transfer a loopful to fresh culture-media. By a little ingenuity this method may be made to yield information as to both time and strength. Hill* has suggested a convenient method of handling the cul- tures, which are dried upon the ends of sterile glass rods and can then be transferred from one solution to another or otherwise manipulated. The Modern Method of Testing the Germicidal Value of Liquids.— The methods of testing germicidal strength given above are uncertain and inaccurate, and can only be looked upon as “‘rough and ready” methods, that should be willingly abandoned for anything better. Three methods are now offered that hold out the promise of scientific accuracy through anestablished standard of comparison. In theorder of their appearance, which is also, probably, the order of their impor- tance, these are the method of Rideal and Walker,} “‘The Lancet Method,’ t and the method of Anderson and McClintic.§ The _ methods are similar in general principles, and have the same object in view, i.e, the expression of the germicidal value of any sub- stance as the carbolic acid or phenol “‘coefficient.”” Experience with the methods leads to the conviction that the Rideal and Walker method is the more easy to execute, but that the Anderson-McClintic method is the more accurate. As the latter in addition to its ac- curacy has now become the standard method of the United States Government, it is the method with which the student should be ‘acquainted and which will be given in detail. I. The Apparatus, Reagents, etc., Required for the Test.—1. A Phenol Solution that shall act as the standard of comparison. In the preparation of this solution, pure phenol—as free from cresols, etc., as possible—should be employed. Walker recommends that only * “Public Health,” vol. xx1v, p. 246. t Journal of the Royal Sanitary Institute, London, 1903, p. 424. The Standardization of Disinfectants” (unsigned article), Lancet, London, vol. CLXxv1I, Nos. 4498, 4499 and 4500. § Bulletin No. 82 of the Hygienic Laboratory, Washington, D. C., 1912. 254 Value of Antiseptics phenol with a melting point of 40.5°C., be used, as only suchisentirely free from impurities. The Eighth Revision of the U. S. Pharma- copeeia declares phenol with a melting point of 40°C. to be pure and that is the quality that may be accepted as the standard. The phenol used at the Hygienic Laboratory is Merck’s “Silver Label.” The standard dilution, made by the U. S. P. method (Koppeschaar), contains exactly 5 per cent. of pure phenol by weight, _ in distilled water. From this stock solution, the higher dilutions are made fresh each day for that day’s tests. 2. The Solution to be Tested—A 5 per cent. solution is made by adding 5 cc. of the disinfectant to 95 cc. of sterile distilled water with a standardized 5 cc. capacity pipet. After filling the pipet, all excess of the disinfectant on its outside is wiped off with sterile gauze. The contents of the pipet are then delivered into a cyl- inder containing 95 cc. of sterile distilled water and the pipet washed out as clean as possible by aspiration and blowing out the contents into the cylinder. The contents of the cylinder are then thoroughly shaken. 3. The Test Organism selected is Bacillus typhosus. Before be- ginning the tests, the organisms in bouillon culture should be trans- planted to fresh media every twenty-four hours for at least three successive days. In making the transfers one loopful of a 4-mm. platinum loop is carried over. In exposing the culture to the dis- infectant, }{9 cc. of the culture is always added to 5 cc. of the diluted disinfectant, the amount being measured by pipets graduated in tenths of a cubic centimeter. _ 4. The Inoculating Loops.—These loops are made of No. 23 U. S. standard gauge platinum wire, each loop being 4 mm. in diameter. There should be four, and preferably six, such loops mounted in the usual glass handles, ready for use. In order to facilitate their sterilization, a special holder is used. 5. The Water-bath—As variations in the temperature of the disinfecting solutions hasten or retard their destructive action, a temperature of 20°C. has been arbitrarily adopted as the standard. For its maintenance the following simply constructed water-bath has been devised. It consists of a wooden box 20 inches deep, 21 inches long and 21 inches wide. Inside this box a 14-quart agate- ware pail, 1o inches deep, is placed and saw-dust is well packed around, sufficient being placed in the bottom of the box to bring the rim of the pail on a level with the top of the box. A tightly fitting wooden cover, so made that the edges project slightly over the rim, is placed over the pail. In the cover area sufficient number of holes for the seeding tubes, a thermometer, and the tube contain-_ ing the culture. About 3 inches below the rim of the pail a false bottom of wire gauze is placed; this is for the seeding tubes, etc., to rest on. Water is placed in the pail to within half an inch of the top. When an experiment is about to be made the tempera- Testing Germicidal Value of Liquids 255 ture of the water in the pail is taken, and if above or below 20°C., it is brought to the desired temperature by the addition of either Fig. 88.—Water-bath showing position of holes for seeding tubes and ther- mometer in place (Anderson and McClintic, in Bulletin No. 82, Hygienic Laboratory). i j y y y. / y y, Vad Fig. 89.—Cross section of water-bath showing seeding tubes in place (Ander- son and McClintic, in Bulletin No. 82, Hygienic Laboratory). hot or cold water. When the proper temperature has thus been adjusted, very little change takes place in an hour’s time. The apparatus is shown in the cut. 256 Value of Antiseptics 6. The Culture-media used for the primary culture, and for the subcultures, made after exposure of the micro-organism to the dis- infectant, is nutrient bouillon made with Leibig’s beef extract in the usual manner and given a reaction of exactly + 1.5. Anderson and McClintic achieve this by so carrying out the titrating of the medium that a distinctly perceptible pink color marks the point at which the addition of the alkali stops (see directions for titrating culture-media). 7. The Tubes for the culture and subcultures are ordinary culture tubes, containing 5 cc. of the nutrient bouillon mentioned above. They are filled, plugged and sterilized in the usual manner. The tubes for “seeding,” i.e., exposing the bacteria to the ger- micide, are more convenient when shorter. At the time of transfer, the platinum loop is to be introduced into the tube as it stands in the water-bath and as this is not easy with tubes of standard length, Anderson and McClintic recommend tubes 1 inch in diameter and 3 inches long. These are plugged and sterilized by dry heat, or as recommended by the authors quoted, are sterilized mouth down, without plugs in a paper-lined wire basket. 8. The Dilution of the Phenol and Test Solutions.—This is done in standardized graduates with standardized pipets, according to the requirements of the particular case. Anderson and McClintic give tables that are useful for making the dilutions, though with the aid of a little arithmetic it is easy to calculate the proportions of the 5 per cent. solutions already prepared, and sterile distilled water necessary to make the test solutions required. As it is certain that some of the dilutions will be below germicidal strength, and as “weeds”? may be more difficult to kill than the test organism (B. typhosus) it is important to see that the distilled water used for dilution is sterile, and that the cylinders and bottles or pipets used for making the dilutions are all sterile and that the dilutions themselves are made with aseptic precautions. Under the standard conditions recommended, the phenol solu- tion that destroys all of the B. typhosus introduced, in 214 minutes is 1:80, but it is always wise to make additional dilutions to control the strength, as shown in the table below. When the strength of the disinfectant or germicide to be tested is entirely unknown, it is well to begin by making a number of tests with widely sepa- rated dilutions, by one of the “rough and ready” methods, so as to arrive at an approximate strength, before commencing the more difficult technic required for the determination of the phenol co- efficient, which should be looked upon as the final test for exact comparison. 9. Racks for Holding the Tubes are indispensable. The “seeding tubes,” that is, the tubes in which the actual exposure of the culture to the germicidal solutions is to take place, have already been pro- vided for in the construction of the water-bath. Testing Germicidal Value of Liquids 257 For the “subculture” tubes, any test-tube rack will do, but it is more convenient to have a special rack or stand made. That recommended contains five rows of 14 holes each. Each tube of culture-medium is carefully marked with a blue pencil to show three things, 1, the germicide; 2, the dilution; 3, the time of exposure, and stood in its place in the rack as will be explained below. yee old Yt / CE ial SS) sf 2 wall Fig. 90.—Block for subculture tubes (Anderson and McClintic, in Bulletin No. 82, Hygienic Laboratory). Fig. 91.—Device for flaming inoculating loops (Anderson and McClintic, in Bulletin No. 82, Hygienic Laboratory). The transplantations from the seeding tubes to the culture tubes are to be made every 214 minutes up to 15 minutes, so that for each strength of dilution to be tested, there will be six tubes. In addition to these test-tubes there will be four dilutions of phenol to act as controls so that every 214 minutes ten transplantations must be made. As 214 minutes contain 150 seconds, and as the picking up and opening of the subculture tube, the transfer of the seed-culture to the medium, the replacement of the stopper and the return of the tube to the rack require about 15 seconds at the hands of an U7 258 Value of Antiseptics expert manipulator, the ten tubes in the series comprise the maximum number that can be handled. The illustration shows one of the racks, and indicates how the tubes are placed in ten rows of six each, each row with an empty hole on the left. As the first tube of each series is inoculated, it is stood in the left-hand empty hole, the second stood in the hole from which the first was taken, the third in that from which the second was taken, and so on, so that there is always an empty hole to show the operator which tube to take up for the next inoculation. The Technic of Determining the Phenol Coefficient.—Everything being ready as outlined above, one proceeds as follows: The 24-hour bouillon culture of B. typhosusis shaken, then poured through a sterile filter-paper in a sterile glass funnel and caught in a sterile tube. In this way clumps of bacteria are removed and uniformly distributed bacteria secured for addition to the “seeding tubes.” Exactly 5 cc. of each dilution to be tested is now measured into a seeding tube. To economize glassware the same pipet may be used for a whole series, by beginning at the lowest dilution, meas- uring out the necessary 5 cc. into the first seeding tube, with a 5-cc. delivery pipet. The contents of the pipet are then thor- oughly blown out, and a pipetful of the next weaker dilution taken up to wash out the pipet. After this has been thoroughly blown out and thrown away, a pipetful of this second strength of diluted disinfectant is carefully measured into a second seeding tube, after which the same is done with each remaining dilution in turn. The tubes are so marked and so arranged in the rack of the water-bath that no mistake can be made in transplanting from them in regular order later. As each tube is filled, the stopper is replaced and when all have been filled and stood in the rack, it is placed in the water-bath and the temperature raised to 20°C. Anderson and McClintic do not use cotton plugs for the seeding tubes but sterilize them, open end down in a paper-lined wire basket. Some feel safer, however, in using tubes with plugs. The culture now being filtered, and the seeding tubes each with the re- quired 5s cc. of each dilution of the disinfectant to be tested, all at 20°C. in the water-bath, the subculture tubes marked and stood in their respective places in the racks, sterilized pipets at hand, and four or six platinum loops on the block ready sterilized, with the burner in place ready to re-sterilize them, the technic is continued by the addition of the culture to the seeding tubes. At this point one should make a slight calculation: if the culture is to be added to each of ten of the seeding tubes, it must be done before the expiration of 150 seconds or 214 minutes for at the con- clusion of that time, the first transplantation from each seeding tube to a culture tube must take place. We have averaged 15 seconds for each operation. If each transfer takes an average of Testing Germicidal Value of Liquids . 259 15 seconds, the operator must have every detail of the technic so well in hand, and the materials so conveniently placed, etc., that he can complete the entire performance of the technic from the addition of the culture to the seeding tubes to the last trans- plantation from seeding tubes to subculture tube without a hesita- tion and without a distraction. It is on account of the necessity of this “‘continuous performance” that such care was taken to point out the exact details of apparatus and materials needed, before describing the technic. To return to the seeding of the tubes, a sterile pipet graduated n lo cc. is used. The cotton stoppers are removed from the . seeding tubes and thrown away as of no further use. One by one as the time arrives, tubes are taken in one hand, inclined to an angle of about 45 degrees, while the tips of the pipet are lightly touched to that side of the tube from which the fluid has run away on account of the slanting, and exactly 0.1 cc. of the cul- ture delivered. This may under no circumstances take longer to perform than 15 seconds, and if one succeed in finishing it in a shorter time, he must wait until the calculated time arrives before delivering the culture into the next tube and so on until the end is reached. Each tube is given three gentle shakes after being straightened up, then returned to the water-bath. ' With a ten-tube series, and a time allowance of 15 seconds for each tube, the entire series of tubes is no sooner completed than the time (214 minutes) for making the first series of transplanta- tions to the subculture tubes has arrived. The operator therefore seizes at once the first of the culture tubes in the 214-minute series _with one hand, and a sterile platinum loop with the other. He cautiously removes the cotton plug from the culture tube, and at the proper moment introduces the platinum loop into the first seeding tube all the way to its bottom, withdraws it, and carries one drop of the contained fluid into the first subculture tube which he plugs and places in the empty hole to the left of the row in the block, at once taking up its neighbor on the right. As only 15 seconds are allowed for each such transfer, the operator must pro- ceed without hesitation. There is no time to sterilize the platinum loop, so he lays it on the block, pushes the flame under it and takes up an already sterilized loop with which he performs the same act of transplantation for the second tube that was done for the first, doing it on the appropriate second of time, and so continuing through the whole series. Every test of the phenol coefficient of disinfection must em- brace two such series, one made with the dilutions of the phenol that is to act as the standard, the other made with the dilutions. of the disinfectant to be determined. If, however, a variety of dif- ferent germicides are to be tested the same day, one phenol test will answer the requirement of the whole group. The following 260 Value of Antiseptics tabulation will make clear the details of a test (Table 17 from Anderson and McClintic’s paper). TABLE 17 Name “A.” Temperature of medication 20°C. Culture used. B. typhosus, 24-hour extract broth-filtered. Proportions of culture and disinfectant, 0.1 cc. X 5 cc. ie Time culture exposed to action of disin- Phenol Sample Dilution fectant for minutes coefficient 4 10 121g] 15 bd \e DN | on | Os nN an x a Cn a 780 190 :100 :110 2350} > | Sl) oo eeeraelh ene eiea cas 4.69 X 5.91 °375 1400 1425 1450 3500 2550 :600 1650 5700 2750 Phenol........ H l+t++ 1 [++ | |++ | +1 4 Disinfectant, “ A ” HRHHH HHH RH HARA OR bepbl ob Tl Sra aD Sete he +H+4+4+444+4 11 4444411011 ++4+4+4+444+4 | To calculate the phenol coefficient, the figure representing the degree of dilution of the weakest strength of the disinfectant that kills within 214 minutes is divided by the figure representing the degree of dilution of the weakest strength of the phenol control that kills in the same time. The same is done for the weakest strength that kills in 15 minutes. The mean of the two is the coefficient. The coefficient of any disinfectant may, for practi- cal purposes, be defined as the figure that represents the ratio of the germicidal power of the disinfectant to the germicidal power of the phenol, both having been tested under the same conditions. As many disinfectants and germicides are greatly modified through precipitation, combination or other transformation in the presence of organic matter, in all of those whose coefficient is considerably more than 1, it is wise to perform a second series of tests in which the disinfectant is tested, and the control tests made in the presence of organic matter and the coefficient calculated accordingly. It is usually found that under these conditions the coefficient falls. In a general way, those disinfectants are most valuable for general employment, whose coefficients are highest in the presence of organic matter in the test solutions. The difference in the details of the test given and the new test to be made are as follows: 1. The test dilutions are made 20 per cent. stronger to allow for the dilution made by the addition of the solution of organic matter. Testing Germicidal Value of Liquids 261 2. An organic matter solution is to be prepared. It consists of water containing 10 per cent. of peptone and 5 per cent. of gelatin. The solids are dissolved and the solution sterilized. Titration is not essential. The variations in technic are simple. Of the dilutions made 20 per cent. stronger than for the other experiment, 4 cc. (not 5 cc.) are measured into each seeding tube. The culture after being filtered is added to the organic matter in the proportion of 0.1 cc. to each 1 cc. to be employed in seeding. The addition of 1.1 cc. of the organic solution culture mixture to each seeding tube, gives a total of 5.cc. of diluted disinfectant containing 0.1 cc. of culture and a total of 2 per cent. of peptone and 1 per cent. of gelatin. Except for the slight difference in the dilutions and the seeding with mixed culture and organic fluid the method is the same, and the method of calculating the results is the same. Anderson and McClintic point out that it is manifestly cheaper to purchase a disinfectant for 60 cents a gallon than to purchase one for 30 centsa gallon, providing the former has four times the efficiency of the latter. The true cost of a disinfectant can only be deter- mined by taking into consideration the phenol coefficient and the cost of the disinfectant per gallon. The cost of a disinfectant per 100 units of efficiency as compared with pure phenol is obtained by first dividing the cost per gallon of pure phenol; the efficiency — ratio is of course obtained by dividing the coefficient of the dis- infectant by the coefficient of phenol, but as the coefficient is al- ways 1, the efficiency ratio is represented by the phenol coefficient of the disinfectant. The cost ratio divided by the efficiency ratio (the coefficient of the disinfectant) gives the cost of the disinfectant per unit of efficiency as compared with the cost per unit of efficiency of pure phenol = 1. By multiplying by 100 the relative cost of roo units is obtained thus: Cost of disinfectant Coefficient of disinfec- per gallon. os .., tant. (= Efficiency Cost of phenol per qo Gon ney Coefficient of phenol. ratio.) gallon. (=1.) = cost of the disinfectant per unit of efficiency as compared with phenol = 1, and by multiplying by too the cost of too units is obtained. For instance, the cost of disinfectant “‘Can” is $0.30 per gallon and it hasa coefficient of 2.12; the cost of phenol is $2.67 and it has a coefficient of 1. Then, 0.30 , 2:12 2.67 a oar = 0.052 Therefore, the comparative cost per unit of efficiency of “Can” and phenol respectively, is as 0.052: 1; or, by multiplying by 100, the relative cost per 100 units—s5.2 : 100 is obtained. 262 Value of Antiseptics Gaseous Disinfection.—If the germicide to be studied be a gas, as in the case of sulphurous acid or formaldehyd, a different method must, of course, be adopted. It may be sufficient to place a few test-tube cultures of various bacteria, some with plugs in, some with plugs out, in a closed chamber in which the gas is evolved. The germicidal action is shown by the failure of the cultures to grow upon transplantation to fresh culture-media. This crude method may be supplemented by an examination of the dust of the room. Pledgets of sterile cotton are rubbed upon the floor, washboard, or any dust-collecting surface present, and subsequently dropped into culture media. Failure of growth under such circumstances is very certain evidence of good disinfection. These tests are, however, very severe, for in the cultures there are immense numbers of bacteria in the deeper portions of the bacterial mass upon which the gas ‘has no oppor- tunity to act, and in the dust there are many sporogenous organisms of extreme resisting power. Failure to kill all the germs exposed in such manner is no indication that the vapor cannot destroy all ordinary pathogenic organisms. A more refined method of making the tests consists in saturating strips of blotting-paper, absorbent cotton, various fabrics, etc., with cultures and exposing them, moist or dry, to the action of the ‘gas. Such materials are best made ready in Petri dishes, which are opened immediately before and closed immediately after the ex- periment. If, when transferred to fresh culture media, the ex- posed objects fail to give any growth, the disinfection has been thorough so far as the particular test organism is concerned. If the penetrating power of a gas, such as formaldehyd, is to be tested, it can be done by inclosing the infected paper or fabrics in envelopes, boxes perforated with small holes, tightly closed pasteboard boxes, and by wrapping them in towels, blankets, mattresses, etc. Easier of execution, but rather more severe, is a method in which cover-glasses are employed. A number of them are sterilized, spread with cultures of various bacteria, allowed to dry, and then exposed to the gas as long as required. They are subsequently dropped into culture media to permit the growth of the organisms not destroyed. Animal experiments may also be employed to determine whether or not a germ that has survived exposure to the action of reagents has its pathogenic power destroyed. An excellent example of this is seen in the case of the anthrax bacillus, a virulent form of which will kill rabbits, but after being grown in media containing an in- sufficient amount of a germicide to kill it, will often lose its rabbit- killing power, though still able to fatally infect guinea-pigs, or may lose its virulence for both rabbits and guinea-pigs, aoe still able to kill white mice. CHAPTER XVIII BACTERIO-VACCINES A BACTERIO-VACCINE is a culture of micro-organisms so modified as to be no longer a source of dangerous infection, and so administered as to stimulate the body defenses and thus assist either in pre- venting or overcoming more virulent infection. The small amount of benefit that occurred from the employ- ment of the Oriental method of “inoculating against small-pox”’ was based upon the theory that virus of low virulence, obtained from a sporadic case of small-pox if introduced into the healthy body, must result in a mild attack of the disease, by which the individual would be left immune against the more virulent viruses by which epidemics of the disease are brought about. The observa- tion of Jenner, that the virus of cow-pox would protect against small-pox, led to the supposition that the essential causes of the two diseases had originally been the same, but had so diminished that the one became comparatively harmless for man after many generations of residence in the cow. The success of Pasteur’s preventive inoculation against chicken- cholera depended upon the fact that the bacilli of the disease rapidly lost their disease-producing power when grown artificially in cul- ture-media, though they still retained the power of effecting a change in the fowls which thereafter remained immune. His vac- cination against anthrax was based upon the observation that the spore-forming power and virulence of the anthrax bacillus could be destroyed by cultivation at temperatures beyond a certain point, and that animals infected with bacilli of this modified form subse- quently resisted more virulent infections. His vaccination against rabies was based upon the supposed diminution in virulence that the unknown micro-organisms underwent when exposed to artificial inspissation of the nervous tissue in which they were contained. Such organisms of very low virulence protected against those of higher virulence, and so on. From the periods during which these early observations were made, to the present time, when the term ‘‘bacterio-vaccine’’ is in daily use, studies in immunity have been conducted in so great a variety of ways by such a multitude of investigators, that it be- comes tedious to endeavor to trace the logical and orderly steps that lead to present knowledge, theory and practice. Two names, however, stand out conspicuously in connection with the present topic, because of the importance of their contributions, those of Haffkine and Wright. The former used heated and killed cultures 263 264 Bacterio-vaccines of the cholera spirillum as a prophylactic against cholera, and later with equal success, heated and killed cultures of the plague bacillus as a prophylactic against plague. Wright somewhat modified the method, by using two or even three doses of modified cultures of the typhoid bacillus at intervals of ten or even twenty days, to secure complete prophylaxis against typhoid fever. From prophylactic measures it was but a step to therapeutic measures, and the endeavor to facilitate the cure of disease by the administration of cultures of vaccine. The patient suffering from an infectious disease was already impressed by the toxic, enzymic or other disease-producing substances in his body, and the ad- ministration of cultures of micro-organisms seemed like adding so much fuel to an already widespread conflagration. Indeed, experience and experiment seemed to prove this to be the case, for when by any mischance a patient in the early stages of plague received an injection of the Haffkine plague prophylactic, he straight- way became much injured by the added culture and might even die quickly. But there are certain infections in which conditions are different both with regard to the bacteria and the disease. Thus, a certain micro-organism with limited power of invasion and with difficultly soluble toxic products (endo-toxins), whose injurious effects are local and limited in extent, particularly when their effects are pro- longed and the disturbances chronic, are essentially different from actively invasive agents that quickly over-run the body, or those with considerable soluble products by which it is generally disturbed. In the former group it is not unreasonable to hope that through a method of treatment by which the general body defences are stimu- lated, the local infections may be overcome. Such cases of dis- ease were, therefore, selected, especially by Wright, for investi- gation and treatment. Success of varying degree has followed, and though it is difficult to calculate accurately the benefits obtained in cases that are not susceptible of numerical expression, the almost uniform opinion of clinical and laboratory men is to the effect that certain cases of sluggish infection, with little tendency to recover are benefited and sometimes rapidly cured by treatment with bacterio- vaccines. From these preliminary considerations it should be clear to the reader that the theoretical conditions necessary to success are the following: 1. That the disease should be of subacute or chronic duration. 2, That it should be fairly well localized. 3. That it should be caused by a micro-organism incapable of ready invasion or much soluble toxin formation. 4. That the micro-organism be known and capable of cultivation so that the appropriate-specific vaccine can be made. From these conditions certain lesions resulting from infection by pus cocci, colon bacilli, acne bacilli, typhoid bacilli (post-typhoidal Method of Making the Vaccine 265 suppurations), tubercle bacilli, etc., etc., ought to be appropriate. And, indeed, for them the treatment is highly recommended, and in many cases remarkable success is claimed. Remembering that the reactions of immunity are specific, it is imperative that the essential organism of the lesion be found and cultivated, and cultures of that organism used in the treatment. So important is this that Wright insists that only “autogenous vaccines” —that is, vaccines made of cultures of bacteria cultivated from the very lesion to be treated—be used. This somewhat limits the usefulness of the method for the rank and file of practitioners can scarcely be supposed to have the knowledge, apparatus, or time required for carrying out the technic, nor can all patients afford to patronize the laboratory man. Commercial manufacturers are therefore justified in the preparation and sale of what are known as “stock vaccines” that can be tried in lieu of autogenous vaccines, though in checking up the results note should always be taken of the fact that “autogenous” or ‘“‘stock’”’ vaccines were used. In spite of the general principles laid down above, there are re- ports and observations to show that the theoretical considerations may be faulty and that in some cases the method of treating by vaccination may be beneficial in acute maladies, even when the condition to be treated is toxic. It will be necessary, however, to secure much more evidence with regard to the employment of the method in such cases before it can be recommended as sound practice. Should a case of appropriate kind, when investigated, yield more than one species of micro-organism, of such kind as to make it un- certain which is responsible for the injury done, both should be cultivated, two vaccines made and mixed, and both infections simultaneously antagonized. The Method of Making the Vaccine.—A pure culture of the necessary micro-organisms is obtained from the lesion to be treated, and cultivated in agar-agar. One pint “Blake bottles,” pint or quart white glass whisky flasks, or other good sized bottles with large flat sides, are selected and washed. Into each enough melted agar-agar is filled to spread out over one of the flat surfaces to a thickness of about 1 centimeter, after which a cotton plug is placed in the mouth of the bottle, and it and its contents are sterilized in the autoclave. Upon removal, after sterilization, the bottle is laid on its side so as to distribute the agar-agar and permit it to solidify over the greatest surface, without flowing into the neck and touching the cotton stopper. To the agar-agar culture of the, micro-organism to be used, about to cc. of sterile 0.85 per cent. sodium chloride solution is added, the culture mass being detached with a platinum loop and thoroughly mixed with the fluid. When the agar-agar is firm, each bottle receives by means of a carefully sterilized pipet, about 1 cc. of the culture Suspension which is thoroughly distributed over the entire flat surface of the agar-agar by tilting the bottle this way and that until it has been completely covered. The bottles are then placed in the incubating oven, lying upon the side so as to permit the bacteria to vegetate undisturbed upon the moist flat surface of the medium. After 24 hours, the growth having matured, the bottles are removed and about so cc. of sterile distilled water containing 0.85 per cent. 266 Bacterio-vaccines of sodium chloride and o.5 per cent. of phenol is added to each, for the purpose of washing off the bacteria that have grown. This is done by tilting the bottle and permitting the solution to wash over and over the surface. If the culture does not detach, it may be necessary to remove it with a sterilized glass rod, or by means of a sterile swab made by fastening a small pledget of cotton batting upon the end of a wire. When the growth is detached and thoroughly mixed with the salt solution, it is removed to a sterile receptacle by means of a sterile pipet. What is next done will depend upon the theory upon which the treatment is based. The culture washings contain: (A) sub- stances derived from the culture-medium that certainly cannot be regarded as useful or beneficial and may be harmful; (B) bacterial products, of soluble quality, eliminated from the cells during the life activities, some of which may be useful; (C) the bacteria themselves, which with their contained prod- ucts—endo-toxins, etc.—are commonly regarded as the essential immunizing agents. If one’s theory is that the bacterial cells are essential, and there seems to be a growing tendency toward this view, further treatment is necessary before actually preparing the vaccine for administra- tion; if, however, the collected products of their growth are thought to be of partial or equal value, and are to be preserved, this cannot be done without also retaining the less desirable matters from the culture-medium. Let us suppose that only the bacterial cells are to be employed. The suspension of bacteria, under these circumstances, is transferred to appropriate sterile tubes, plugged, and whirled in a powerful centrifuge until the bacteria are thrown down to the end of the tube, leaving the supernatant fluid fairly clear. The fluid is then removed by decantation or with a pipet, and replaced by an equal volume of o.5 per cent. phenol in 0.85 per cent. sodium chloride solution in distilled water. In this the sediment is thoroughly mixed by stirring. As the bacteria are often in masses, groups or chains, it is now necessary to separate them. This is best done by adding a few small glass beads to the contents of the tubes, changing the cotton stopper for a sterile rubber cork, and shaking either in a shaking machine or by hand, until it can be supposed that the micro-organisms are all separated. This is easily accomplished by the aid of the shaking machine but is tedious to effect by hand. The tube is then returned to the centrifuge and again whirled until the bacteria are again sedimented, after which the fluid is again removed and again replaced and the bacteria again dis- tributed. A few turns in the centrifuge now throw down particles of culture- oe and contained flakes of the culture and leave a uniformly clouded fluid above. If it be desired to conserve all of the bacterial products, the - washings from the culture bottles are immediately transferred to the appropriate tube, shaken with the glass beads, given a few turns in the centrifuge to throw out flakes of culture and culture-media, and we again arrive at the point of having a uniformly cloudy fluid with which to continue the preparation of the vaccine. If the vaccine is to be of scientific value, it should be made in such manner that its composition represents what is desired— bacterial cells only, or bacterial cells with their collected products— and some means should be provided by which a reasonably accurate Method of Making the Vaccine 267 determination of its value can be estimated. This is done by cal- culating the number of contained bacteria per cubic centimeter of the fluid, and then either diluting or concentrating by means of centrifugation until an appropriate result is reached. As the con- centration by centrifugation is more difficult than dilution it is best to take care at the very beginning of the process not to add too much fluid to the culture bottles for the purpose of washing off the culture. Whatever dilution of the final product may be necessary is made by the use of the o § per cent. phenol solution. The most ready method of calculating the number of bacteria in the fluid is that of A. E. Wright which will be found in the chapter upon the ‘“‘Calculation of the Opsonic Index.” After having determined the number of bacterial cells per cubic centimeter of fluid, dilution with the phenol solution is made until single doses are contained in quantities easily injected into the patient. As the doses vary with the particular organism to be injected, the operator must calculate from the number of bacteria in the fluid, how much solution must be added to constitute a dose. Several doses of each desired size should be prepared. Quantities of the dilutions containing single doses or a number of doses as may be preferred are now transferred, by means of a sterile pipet, into -previously sterilized, appropriate sized “ampules” or glass bulbs made for the purpose, and the necks sealed in a flame. The bacteria are, however, still alive, and though many of them no doubt undergo autolysis in the phenol salt solution, it is nec- essary to make certain that none remains alive to infect the patient. The destruction of the vitality of the micro-organisms which is the final step in the process of vaccine preparation is effected by ex- posure to the lowest temperature that is known to be positively destructive. As spore-producing micro-organisms may maintain this vitality at temperatures beyond 100°C., at which the micro- organismal substance as well as their products are altered by coagula- tion and other destructive transformation, they are inappropriate organisms to employ for purposes of vaccines, unless, through some such ingenious means as was devised by Pasteur for the anthrax bacillus, the production of spores can be prevented. With very few exceptions non-sporogenous bacteria are destroyed by exposure for 60 minutes to a temperature of 60°C. Should any escape destruction, they are probably so injured as to be incapable of further injurious effect upon the human body. The destruction of the bacteria is, then, effected by heat: The ampules of vaccine are placed in some sufficiently commodious receptacle filled with water, the heat being supplied by a flame below, and the temperature determined by a thermometer whose bulb is at the center of the bath. When small quantities of the vaccine are to be made for special cases, a large beaker supported upon an asbestos plate upon a chemical tripod and heated by a Bunsen’s flame answers very well. The burner is allowed to heat the bath until the proper temperature is reached, when it is removed. As soon as the tem- _ 268 Bacterio-vaccines perature begins to fall, it is replaced. Thus by alternately heating and re- moving the source of heat for 60 minutes, the destruction is affected. If there are many of the small ampules, containing different doses or different cultures, each separate lot may be done up in a piece of gauze, and labelled. J. H. Small uses orange-colored “string tags” for this purpose, writing upon them with either pen or pencil, and fastening them to the gauze packages. In the water of the water-bath, the writing does not wash off of the tag, but the color comes out and gives the water an orange tinge. This is found to be of the greatest use, for as one or more of the factory-made ampules commonly cracks in the water-bath, the color penetrates the contained fluid. Upon removal from the water-bath, to glance at each ampule will inform the observer whether it is cracked or not, through the change in the color of the contents. The tags, therefore, subserve a double purpose. After heating, one of the ampules can be opened and a drop of the contents transferred toa tube of culture to make sure that the bacteria are no longer alive. The vaccine is now ready for use, but in what dose shall it be ad- ministered? There is no other information upon this subject than that which is derived from the experience that certain doses seem to accomplish good without producing ill effects. Thus experience with doses at first selected arbitrarily has led to a fairly accurate standard dosage. As the beginning dose for most vaccines 50-250 millions may be recommended, to be increased to 1000 millions or more, the injections being given every 4-6 days or as controlled by the opsonic index. The benefit of the vaccine is commonly supposed to depend upon the stimulation of the phagocytic cells of the body. This is very probably the case, but when the bacterial bodies are administered, their dissolution results in the liberation of the contained endo- toxin, and when the entire culture is given, endo-toxins and perhaps exo-toxins and other substances are also given so that the increased phagocytosis is not likely to be the only effect of the treatment. A. E. Wright who is a firm believer in the stimulating influence upon the cells seeks to control the dosage and estimate the value of the injections by such study of phagocytic activity, as is shown in the next chapter. If after an injection of vaccine, the phagocytic activity of the leukocytes is diminished (negative phase) harm is supposed to have been done and the inference is drawn that the dose was too large; if, on the other hand, the phagocytic activity is increased for the respective organism, good is supposed to have been done, and at the next injection the same or a larger dose may be given. Besredka and Metschnikoff* have modified the vaccines by what * Ann. d.1’Inst. Pasteur, 1913, XXVII, 597. Method of Making the Vaccine 209 - is called sensitization. This they accomplish by treating the bacteria to be used with an antiserum, prepared by injecting animals with such organisms as form the vaccine. In this manner the specific bacteriolytic amboceptors are supposed to anchor themselves to the bacterial cells, and so pave the way for immediate destructive treatment in the body. To achieve such sensitization, some of the appropriate serum is added to the bacterial suspension which need not be subsequently killed, as the sensitized bacteria meet with prompt destruction through the normal complement of the body juices. However, if the bacteria are first killed by heat and then sensitized, a similar result may be brought about, and one is relieved of all anxiety as to the possibility of infection accidentally resulting from the injections. CHAPTER XIx THE PHAGOCYTIC POWER OF THE BLOOD AND THE OPSONIC INDEX From the time that Metschnikoff connected the phenomena of phagocytosis with those of immunity, there was no recognized technic for the observation and comparison of the bacteria-con- suming and bacteria-destroying power of the cells until 1902, when Leishman* suggested the following simple method: A thin suspension of bacteria in normal salt solution is mixed with an equal volume of blood by drawing in and out of a capillary tube, then dropped upon a clean slide, covered carefully, placed ina moist chamber, and incubated at 37°C. for a half hour. The cover is then slipped off carefully, as in making blood-spreads, dried, stained, and the number of bacteria in each of 20 leukocytes counted and averaged. For comparison with the normal, the patient’s blood and normal blood are simultaneously examined. This was greatly improved by Wright and Douglas,f the accuracy of whose methods enabled them to discover the ‘‘opsonins,” work out the “opsonic index,” and formulate methods by which sufficiently accurate observations could be made for controlling the specific treatment of infectious diseases. The opsonic theory teaches that the leukocytes are disinclined to take up bacteria unless they are prepared for consumption or phagocytosis by contact with certain substances in the serum that in some manner modify them. This modifying substance is the opsonin (opsono, I cater to, I prepare for). To make a test of the opsonic value of the blood it is necessary to prepare the following: -A uniform suspension of bacteria. A suspension of washed leukocytes in physiological salt solution. | The serum to be tested. A normal serum for comparison. The Bacterial Suspension.—This is prepared like the similar suspensions used for determining agglutination, but with greater care, since the bacteria taken up by the corpuscles are to be counted, and any variation in the number of bacteria with which they come into contact may modify the count. It is also necessary to avoid © all clumps of bacteria for the same reason. The culture is best grown upon agar-agar for twelve to twenty- four hours, the bacteria in young cultures being more easy to sepa- * “British Medical Journal,” Jan. 11, 1902, I, p: 73- t“Proc. Royal Soc. of London,” 1904, XXXII, Pp. 357. 270 The Bacterial Suspension 271 rate than those in old cultures. Such a culture may be taken up in a platinum loop, transferred to a test-tube containing some 0.85 per cent. sodium chloride solution, and gently rubbed upon the glass just above the fluid, allowing the moistened and mixed bacterial mass to enter the fluid little by little. - If the culture be older or of a nature that will not separate in vereeeconemmpnem cn a cote wo cee Fig. 92.—Grinding bacteria (Miller). this manner (tubercle bacillus), it may be necessary to rub it between two glass plates, or in a small agate mortar with a drop or two of salt solution, other drops being added one at a time, until a homo- geneous suspension is secured. Such clumps of bacteria as may remain in the suspension are easily removed by whirling for a few seconds in a centrifuge. The next step is the standardization of the suspension. Wright recommends for this purpose and for the standardization of the bacterio- vaccines that the number of bac- teria shall actually be counted. This he does by mixing one part of the bacterial suspension with an equal volume of normal blood and three volumes of physiological salt solu- tion. After thorough mixing a smear : is made upon a slide, the smear _./'iS-_93-—Diaphragm of eye- A ; piece showing hairs in position stained, and the number of bacteria (filler), and corpuscles in successive fields of the microscope counted until at least 200 red blood-corpuscles have been enumerated. As the number of red corpuscles per cubic milli- meter of blood is 5,000,000, the number of bacteria per cubic centi- meter can be determined from the results of the counting by a simple arithmetical process. To facilitate the counting the eye- piece of the microscope is prepared by the introduction of a dia- phragm. The prepared suspension must usually be greatly diluted before using, but the reduction of bacteria is, of course, easily cal- 272 The Phagocytic Power of the Blood culated. It requires experience to determine the appropriate number of bacteria to be employed. When this is once determined, future manipulations are made easy, because one first makes his suspension, Fig. 94.—Photomicrograph showing cross-hairs, bacteria, and red blood- corpuscles (Miller). then enumerates the bacteria, and having determined their number, immediately arrives at the appropriate concentration by dilution. Fig. 95.—Collecting blood for corpuscles (Miller). The Washed Leukocytes.—It is not necessary to have the leuko- cytes free from admixture with the erythrocytes, but it is necessary to have large numbers of them. They are collected by citrating the blood so as to prevent coagulation, and then separating the citrated plasma from the corpuscles by centrifugalization. The Washed Leukocytes 273 The hands of the patient are washed, and a piece of elastic rubber tubing or some other convenient fillet wound about the thumb or a finger to produce venous congestion. With a convenient lancet (Wright uses a pricker made by drawing a bit of glass tubing or a glass rod to a fine point in the flame) a prick is made about a quarter inch from the root of the nail. From this the blood is permitted to flow into small test-tubes pre- viously filled about three-fourths with 1.5 per cent. sodium citrate solution. The blood and citrate solution are mixed, and the tubes placed in a centrifuge, balanced, and centrifugalized until the corpuscles are collected at the bottom of the tube. The citrated plasma is now with- drawn and replaced with 0.85 per cent. sodium chloride solution, through which the corpuscles are distributed by shaking. The tubes are now again centrifugalized until the corpuscles are Fig. 96.—Tube of collected, when the saline is removed carefully, ae . baal erat ae the last drop from the back of the meniscus. after centrifugaliz- In the corpuscular mass that remains the leuko- ing (Miller). cytes form a thin creamy layer on the top. The serum to be tested and the normal serum for comparison are secured in the same manner, the former from the patient, the latter from the operator. As it is advisable to wound the patient Fig. 97.—Removing last drops of saline solution (Miller). but once, the tube for obtaining the serum should be filled at the same time that the citrated blood is taken. The blood to furnish the serum is taken in a small bent tube shown in the illustration. 18 274 The Phagocytic Power of the Blood The blood from the puncture is allowed to flow into the bent end of the tube, into which it enters by capillary attraction and_ from which it descends to the body of the tube ee gravity. At least 1 cc. of the blood is required to furnish the serum. The ends of the tube are closed in the flame and the tube stood in the thermostat for fifteen to thirty minutes. Coagulation takes place almost immediately, and the serum usually separates quickly. Ifit does not do so, Wright recommends hanging the curved arm of the tube over the cen- Fig. 98.—Special blood pipetet (Miller). trifuge tube and whirling it for a mo- ment or two, when the clot is driven into the straight arm of the tube and the clear serum appears above. The tube is then cut with a file so that the serum can be removed when needed. Mixing the factors concerned in the test is a matter that requires practice and a steady hand. It is best done, as rec- Fig. 99 .—Opsonizing pipette containing blood-corpuscles, bacterial emulsion, and blood- serum (Miller). ommended by Wright, in a capillary tube controlled by a rubber bulb. The object of the experimenter is to take up into- this pi- pette equal quantities of the creamy layer of blood-corpuscles, of The Washed Leukocytes 275 the blood-serum, and of the bacterial suspension. Wright first makes a mark with a wax pencil about 1 centimeter from the end of the capillary tube. He first draws up the leukocytic layer of blood-corpuscles to this mark, then removing the tube, permits the column to ascend a short distance. Next he draws up the bac- terial suspension to the same point, withdraws the tube, and per- mits the column to ascend; then draws up the serum to be taken to the same point; thus in the same capillary tube he has three equal volumes of three different fluids, separated by bubbles of air. It is next necessary to mix these, which is done by repeat- edly expelling them upon a clean glass slide, and redrawing them into the tube. After thus being thoroughly mixed, the fluid is once more permitted to enter the capillary tube and come to rest Fig. 100.—Mixing liquids by repeatedly expelling on to slide and redrawing into pipette (Miller). there. The end is now sealed in a flame, the rubber bulb removed and the tube placed in a thermostat, or in case much work of the kind is being done, to an opsonizing incubator in which the tempera- ture is not modified by opening and closing the doors. The tube remains in the incubating apparatus at 37°C. for fifteen minutes (some use twenty, some thirty, minutes as their standard), is then removed, whirled about its long axis between the thumbs and fingers a few times to mix the contents from which the corpuscles have sedimented, its end is broken off, and a good-sized drop is allowed to escape upon a perfectly clean glass slide and spread over its surface. The spreading is a matter of some importance, as an even dis- tribution of the leukocytes is desirable. The capillary tube from which the drop has escaped will form a good spreader if laid flat upon the glass and drawn along, but the edge of another slide is better, and in distributing the fluid, it is better to push than to pull it with the end of the slide, rather than its side. 276. The Phagocytic Power of the Blood Miller* says that “‘a good smear should be uniform in consistency and most of the leukocytes should be found along the edges and at the end. For convenience in counting, it is well to have the smear terminate abruptly and not be drawn out into threads or irregular forms.” Fig. 101.—A small incubator of special design for opsonic work (Miller). This mixing, incubating, and spreading is done twice—once with the serum of the patient, and once with the normal serum of the operator. The technic is the same each time. In order. that the enumeration of the bacteria taken up by the leukocytes can be accomplished, it is next neces- sary to stain the blood smears. This can be done by any method that will demonstrate both the bacteria and the cells. For Fig. 102.—The smear (Miller). staphylococci and similar organ- isms, Leishman’s stain, Jenner’s stain, or J. H. Wright’s stains are appropriate. Marino’s stain, recommended by Levaditi,t gives beautiful results. For the tubercle bacillus the spreads may be stained with carbol-fuchsin * “Therapeutic Gazette,” March 15, 1907. { “Ann. de I’Inst. Pasteur,” 1904, XVIII, p. 761. The Washed Leukocytes 277 and counterstained with methylene-blue, or perhaps better with gentian violet and counterstained with Bismarck brown or vesuvin. The final step in the process is the enumeration of the bacteria in the corpuscles by averaging the number taken up by the cells. . Only typical polymorphonuclear cells should be selected for staph- ylococcic cases, and separate averages made for polymorphonu- clear and mononuclear cells in tubercle bacillus cases. It is best to follow certain routine methods of enumeration. Some who content themselves with a count of the number of bacteria in 20 cells, secure less accurate results than those who count 50 cells. It is usually best to count one-third of the cells in the central portion of the spread, one-third at the edge, and one-third at the end. In each portion no other selection of cells should be made than the elimination of other than polymorphonuclear cells and the elimina- tion of all crushed or injured cells; the others should be taken one after the other, as they are brought into the field with the mechanical stage. After the bacteria included in each of the accepted number of cells selected as the standard has been enumerated, an average is struck. The “opsonic index” is determined by dividing the average number in the patient’s serum preparation by the average in the. normal serum preparation. Leishman’s* studies of the phagocytic power of the blood show that in cases of furunculosis, etc., with each recrudescence of boils, there is a marked diminution of the phagocytic power of the blood, and with each improvement, a marked increase. McFarland and |’Englet found by an examination of the blood of 24 supposedly healthy students and laboratory workers that it was possible to prejudge, by the phagocytic activity of the cells, the past occurrence of suppuration and present liability to it. Wright and Douglas use the opsonic index as a guide to the specific therapy of the infectious diseases. If the opsonic index is low they believe bacterio-vaccination is indicated. In its admin- istration, however, care must be taken to administer a counted number of bacteria, and to make frequent opsonic estimations to determine the good or ill effects accomplished. Thus, the ad- ministration is always followed by a temporary diminution (negative phase) of the opsonic index, soon followed, if the dose be not too large, by a marked increase (positive phase). It is supposed, upon theoretic grounds, and proved by practical experience, that the increase of phagocytic activity brings about improvement. The care of the operator should be to avoid giving so large a dose of the vaccine that the negative phase will be so long continued that harm instead of good may be achieved. Although Wright is said to cling to the study of the opsonic * “Lancet,” 1902, I, p. 73- Tt “Medicine,” April, 1906. 278 The Phagocytic Power of the Blood index as a guide to bacterio-vaccination and the resulting degree of immunity, the greater number of workers have abandoned it upon grounds which the writer long ago expressed—‘that the estimation of the value of bacterio-vaccination by means of the opsonic index was a very complicated way of finding out very little.” CHAPTER XX THE WASSERMANN REACTION FOR THE DIAGNOSIS OF SYPHILIS Tus now popular and fairly reliable method for assisting in the diagnosis of atypical syphilitic infections was devised by Wasser- mann, Neisser, and Bruck.* It is a method of making the diagnosis of syphilis by demonstrating in the blood (cerebrospinal fluid, milk, or urine) of the patient a complement-fixing substance (antibody?) not present in normal blood. The test is twofold: (1) A combination of syphilitic antigen, complement, and suspected serum. (2) A subsequent addition to the mixture of blood-corpuscles and hemolytic amboceptor. If the suspected serum contain the syphilitic antibody the antigen and complement unite with it, and the complement being thus “fixed,” no hemolysis can take place upon the subsequent addition of the blood-corpuscles and hemolytic serum. If, on the other hand, the suspected serum contain no antibody, the complement cannot be fixed, and is, therefore, free to act upon the subsequently added blood-corpuscles in the presence of the hemolytic serum, and hemo- lysis results. It is thus seen that the first test is made for the purpose of fixing the complement, and the second for the purpose of finding out whether it has been fixed or not. It is quite clear that such a test is very delicate, and can only be successful when executed with great precision and with reagents or factors titrated, so that their exact value may be known. CONSIDERATION OF THE REAGENTS EMPLOYED I. For the first, or fixation, test it is necessary to bring together— Syphilitic antigen. Serum to be tested. Complement. (t) The Syphilitic Antigen.—It was supposed by Wassermann, Neisser, and Bruck, who first devised the test, that the syphilitic antigen must contain the essential micro-organisms of syphilis. No method for the cultivation of Treponema pallidum having at that time been devised, cultures of the specific micro-organism could not be employed. Histologists had, however, shown that greater num- bers of the organisms were to be found in the livers of the congen- itally syphilitic stillborn infants than anywhere else. With the * “Teutsch. Med. Wochenschr.,” 1906, No. 10. 279 280 Wassermann Reaction for Diagnosis of Syphilis purpose, therefore, of securing the greatest possible number of micro- organisms for the antigenic function, such livers were used. The tissue, having been cut into small fragments, was spread out in Petri or other appropriate dishes and dried, and the fragments rubbed to a fine powder with a mortar and pestle. Such a powder can be kept indefinitely in an exsiccator over calcium chlorid if placed where it is cool and dark. When the powder is to be used, 0.5 gm. is extracted either at room temperature or in the ice-box with 25 cc. of 95 per cent. alcohol for twenty-four hours, filtered through paper, and the filtrate used in quantities later to be mentioned. Instead of drying the liver tissue, pulverizing, and then extracting it, many investigators now prefer to cut it up, rub it into a uniform paste with a mortar and pestle, and add 5 volumes of 95 per cent. or absolute alcohol, with which the paste is thoroughly macerated and shaken many times or in a shaking machine. The alcohol may then be filtered off, or may be permitted to remain upon the sedi- mented liver tissue remnants, and the clear supernatant fluid pipeted off and diluted, at the time of employment, with the isotonic sodium chlorid solution. When this alcoholic extract is added to the salt solution a turbidity occurs, but this must not be filtered out, as it consists of the lipoids or other substances in the extract that are essential to the test, and the quantity of the cloudy fluid in the | final mixtures is so small as not in any way to interfere with the results. The small amount of alcohol in the diluted extract is negligible and has no influence upon the reagents used for the test. The mention of the lipoids now brings us to the point where it seems advisable to state that one of the most interesting facts about the Wassermann reaction is that its theoretic basis was founded upon the erroneous assumption that the essential antigenic substance consisted of the whole or fragmented treponemata in the liver ex- tract. The method scarcely began to meet with practical applica- tion, however, before it was discovered that the active antigenic substance was soluble in alcohol, was present in other than syphilitic livers, and could be extracted not only from human tissues, but also from dogs’ livers and from guinea-pigs’ hearts. Porges and Meier, indeed, found that lecithin could play the réle of syphilitic antigen, and Leviditi and Yamanouchi place sodium glycocholate, sodium taurocholate, protogon, and cholin among those bodies capable of acting as syphilitic antigens, and Noguchi goes so far from the orig- inal that he regularly employs an extract of the normal guinea-pig’s heart as the antigen to be employed in his modification of the test. These discoveries now make it clear that the complement fixation that takes place in syphilis is not identical with that of the Bordet- Gengou reaction, in which it had its beginning. Happily, however, the error does not destroy the usefulness of the method for diagnosis. The probable nature of the reaction will be described below. For The Serum to be Tested 281 the present we must be content to follow the beaten path, and for this purpose will use the congenitally syphilitic liver extract as the antigen, preparing it as described above. (2) The Serum to be Tested.—Wassermann, Neisser, and Bruck i j f ; : | i | Me es: a gE Fig. 103.—The Kei- Fig. 104.—Parts of the Keidel tube. £ is the del tube for collecting vacuum bulb which is attached to the needle by a blood. (Manufac- piece of rubber tubing (D); the gl : glass tube (B) turéd by the Steele covers the needle and the whole is sterilized. Glass Co., of Phila- (Kolmer.) delphia.) at first employed the cerebrospinal fluid, but now the blood-serum of the suspected patient is almost universally used. As is usual with antibodies, the substances engaging in the complement-fixation test are widely distributed throughout the-body, and reach the 282 Wassermann Reaction for Diagnosis of Syphilis cerebrospinal fluid, the milk, the urine, and the other body fluids through the blood, in which it exists in greatest concentration. The blood is, moreover, readily obtainable for study, which is another reason it is at present used for making the test under all ordinary circumstances. Noguchi, who works with very small quantities of the reagents, secures the blood by obstructing the venous circulation of the thumb or of a finger by means of a rubber band (see directions for obtaining the blood for making the opsonic index) but the greater number prefer to obtain it by introducing a large hypodermic needle into one of the veins near the bend of the elbow. The arm above the elbow is compressed by a fillet, as though for the purpose of performing phlebotomy, and a conspicuous vein selected for the purpose. The skin is first carefully washed, then treated with tincture of iodin. If the patient is nervous, a momentary spraying with chlorid of ethyl will make the operation entirely painless. Some prefer to use the iodin without the preliminary washing, be- lieving that soap makes it difficult for the iodin to effect satisfactory disinfection of the skin. The sterilized needle is thrust into the vein, care being taken that the vein is not too compressed and the point of the needle thrust entirely through instead of into it. From 15 to 25 cc. of blood may be withdrawn in a Keidel tube, or into a large syringe or may be allowed to flow into a sterile test-tube. The blood, however secured, is permitted to coagulate and the clear serum re-- moved by a pipette, or the clotted blood is placed in a centrifuge tube and whirled, so that clear serum is secured in a few minutes. As normal human blood-serum, when fresh, contains a certain amount of complement which would interfere with the success of the experiment, the serum is next placed in a test-tube and kept in a water-bath between 55° to 58°C. for a half-hour. This degree of heat destroys the complement and leaves the complement-fixing substance uninjured. The serum is now ready for use. (3) The Complement.—The complement generally employed is contained in the blood of a healthy adult guinea-pig. To obtain it a piece of cotton moistened with ether or chloroform is held to the guinea-pig’s nose until it becomes unconscious, when the head is forcibly extended and a longitudinal incision made through the skin of the neck. The skin is then drawn back between the finger, on the one side, and the thumb, on the other side, of the operator’s left hand, while, with a sharp knife held in the right hand, he cuts through all the tissues of the neck down to the spinal column and thus opens both carotid arteries. The spurting blood is caught in a sterile Petri dish and the animal permitted to bleed to death. The blood soon coagulates when undisturbed, and in a short time clear serum exudes from the clot. As, however, the complement seems to be at least in part derived from the corpuscles, the serum should not be removed as soon as it forms, but permitted to remain . in contact with the clot for three hours. If it is desired to save The Blood-corpuscles 283 time, the clot, as soon as formed, may be cut into strips and placed in the tubes of a centrifuge and whirled for a half-hour. This se- cures a greater quantity of the serum and at the same time gives it its full value, probably by injuring the leukocytes. Such serum containing the complement is useful for twenty-four hours. Longer it should not be kept or used, as it begins to deterio- rate almost at once, and the deterioration increases in rapidity in proportion to the length of time it is kept. The quantity of thecom- plement in the serum of the guinea-pig is fairly constant, when the animal is regularly fed, and furnishes a fairly uniform reagent that requires no titration. II. For the second, or hemolytic, test two additional reagents are required: Blood-corpuscles to be dissolved. Hemolytic amboceptors by which complement may be united to them. (4) The Blood-corpuscles.—It makes no difference what kind of blood-corpuscles are employed. Ehrlich and Morgenroth, in their pioneer experiments into the mechanism of hemolysis, used goat ‘corpuscles. Bordet used rabbit corpuscles; Wassermann, Neisser, and Bruck, sheep corpuscles; Detre, horse corpuscles; Noguchi, human corpuscles. As those who do many tests require a considerable quantity of blood, it seems wisest to make use of some kind that is readily ob- tainable in any quantity, hence most investigators now follow Wassermann and his collaborators and use sheep blood, which is easily obtained at a slaughter-house or from sheep kept for the purpose. The flowing blood is caught in some open receptacle, stirred until it is defibrinated (it must not be permitted to coagulate), and then taken to the laboratory. The corpuscles must next be washed with care, so as to free them from all traces of amboceptors and complement belonging to the serum in which they are contained. For this purpose a centrifuge is indispensable. The tubes of the apparatus are filled with the defibrinated blood and then whirled for fifteen minutes until the corpuscles form a compact mass below a fairly clear serum. The serum is then cautiously removed and replaced by 0.85 per cent. sodium chlorid solution, the top of each tube closed by the thumb, and vigorously shaken so as to distribute the corpuscles throughout the newly added fluid. The tubes are next returned to the centrifuge and again whirled until the corpuscles are sedimented, when the fluid resulting from this first washing is removed and replaced by fresh salt solution, in which the corpuscles are again thoroughly shaken up. They are now again whirled until again sedimented, when the second washing is removed, leaving the corpuscular mass undisturbed. Some prefer to give the corpuscles a third washing, . iy 284 Wassermann Reaction for Diagnosis of Syphilis _ but it does not seem to be necessary. Of the remaining corpuscular mass, 5 cc. are added to 95 cc. of salt solution to make a 5 per cent. volume suspension, in which form they are ready for use. As the corpuscles of healthy sheep thus treated form a practically invariable unit, no titration or other preliminary is needed before they are used. They must, however, be used within seventy-two hours to secure satisfactory results, as they tend to soften when kept and so to lose their standard value. If kept longer than twenty-four hours they should be washed before using. (5s) The Hemolytic Amboceptor.—As the validity of the test de- pends upon the ability or inability of the complement to dissolve the corpuscles, and as this can only be achieved when appropriate amboceptors are added, the hemolytic amboceptors must correspond to the kind of blood-corpuscles employed in the experiment. As has been shown, the greater number of investigators now employ sheep corpuscles, hence must use such corpuscles as the antigen through whose stimulation the amboceptors or antibodies are excited. The usual method of obtaining the amboceptor is in the blood- serum of an experimentally manipulated rabbit. A large healthy rabbit is employed for the purpose, and is given a series of intra- peritoneal injections of the 5 per cent. suspension of washed and “ sedimented sheep corpuscles prepared as above described. These injections are usually given about five days apart, and the dosage is usually 5, 10, 15, 20 and 25 cc. respectively. A serum of higher amboceptor content may be prepared by using a greater number of corpuscles, and for this purpose the solid cor- puscular mass thrown down by centrifugalization after the second washing is employed. Of this, 2, 4, 8, and 12 cc., diluted with just enough salt solution to make it pass readily through the hypodermic needle, may be regarded as appropriate doses, thé intervals being the same, viz., five days. The amboceptor content of the rabbit serum seems to be greatest about the ninth or tenth day after the last injection. Much care must be taken to see that the injected fluid is sterile and the operations performed under aseptic precau- tions, as the rabbits are easily infected and not infrequently die. They also seem prone to die after the last injection, so that it is best: to have more than one rabbit under treatment at a time. When the appropriate time has arrived, the rabbit is bled from the carotid artery, according to the directions given in the chapter upon Experiments upon Animals. The blood thus obtained is permitted to coagulate, and the serum, which should be clear, removed with a pipette. More serum may be obtained from the clot by cutting it into strips, placing these in a centrifuge tube, and whirling them for fifteen minutes. Having thus described the preparation of the reagents to be em- ployed in making the Wassermann test, the next step, that of titrat- ing them, becomes essential. One of the first questions that pre- The Hemolytic Amboceptor 285 sents itself is how successful titration of reagents that may all be more or less variable can be effected. To achieve this it is necessary to begin with those that can be assumed to be least variable and work up to those that are most so. (1) The Sheep Corpuscles.—As these come from a healthy animal, are always treated in precisely the same manner and used under standard conditions of freshness, they can be looked upon as an in- variable factor. 1 cc. of the 5 per cent. suspension forms a good working quantity and constitutes the unit. (2) The Normal Guinea-pig Serum Containing the Complement.— As this also comes from a normal animal, is always treated in pre- cisely the same manner, and is also used under standard conditions of freshness, etc., it may also be looked upon as a factor subject to very slight variation. Of this serum, o.1 cc. (1 cc. of a 1:10 dilution, made with physiological salt solution) forms the unit, or working quantity. These two reagents, therefore, may be regarded as the standards of measurement through which the titer of a third is made possible. (3) The hemolytic serum from the rabbit treated with the sheep corpuscles. This is subject to very great variation, according to the treat- ment of the rabbit, and apparently, also, according to the ability of the individual rabbit to respond to the treatment by the forma- tion of hemolytic amboceptors. It is, therefore, imperative to make a careful titration of it. To do this we proceed as follows, the quantities recommended being such as experience has proved most satisfactory: Into each of a series of common test-tubes or culture-tubes 1 cc. of the 5 per cent. suspension of sheep corpuscles and 1 cc. of the 1:10 dilution of the normal guinea-pig serum (complement) are measured with graduated pipettes, and then to each of these tubes the rabbit serum (amboceptor), diluted with physiological salt solu- tion so as to make the correct measurement of the minute quantities necessarily employed a matter of ease and convenience, is added in diminishing quantities for the purpose of determining the least quantity that will bring about complete hemolysis in two hours at the temperature of 37°C. The occurrence of the hemolysis is shown by a very striking change in the appearance of the fluids. The mixture is at first opaque and pale red, but after hemolysis, or solu- tion of the red corpuscles, becomes a beautiful transparent Burgundy wine red. ' The actual ‘“‘set-up” or working scheme for determining the unit or least hemolyzing addition of the amboceptor serum may be represented as follows, the tubes being placed in a thermostat and observed every fifteen minutes: 286 Wassermann Reaction for Diagnosis of Syphilis Five per cent. suspen- Normal guinea-pig Hemolytic rabbit Result (final readings sion of corpuscles. serum. serum. after two hours). I cc. o.r cc. 0.01 ce. Complete hemolysis. I “ ol ce 0.005 «“ “cc “ m8 o.r “ 0.002 “ Ke « rf Or o.oor “ ff 7 z. o.r 0.0005 “‘ ee i ry ot 7 oun. 0.0003 “ Partial s ar tt our 0.0002 “ No . tS our “* o.ooo1 “ “ tk After the reagents are added, enough 0.85 per cent. salt solution is added to each tube to bring the total bulk of the mixture up to 5 ce. From the results shown in the tubes it is evident that the hemolyz- ing quantity of the rabbit serum lies between 0.0005 and 0.0003 cc., and is probably 0.0004 cc. To be as accurate as possible, a second series of experiments should be made with 0.0005, 0.00045, and 0.0004 cc., so that the proportion of amboceptor serum neces- sary to effect hemolysis be known within small limits. This least quantity, that will certainly cause hemolysis in two hours at 37° C., is known as the unit. The combination of the unit of corpuscular suspension (1 cc.), the unit of complement (0.1 cc.), and the unit of hemolytic amboceptor is known as the hemolytic system. As soon as this unit is known accurately, we are in position to reverse the conditions of the test. Thus, if we should desire to know how much variation there may be in the complements from different animals under different conditions of age, feeding, health, etc., we can now do so by determining whether, when 1 cc. of the corpuscles, i unit of amboceptor and varying quantities of complementary serums are combined, any variation in the final results will obtain. Or, if we desire to know to what extent the sheep corpuscles may change through prolonged keeping or other manipulation, it can be done by maintaining the unit of amboceptor and the unit of complement and adding larger or smaller quantities of the corpuscles. The conditions under which the unit of amboceptor is titrated constitute the standard conditions of the Wassermann reaction. In it are always employed 1 unit of sheep corpuscle suspension, 1 unit of complement, and 1 unit of amboceptor. Here, however, a slight difference of opinion is reached, it being argued by many experi- menters that such exact proportions may make the test uncertain, because, should there be the slightest tendency on the part of the remaining reagents to inhibit hemolysis by means other than comple- ment fixation, it would result in positive readings where the final result should be negative. To overcome this possibility, they dif- ferentiate between the amboceptor uit and the amboceptor dose, the latter being commonly twice and sometimes four times the unit. : Now, though the amboceptor unit is determined by the method given, it by no means follows that those proportions are the only The Hemolytic Amboceptor 287 ones that will lead to hemolysis. By increasing the amboceptor we can diminish the complement with the same end-result, a matter that has been graphically shown by Noguchi,* who says “that hemolysis is merely the relative expression of the combined action of amboceptor and complement, and is not the absolute indication of the amount of the hemolytic components present in the fluid. The same amount of hemolysis can be produced by 1 unit of com- plement and by 1 unit of amboceptor as by 20 units of amboceptor and o.1 unit of complement or any other appropriate combination of these two components.” As in the performance of the test we work always with 1 unit of complement, we do not want to unduly disturb its proper propor- tional action by any excessive addition of amboceptor, but simply to increase the latter sufficiently to provide for the accidental presence, in the serum to be tested, of substances affecting hemolysis. Fortu- nately, means are provided for controlling this action, as will be shown below. The amboceptor serum keeps indefinitely. When it is to be kept and used from time to time, many experimenters prefer to seal it ina number of small tubes, one of which is opened when the serum is needed, the remainder being kept in an ice-box. Others prefer a stoppered bottle that can be opened and a measured quan- tity removed as needed. The most convenient way of treating it seems to be Noguchi’s method of drying it upon filter-paper. For this purpose a good quality of filter-paper is cut into strips to to 20 cm. in length and 6 to 8 cm. in breadth, and saturated with the serum, which is permitted to dry. It is well to make a pre- liminary titration of the serum, for if it. be very active it may have to be diluted in order that the piece of dry paper containing the dose be of a size convenient to handle; 1 drop of serum usually covers about 14 sq. cm., which is about as small a piece as can be measured, cut, and used with satisfaction if sufficient allowances are to be made for variations in distribution and other conditions that may modify the accuracy of the method. If the unit-strength of a serum be, say, 0.00005 and the dose 0.0001, water should be added to the extent of about 9 volumes and the mixture gently agitated, so that diffusion may occur without frothing. The diluted serum is poured into a large flat dish, and the strips of paper passed lengthwise and slowly to and fro until not only wet, but thoroughly saturated. Each strip, when the dipping is finished, is held first by one end, then by the other, to drain off the free drops, and then laid flat upon a clean glass plate and permitted to dry. The use of an electric fan is recommended to hasten drying. Paper so prepared contains everywhere about the same quantity of serum. . ie real titration of the serum now begins. With a ruler, one piece of paper 1s divided into squares of, say, 14 cm., and a series of tubes prepared with cor- * “Serum Diagnosis and Syphilis,” 1910, p. 13 et seq. 288 | Wassermann Reaction for Diagnosis of Syphilis puscle suspension and complement and the paper added 1 square, 2 squares, 214 squares, and so on until the unit is determined. When that is achieved, the exact size of the paper containing the unit being known, one sheet of the paper can be ruled into squares of that size or into squares of twice that size— since the “dose” is two units—at the option of the investigator. The sheets of paper are kept in a clean envelope, the quantity for each test being cut off as needed. The dry serum changes so little that the dose once determined, the size of the square of paper needed for the test remains about the same. The method has the advantage that the amboceptor serum cannot be spoiled or spilled. It has the disadvantage of being slightly less accurate, though it must be admitted that the chances of error in measuring and diluting the fluid serum are probably as great as those arising from inequalities in the distribution of the serum throughout the paper. (4) The Antigen —It has already been shown that complement is labile, and it may have occurred to the reader that its activity is similar to that of ferments. It is now necessary to point out the - many conditions (some of which may arise in the performance of a test so delicate as the Wassermann reaction) by which the comple- mentary action may be affected or set aside. Thus, temperature affects it, and temperatures of o°C. suspend it. It is on this ac- count that the test is always made at 37°C. Like most of the ferments of the living organism, salts affect it, and in salt-free media its action ceases, to return when a small quantity of an alkaline salt is added. Not only inorganic salts, but salts of the fatty acids and the bile-salts may inhibit it. Certain lipoids, such as lecithin, cholesterin, protogon and tristearin, and neutral fats inhibit the complementary action. Some of these substances are always present in the serum containing the complement itself or in the other serums to be tested by its use, and, as Wassermann and Citron have pointed out, we really know nothing about complementary action. Aleuronat, inulin, peptone, albumose, tuberculin, natural and artificial aggressins, gelatin, casein, sitosterin, coagulated serum- albumin, and albuminous precipitates all act as inhibitives to complementary action. Now, in all combinations of several serums and antigens it is always possible that some of these complement-binding or comple- ment-inhibiting substances may be present, hence the first thing that has to be done in the way of titrating the antigen—which is a tissue extract, rich in lipoids which inhibit complementary action—is to determine how much of it can be added to the “hemolytic system” without disturbing hemolysis. As, however, the antigen is not used by itself, but always in com- bination with a serum to be tested, we must always combine it with serum when making the titration, so that the requirements of the test may be conformed with. In order that the essential difference between the normal serum and the syphilitic serum can be reduced The Hemolytic Amboceptor 289 to precise calculation it is imperative that, in all the tests, the same quantity of added serum be employed. Experience has shown this quantity to be 0.2 cc., and this we regard as the unit of serum to be tested. To titrate the antigen we require (1) a normal human serum and (2) a known syphilitic serum, obtained from blood drawn from the arm veins of cases known to be well and cases known to be syphilitic respectively. These serums should be kept on hand in the labora- tory in considerable quantity, as they are constantly needed for making the controls that must accompany each test, as well as for making the preliminary titration of the antigen. TaBLe I.—Series with the Normal Serum Tubes I. trunitof + 1 unit of antigeno.or SWa¢ad = Complete 2A§sye p complement normal serum BEES hemolysis. 2. 6c + “cc + 6c 0.03 Baud az “ #0 83S 3 ce +4 “ce + ce 0.085 spars = ae ee Bo 82d “cc “cc 6c gaaee = “e 4. + + 0.07 Sg hoy as “ te “cc SBoog “ ic. + + 0.08 gales = 38 3; 6 te «e BSSee ce 6. + + 0.09 ogc he = 4 os a 7 ‘c + “c + « 0.01 eee a “cc 7 os 89g Boe 8 ‘ «6 ce ay SSF «eo : + + 0.12 &egae = we 325 “ce ‘ OOS 9: + : + “0.15 BSea5 = = oe 8 tc ‘ NOOO? 10. + + ‘ 0.18 gH oROG = es BOG gs “ “ec “ce Oe ee ae II, + + 0.2 Beaes = ve nd : emolysis, au TaBLe II.—Series with the Syphilitic Serum ubes Pr SHED +, . . —_ oot ‘1. runitof + xzunitof + antigen o.or ogee = Complete complement syphilitic serum Sugg hemolysis. 2 6c + 6 6c 25%us = ‘e i + 0.03 eo Rea = 3. as + fe + ‘ 0.05 Pee = Sugges- : Poop * geez a of yo — ) > a “283 emolysis, 4. =F + 0.07 S328 = Slight a Ba, oe hemolysis. 5. + ss + ‘ 0.08 Bs 8se = Partial OS h lysi: 8 emolysis. 6. ee + es + ‘f 0.09 g8- be = No ? : fg? ae , ae a2 hemolysis. 7 a + “" or 2eafe = “ ‘dh GOOG Ests6 8 ce + 6c “cc gars “ce * 0.82 wa sor = 7 Seba Oak Ge RRS Sah ae ONE iguaig ge. = % no Ag “ Hn Eg 10, + 3 + “cc 0.18 Bbaed = “cc Te 4 8s mwa & MOA 19 290 + Wassermann Reaction for Diagnosis of Syphilis The “set-up” for the titration of antigen is fairly simple. A series of tubes is prepared and divided into two groups. Into each tube in each group is placed 1 unit of complement. Each tube of one group receives the addition of 0.2 cc. of the normal serum; each tube of the other group, o.2 cc. of the known syphilitic serum. All the tubes now receive additions of antigen, so that one tube of each group contains the same quantity. The quantity of antigen not being known, it is only through the experience of others that we can guess where to start. An idea can be formed through study of the tabulation on page 289. From this we find that the unit of antigen is 0.09 cc., the largest quantity of the antigen that can be added without prevent- ing hemolysis when the normal serum is used is probably 0.18 cc. At the same time 0.09 cc. is the smallest quantity that can be added, when the syphilitic serum is used, to prevent it. In this case the dose exactly fulfils Kaplan’s requirement that “The unit dose of antigen must completely inhibit hemolysis . . . of a known luetic serum, provided double the dose does not interfere with the complete hemolysis of cells using a known normal serum and complement.” We have now accomplished the titration of all five of the factors involved in making the Wassermann reaction, but we have done. more, we have really done the test, and have seen positive and negative results, for in titrating the antigen we have developed the reaction by which we can confirm the diagnosis of syphilis in the case from whom the syphilitic serum was obtained, and have failed to develop it with the known normal serum. However, in order that those who perform the test may be able to escape the numerous errors into which one may fall, it will be necessary to point out the controls by which they can be avoided. A Wassermann reaction at the present time comprises not only ~ the test of the patient’s serum, but simultaneously includes a long series of other tests by which the validity of every part of the test and the correct titer of all the reagents employed can be simultane- ously ascertained. Every one who makes the test should practice some such systematic method as is suggested by the following scheme for the “set-up.” Nine tubes are employed for the usual test. These are stood in a rack in the same order for every test, and in the course of time it becomes a matter of habit to know the tubes by number, and to recall for what each stands. If many tests are to be made at one time, it is, of course, un- necessary to make more than one series of controls. Of the complementary serum we add 1 cc. to 9 cc. of 0.85 pet cent. (physiologic) salt solution, making each cubic centimeter of the dilution of the fluid equal o.1 cc. This quantity, carefully measured by the same volumetric pipette, is dropped into each tube, and this pipette laid aside. 5 I. The Fixation Test, the first part of the Wassermann Test. ; $38 > eta ag ‘B aa 3 Ae aa, aags 18 asd aig as 2990 m OO. 3 Sgt ° oquad Oko Or ogegy * ad aon zee aeay ae. x eo 22a “8 Zant Q HO % Hos BESS e3¢ eB pO Oc cE eed 8 Zuas Zeke zZ9ko ZS5 Ze%9 ZUG Zo Zane BS SEES S44 ogo Oye : SHOP 8 o's og | 28 2 oo OBws Og» Yo ogy Og ag Oss Cow Og -B | SattSotdiod $8 2 |SotrSatution| 7% |SaitSalution 228 |SaltSotuhn | <3 | SoitSoluhan S205 |SottSotution| +25, |SaltSolution| 3 |SaltSalution) = 'S 2 |SaltSoluhion 3 add fo3ce.| 4 ae addle3ec.| ‘S'z jaddlo3ca} 4 3 add fe3cc) “S — |addterce.) woo addla3ce} 90 | add lesce, 3 add lo5cG.) & y g odd BSec. #1 7Dose oan afl 1Dose oe =| Jose ae — rd = Sas § | dahgen | Bo Ba |Antsen | Eee ce oon) Fae £@2)dpese | & £33 © (bacco 3 oS teaaieone Sg laxee umes, a Od larccAstives | 3 [azecHermls| 2° 2D [ezcedermal $ eee Athen a ag a ccFikew Soon] ‘Lunitof 6 o'~ \Lunito OB \ Lunifor Cod e\ Iunitet Oe \ tuntt) 6’ \ funitor OaL\ Junitot OV Jumbot 9 Ac | qnito 3 Gee) O86 > \Gnplemey OS \complemny OS > & \Compeam OF OBE \Gaplenmy Cvs Campreum>/ OO Complasndy Der a & EE ey & ggg” “§ 22 #5 Es II. The Hemolytic Test, the second part of the Wassermann Test.—The same tubes as above. Each tube receives the additions indicated below, and is then again stood in the thermostat at 37°C. for two hours in order that the occurrence or non-occur- rence of hemolysis may show whether the complement had previously been fixed or not. If the complement be fixed there is no hemolysis in tubes 1 and 3, and the patient has syphilis (within such limitations as the validity of the test necessitates). The Hemolytic Amboceptor ‘Dose of 1 Dose of 1 Dose of LDoseof | 1 Dose of LDose of JSboseof 1 Dose of Salt Solution mbocepror Amboceprr |Amboceplar Abmboceplor Amboceplor Atnbocepror Amboceptor Amboceplor Ice. dunit unit dunit dlumt dunit unit Lonit unit Loni Carpuscles ‘orpuscles Corpuscles Corpuscles Corpuscles orpuscles Corpuscles puscles Corpuscles 292 Wassermann Reaction for Diagnosis of Syphilis The serum to be tested is drawn into a second finely graduated pipette, and 0.2 cc. added to tubes 1, 2, and g, and that pipette laid aside. The positive syphilitic serum used to control the test is similarly drawn up in a fresh pipette and o.2 cc. of it measured into tubes 3 and 4, and the pipette laid aside. The normal serum used as a control is similarly drawn into still another pipette and o.2 cc. measured into tubes 5 and 6, and the pipette laid aside. The alcoholic extract composing the antigen is next added, either by diluting it so that 1 cc. contains the unit, or measuring the unit cae directly into the tubes. The antigen is added to tubes I, 3, 5, and 7, and the pipette laid aside. Lastly, each tube receives a correctly measured quantity of 0.85 per cent. sodium chlorid solution to bring the total bulk of fluid up to exactly 3 cc. Each tube is now shaken carefully, so as not to cause frothing of the fluid, and the rack is stood in a thermostat kept at 37°C. At the end of an hour the rack is removed, and every tube receives the addition of 1 unit of the sheep corpuscle suspension and, with the exception of tube g, receives one dose of amboceptor, either the serum measured by diluting so that 1 cc. equals the dose, or the necessary square of paper. This, in the former case, brings the total bulk of fluid to 5 cc., in the latter makes it necessary to add 1 more cubic centimeter of salt solution to each tube. We aim to have exactly 5 cc. of fluid in each tube. The tubes are again stood in the thermostat, where they are per- mitted to remain for an hour, when the readings are taken and carefully noted. After this the rack and all the tubes are placed in the ice-box until twenty-four hours old, when the final readings are taken and the conclusions are reached. As a rule, the readings taken after the second hour of incubation and those taken after twenty-four hours correspond. A valid test should show the following: Tubes 1. No hemolysis in syphilis. Hemolysis in health. fo, Complete hemolysis. 3. No hemolysis (this is the standard of comparison). 4. Complete hemolysis. Test Controls. 4 5 ae? 8. 9. No hemolysis, as a rule. In the tubes in which hemolysis takes place the change is very marked. The hemoglobin dissolves out of the corpuscular stroma and saturates the fluid, transforming it from the opaque pale red to a transparent Burgundy red. Sometimes the corpuscular The Hemolytic Amboceptor 293 stroma dissolves, sometimes it sediments as a colorless mass to the bottom of the tube. In the tubes containing the positive or syphilitic serum, and in which there is complete complement fixation, the unaltered cor- puscles sediment to the bottom of the tube, leaving a colorless fluid above. When the complement fixation is complete there is no solution of the hemoglobin. Such a result has been described by Citron as ++-++. When the sedimented corpuscles lie at the bottom of a slightly reddened fluid, the result is said to be + + +; when at the bottom of a distinctly red fluid, ++, etc. Confusion will be avoided by making renorts as positive in all cases in which there is Fig. 105.—A typical positive Wassermann reaction with the recommended controls as it appears after standing twelve hours. Corpuscular sedimentation without hemolysis is seen in tubes 1, 3, and 9; complete hemolysis in the others. a distinct red corpuscular deposit, regardless of the state of the supernatant fluid, and negative when there is no such deposit. When we come to inquire why the supernatant fluid should be red, we reach a question that is not quickly answered. In order to be in a position to explain it in certain cases we introduced in our series tube 9, by which to discover whether the serum under examina- tion contain, as is sometimes the case in health as well as in syphilis, sheep corpuscle amboceptors. If tube 9 shows such amboceptors to be in the serum, it explains the redness of the fluid bathing the corpuscles, and does not invalidate the test. If no such amboceptors are present and the fluid is still red, it may indicate that a little of 294 Wassermann Reaction for Diagnosis of Syphilis the complement remained unfixed and acted upon a few of the corpuscles. _ The Validity of the Test —The Wassermann reaction is not a certain test for syphilis. It is an aid in making the diagnosis, especially in cases in which there are no symptoms. Of thousands of bloods of normal persons examined, the results are almost 100 percent. negative. Basset-Smith has had a positive reaction in a case of scarlet fever and one in a case of malignant disease of the liver with jaundice; Oppenheim, one in a case of tumor of the cerebellopontine angle; Marburg, one in a similar case; New- mark reports 2 cases of brain tumors with positive reactions; Cohn, a positive in a patient with a cerebral tumor. The Wassermann reaction is of no value for the differential diagnosis of syphilis and frambeesia or yaws. All cases of the latter give a positive reaction. Positive reactions have been found in some cases of nodular leprosy, in a few cases of malaria, in some cases of pellagra, and in a good many cases of sleeping sickness. These seem to form the greater part of positive reactions in non-syphilitics thus far recorded. In active syphilis Wassermann had go per cent. of positive reac- tions in 2990 cases; and most others report about the same. Basset- Smith in 458 such cases found 94 per cent. positive reactions. In latent syphilis Wassermann found 50 per cent. positive reactions; Basset-Smith, 46 per cent. In chronic, presumably syphilitic, disease of the nervous system, general paresis, and tabes dorsalis the positive reactions vary. In the former disease some have found as high as go per cent. positive; in the latter the usual figures vary about 50 per cent. It is thus seen that the occurrence of the reaction is much more conclusive evidence of the presence of syphilitic infection than the failure of the reaction is of its absence. Treatment greatly influences the test. When under active treatment, either with mercury and iodids or with salvarsan, the reaction of the serums is usually negative. Nature of the Reaction.—We now reach the point of considering the nature of the reaction. It is certainly not a variation of the Bordet-Gengou phenomenon. It does not occur because of the presence in the blood of syphilitics of antibodies which combine with the antigen and fix the complement. It is probably not comple- ment fixation so much as complementary inhibition, through the ‘presence in the blood of syphilitics of certain metabolic products, ‘whose action interferes with the complement in some entirely ‘different manner. NOGUCHI’S MODIFICATION OF THE WASSERMANN REACTION Noguchi* has modified the Wassermann reaction, first by employ- ing as an antigen an extract of the heart of a normal guinea-pig, * “Serum Diagnosis of Syphilis,” Philadelphia, rg10, J. B. Lippincott Co. Noguchi’s Modification 205 and, second, by making use of human instead of sheep corpuscles for the hemolytic test. The advantage of the latter depends upon the fact, carefully determined by Noguchi, that human blood-serum contains no amboceptors active in effecting hemolysis of human blood- corpuscles, though it not infrequently contains hemolytic ambocep- tors for sheep corpuscles. In the directions for making the Wasser- mann test a control test for determining their presence or absence was found expedient. It will also be remembered that the presence of these amboceptors causes no invalidity of the test, provided it be recognized. Noguchi also varies the technic in such a manner that very small quantities of the various reagents are employed—a necessity that arises from the relatively small quantity of the patient’s blood ob- tainable according to the method he employs. The reagents employed are as follows: (1) The Serum to be Tested—To obtain this, Noguchi binds the finger of the patient with a rubber band, makes a good-sized punc- ture near the root of the nail with a Hagedorn needle, and collects about 2 cc. of the blood in a Wright tube (see directions for making the opsonic index). The blood soon coagulates in the tube, which is then scratched with a diamond or file, broken, and the serum re- moved with a capillary pipet. The serum may or may not be in- activated by heat, according to the option of the experimenter. The dose of the unheated serum is 1 drop; of the inactivated serum, 4drops. The same doses of the normal and syphilitic control serums are used. (2) The Complement—This consists of fresh guinea-pig serum. ‘Of it he makes a 4o per cent. dilution in physiologic salt solution by adding one part of the serum to 1}4 parts of the salt solution; 0.1 ce. is the unit. Two units constitute the “dose.” (3) The Antigen—tThe antigen is made, according to the direc- tions given in the description of the Wassermann test, out of normal guinea-pig heart. The extract is dried upon filter-paper, as has been recommended for the hemolytic amboceptor, and titrated according to the size of the square of paper needed, instead of the quantity of fluid to be added. (4) The Corpuscle Suspension.—For this purpose either normal human corpuscles or the corpuscles of the patient whose blood is to be examined may be employed. Instead of a 5 per cent. suspension a I per cent. suspension is recommended. If normal corpuscles are employed, it is necessary to wash them free of the normal serum or plasma, which Noguchi accomplishes as follows: 8 cc. of normal salt solution are placed in a large test-tube, and the blood flowing from a puncture (in the operator’s own finger, for example) permitted to drop in, the proportion being 1 drop each 4 cc. The fluid is then shaken and stood on ice over night, when the corpuscle sediment and the supernatant fluid containing the fibrin factors and ferment i sion is f Syphil d the suspen jagnosis 0 ion, an Wassermann Reaction for D Or, in a laboratory, the corpuscles can be decanted and replaced by fresh salt solut made by shaking. 296 is If the patient’s Set for diagnosis. _ Positive control set. Negative control set. Test with the serum in question | Test with a positive syphilitic serum Test with a normal serum w ue é e ® E a. Unknown serum, I drop.* a.’ Positive syph. serum, 1 drop* a.” Normal serum, 1 drop.* 2 g = : = x O: Complement, 2 units, O: Complement, 2 units. O: Complement, 2 units. 5 3 2 Q Q 3 6 ¢. Corpuscle susp., 1 ¢.c. c. Corpuscle suspension, 1 ¢.c. c. Corpuscle susp., 1 c.c. z q ao toe o8 & 8 ee : oO S| 2g | of : a. Unknown serum, 1 drop.* ‘a.’ Positive syph. serum, 1 drop* a.” Normal serum, 1 drop.*]| & 23 $3 oy on ony £ O: Complement, 2 units. O: Complement, 2 units. O: ‘Complement, 2 units. 2 3a 2 8 * Z $ ° on g ¢. Corpuscle susp., 1 ¢.c. c. Corpuscle suspension, 1 c.c. ¢. Corpuscle susp., 1 ¢.c. 2 a By n s be +Antigen.t +Antigen.t +Antigen.t 3 a6 35 Q oa yc & |< a * When working with inactivated serum, 4 drops (0.8 cc.) should be employed; with cerebrospinal fluid, 0.2 cc. (not inactivated) is used. { When using unheated serum, pure lipoids prepared by Noguchi’s methodshould be used; with inactivated serum aqueous, alcoholic, or artificial antigen (Sachs and Roudoni) may also be used. (This diagram and reading matter are reproduced from “Serum Diagnosis of Syphilis,’’ by Hideyo Noguchi, M. D., with the kind permission of the publishers, J. B. Lippincott Co.) own corpuscles are to be employed, some of them may be dis- tributed, through the serum without any washing, by simply shaking washed as usual with the aid of the centrifuge. Noguchi’s Modification 297 it up a little with the clot. It is not essential exactly to measure the corpuscles, as after a few trials with the suspension of normal cor- puscles the eye becomes accustomed to the color, intensity, and density corresponding to the requirement. (5) The Antihuman Hemolytic Amboceptor.—This is prepared by injecting rabbits, according to the method already described, with washed human corpuscles obtained from fresh human placente or from the heart of a fresh cadaver come to autopsy. The serum of the rabbit, when obtained, is dried upon blotting-paper and titrated as already described. The “set-up” for the test, as given by Noguchi, is less cumber- some than that recommended for the Wassermann test and includes six tubes. It can best be understood by reference to the diagram. The method recommends itself through its simplicity and con- venience, no sheep corpuscles being used, and through the smaller quantity of blood required, it seeming to the patient that less damage is done by pricking the finger than by introducing a syringe needle into a vein. It is, moreover, a very sensitive test, and gives very accurate results as far as regards positive cases. Unfortunately, it seems to have the demerit of occasionally finding the reaction in negative cases, which is a serious defect. Diagnosticians are still divided in opinion, some preferring the Wassermann test, some the Noguchi test, and some always doing - both, permitting the one to control the other. In the long run the Wassermann test seems to meet with most favor, and in the hands of the majority leads to most satisfactory results. PART II. THE INFECTIOUS DISEASES AND THE SPECIFIC MICRO-ORGANISMS CHAPTER I SUPPURATION SUPPURATION was at one time looked upon as a normal and in- evitable outcome of the majority of wounds, and although bacteria were early observed in the purulent discharges, the insufficiency of information then at hand led to the belief that they were spon- taneously developed there. From what has already been said about the evolution of bac- ‘teriology and the biology and distribution of bacteria, the relation- ship existing between bacteria and suppuration, and, indeed, be- tween bacteria and disease in general, is found to be reversed. Instead of being the products of disease, the micro-organisms are the cause. Suppuration, while nearly always the result of micro-organismal activity, is not a specific infectious process. Being but the expression of tissue irritation arising through strong chemotactic influences, as many bacteria may be associated with it as can bring about the essential conditions. Bacteria with which these qualities are exceptionally marked appear as the common cause of the process; those with which it is less marked, as excep- tional causes. The relative frequency with which certain varieties of bacteria are associated with suppuration ‘is shown in the following table from Karlinski:* ’ Suppuration in man— Streptococci, 45 cases. Staphylococci, 144 ‘ Other bacteria, 15 Suppuration in the lower animals—Streptococci, 23 Staphylococci, 45 Other bacteria, 15 Suppuration in birds— Streptococci, II Staphylococci, 40 Other bacteria, 20 Andrewes and Gordon,{ after the examination of large numbers . Centralbl. f. Bakt.,” etc., 1800, vir, S. 113. «ql Report of the Local Government Board of Great Britain,” Supplement; Report of the Medical Officers,” 1905-06, vol. XXXV, Pp. 543- ‘299 300 Suppuration of staphylococci from lesions of the human skin and mucous mem- branes, came to the conclusion that four varieties are differentiable. Of these, the Staphylococcus pyogenes is the most common and most important. When typical, it produces an orange-colored pig- ment; when atypical, it may be lemon yellow or white. Staph- ylococcus epidermidis albus is a distinct species. ‘The differences between these cocci are shown in the table. StapHyLococcus EpipERmIpIs ALBUS (WELCH) General Characteristics.—A non-motile, non-flagellate, non-sporogenous, slowly liquefying, non-chromogenic, aérobic and optionally anaérobic, doubtfully pathogenic coccus, staining by the usual methods and by Gram’s method, and having its natural habitat upon the skin. Under the name Staphylococcus epidermidis albus, Welch* has described a micrococcus which seems to be habitually present upon the skin, not only upon the surface, but also deep down in the Mal- pighian layer. He believes it to be Staphylococcus pyogenes albus in an attenuated condition, and if this opinion be correct, and there is seated deeply in the derm a coccus which may at times cause sup- puration, the conclusions of Robb and Ghriskey, that sutures of cat-gut when tightly drawn may be a cause of skin-abscesses by predisposing to the development of this organism, are certainly justifiable. As the morphologic and cultural characteristics of the organism correspond fairly well to those of the following species, no separate description of them seems necessary. STAPHYLOcOoccUS PYOGENES ALBUS (ROSENBACH)f _ General Characteristics.—A non-motile, non-flagellate, non-sporogenous, ' liquefying, non-chromogenic, aérobic and optionally anaérobic, mildly patho- genic coccus, staining by the ordinary methods and by Gram’s method. Although, as stated, Staphylococcus pyogenes albus is a common cause of suppuration, it rarely occurs alone, Passet so finding it in but 4 out of 33 cases investigated. When pure cultures of the coccus are subcutaneously injected into rabbits and guinea-pigs, abscesses occasionally result. Injected into the circulation, the staphylococci occasionally cause septicemia, and after death can be found in the capillaries, especially in the kidneys. From this it will be seen that the organism is feebly and variably pathogenic. In its morphologic and vegetative characteristics Staphylococcus albus is almost identical with the species next to be described, dif- fering from it only in the absence of its characteristic golden pigment. * “Amer. Jour. Med. Sci.,” 1891, p. 439. { “Wundinfektionskrankheiten des Menschen,” Wiesbaden, 1884. 301 Staphylococcus Pyogenes Albus : ae es a : ; f- + * sno900 JON ab = = = + SAM | PPB V | -o[Aydeis jmog 3 = _ = : : + snearyes 70N ae at = +e + OTM. a { snosov0j4ydeig ‘+ + snqye “Ayqeegd | + + + + Se + + + “OTM. ‘Vv | siprurepida | snososo0fAydeysg . ; 4 as “moqpad : 3 shame ATqStH a iP ar te + + oT aZurio v { snosoo0jAydeyg sad AJ, ° 5 - ery (LE ye ‘i i 3 rormafowzeg | PP) | “CP? Bie es eauyeaey, -paonpar |g on he eae a | creseaeae ing aed : aquuEyY | THAATD |-393 asojr]|-s9y asoyfe yl ee Foie P21 PIMAN by unepo|pawsoy 3019" yuswStd' uy sayoereqD ‘NVW NI GNNOd INDODOTAHAVIS AO SHd AL AS1HO HHL #0 HIAVL 302 Suppuration STAPHYLOCOCCUS PYOGENES AUREUS (ROSENBACH*) General Characteristics—A non-motile, non-flagellate, non-sporogenous’ liquefying, chromogenic, pathogenic, aérobic and optionally anaérobic coccus’ staining by the ordinary methods and by Gram’s method. Commonly present upon the skin, though in smaller numbers than the organisms already described, is the more virulent and sometimes dangerous Staphylococcus pyogenes aureus, or ‘golden staphylococ- cus,” first observed by Ogston and cultivated by Rosenbach. As the morphology and cultural characteristics of this organism are identical with those of the preceding species, it seems convenient to describe them together, pointing out such minor differences as occur. In doing this, however, it must not be forgotten that, although Staphylococcus albus was first mentioned, Staphylococcus aureus is the more common organism of suppuration. STAPHYLOCOCCI PYOGENES AUREUS ET ALBUS Distribution.—The cocci are not widely distributed in nature, seeming not to finda purely saprophytic existence satisfactory. They Fig. 106.—Staphylococcus pyogenes aureus (Giinther). occur, however, upon man and the lower animals, and can occasionally be found in the dusts of houses and hospitals—especially in the surgical wards—if proper precautions are not exercised. They are common upon the skin, in the nose, mouth, eyes, and ears of man; they are nearly always present beneath the finger-nails, andsome- times occur in the feces, especially of children. : Staphylococci are the most common micro-organisms in some acne pustules, in furuncles, in carbuncles, in superficial and deep abscesses, and in the ordinary run of surgical injections. So com- mon are they that one should never be satisfied that he has exhausted * “ Mikroorganismen bei Wundinfektionskrankheiten des Menschen,” Wies- baden, 1884. Staphylococcus Pyogenes Aureus et Albus 303 the etiological possibilities of the case through their demonstration. He should always seek for less evident though sometimes far more important organisms. In the absence of such, and in their absence only, should the case be referred to staphylococci. Morphology.—The cocci are small spheres measuring about 0.7—- 1.0 » in diameter. There is no definite grouping in either liquid or solid cultures. It is only in pus or in the organs or tissues of dis- eased animals that one can say that a true staphylococcus (bunch of grapes) grouping occurs. _ The organisms are not motile and have no flagella. They do not form spores. Staining.—They stain easily and brilliantly with aqueous solutions . of the anilin dyes and by Gram’s method. Fig. 107.—Staphylococcus pyogenes aureus. Colony two days old, seen upon an agar-agar plate. XX 40 (Heim). Isolation.—Staphylococci are easy organisms to isolate, and can be secured by plating out a drop of pus in gelatin or in agar-agar. The colonies of Staphylococcus aureus differ considerably in color, some being much paler than others. Cultivation.—The staphylococci grow well upon all the standard culture-media either in the presence or in the absence of oxygen at temperatures above 18°C., the most rapid development being at about 37°C. Colonies.—Upon the surface of gelatin plates the colonies appear as small whitish points, after from twenty-four to forty-eight hours, rapidly extending to the surface and causing extensive liquefaction of the medium. The formation of the yellow pigment can be best observed near the center of thecolonies. Under the microscope the colonies appear as round disks with circumscribed, smooth edges. They are distinctly granular and dark brown. When the colonies are grown upon agar-agar plates, the formation of the pigment is more distinct. ; 304 Suppuration Gelatin Punctures.—In gelatin the growth occurs along the whole length of the puncture, causing an extensive liquefaction of the medium in the form of a long, narrow, blunt-pointed, inverted cone, sometimes described as being like a stocking, full of clouded liquid, at the apex of which a collection of golden or orange-yellow precipitate is always present in Staphylococcus aureus. It is this precipitate in particular that gives the organism its name, “golden staphylo- coccus.”’ Agar-Agar.—The growth of the golden staphylococcus upon agar-agar is subject to con- siderable variation in the quantity of pigment produced. Sometimes, perhaps rarely, it is golden; more commonly itis yellow, often cream color. Along the whole line of inoculation a moist, shining, usually well-circumscribed growth occurs. When the development occurs rapidly, as in the incubator, it exceeds the rapidity of color production, so that the center of the growth is distinctly colored, the edges remaining white. Potato.—Upon potato the growth is luxu- riant, Staphylococcus aureus producing an orange-yellow coating over a large part of the surface. The potato cultures may give off a sour odor. Bouillon.— When grown in bouillon the organ- ism causes a diffuse cloudiness, with a small quantity of slightly yellowish sediment. The Tee reaction of the medium becomes increasingly oe ae acid. Nitrates are reduced to nitrites. alreus, “Puneture Milk.—In milk, coagulation takes place in culture three days about eight days, and is followed by gradual eee digestion of the casein. In litmus milk slow acid production is observed. Thermal Death Point.—Staphylococci are usually quite suscep- tible to the effect of heat, though their resistance is not uniform. Sternberg found them destroyed by an exposure to 62°C. for ten minutes, and to 80°C. for one and a half minutes, but three cultures studied by von Lingelsheim were not killed by an exposure to 60°C. for an hour, and one culture studied by him endured an exposure to 80°C. for ten minutes. Metabolic Products.—Staphylococci can make use of free or combined oxygen, hence are aérobic or anaérobic. In liberating combined oxygen, no gasis generated in any culturemedium. They produce ferments by which gelatin is liquefied, milk coagulated and digested, blood-serum digested and slowly liquefied. A yellow pigment is produced. Nitrates are reduced to nitrites in cultures Staphylococcus Pyogenes Aureus et Albus 305 kept for three days at 37°C. Staphylococci are capable of producing fatty acids from sugars, hence acidity develops in media containing lactose, maltose, mannite and glycerin. The acids most commonly produced are acetic, valerianic, butyric and propionic. Toxic Products.—Leber seems to have first conceived of suppura- tion as a toxic process depending upon the soluble products of parasitic fungi, and in 1888, through the action of alcohol upon staphylococci, prepared an acicular crystalline body soluble in alcohol and ether, but slightly soluble in water, to which he gave the name phlogosin. Mannatti found that pus has substantially the same toxic prop- erties as sterilized cultures of the staphylococcus; that repeated in- jections of sterilized pus induce chronic intoxication and marasmus; that injection of sterilized pus under the skin causes a grave form of poisoning; and that the symptoms and pathologic lesions caused by these injections correspond with those observed in men suffering from chronic suppuration. Van de Velde* found that the staphylococcus has some metabolic products destructive to the leukocytes, which he has called leuko- cidin. This poison causes the cells to cease ameboid movement, become spheric, and gradually to lose their granules, until they finally appear like empty sacs containing shadow nuclei, which eventually disappear. The leukolysis occurs in about two minutes. These observations have been abundantly confirmed. 1500 (Davis). (Photomicrograph by Mr. L. S. Brown. Vital Resistance.—The organisms seem to possess little vitality, their life in artificial culture being limited to a few days. Fre- quent transplantation enabled Davis to carry them on to the eleventh cultural generation. Pathogenesis.—The organism is pathogenic for man and certain monkeys (macacus), but not for the ordinary laboratory animals. The organism can be found in large numbers in both the genital and extragenital chancroidal lesions, and usually in small numbers in the pus from chancroidal buboes. It has not been encountered elsewhere. Lenglet* isolated the organism in pure culture, and by inoculation with his cultures reproduced the lesions in man. * “Bull. Med.” 1898, p. 1051; “Ann. de Dermatol. et de Syph.,” 1901, 1, p. 209. CHAPTER XI ACUTE CONTAGIOUS CONJUNCTIVITIS Tue Kocu-WEEKS BACILLUS General Characteristics.—A minute, slender bacillus, non-motile, non-flagel- lated, non-sporogenous, non-liquefying, non-chromogenic, aérobic, and optionally anaérobic, staining by the ordinary methods but not by Gram’s method, sus- ceptible of cultivation upon special media only, and specific for acute contagious conjunctivitis. / Acute contagious conjunctivitis is a common and world-wide affection, sometimes called “pink eye,” and sometimes erroneously called catarrhal conjunctivitis. All its characteristics, and es-— pecially its contagiousness, point to its being a specific disease due to a specific cause, and thus entirely different from. ordinary non- specific catarrh. Specific Micro-organism.—The first bacteriologic investigation of acute contagious conjunctivitis was made by Robert Koch,* when in Egypt investigating a cholera epidemic. While in Alex- andria he examined the secretions from so cases of conjunctivitis, finding the gonococcus, or an organism closely resembling it. Ina less severe form of the disease, however, he found a peculiar small bacillus. He seemed satisfied with this observation, or had no time to pursue the matter farther, for no cultivation or other experiments are mentioned. The organism was observed from time to time, but no serious consideration seems to have been devoted to it until Weeks} pub- lished an account of what seemed to be the identical organism, which he not only observed, but also cultivated, and eventually success- fully inoculated into the human conjunctiva. In the same year Kartulisf in Alexandria succeeded in cultivating the same organ- ism. In 1894 Morax published a brochure in Paris in which he says that ‘‘the disease [which he describes under the name of acute conjunctivitis] is characterized by the constant presence in the conjunctival secretions of a small bacillus seen for the first time by Koch, but studied some years later by Weeks, and now known as the bacillus of Weeks.” Further descriptive and clinical information can be found in a paper by Weeks, ‘“‘The Status of our Knowledge of the Atiological Factor in Acute Contagious Conjunctivitis.”’§ * “Wiener klin. Wochenschrift,” 1883, p. 1550. Tt “N. Y. Med. Record,” May 21, 1887. t“Centralbl. f. Bakt. u. Parasitenk.,” 1887, p. 289. § “New York Eye and Ear Infirmary Reports,” Jan., 1895, vol. 11, Part. 1, p. 24. : 406 Cultivation 407 Morphology.—The organism is very tiny and is said to bear some resemblance to the bacillus of mouse-septicemia. It measures 1to2 X 0.25u(Weeks). The lengthis more constant in individuals found in the pus than those taken from cultures. In cultures the organisms are longer and more slender. Involution forms of con- siderable length and of irregular shape also occur. No spores are observed. The organism has no flagella and is not motile. Staining—Weeks found that the organism stained well with watery solutions of methylene blue, basic fuchsin, or gentian violet. The color is fainter than that of the nuclei of the associated pus-corpuscles, and is much less intense in old than in fresh cultures. It is readily given up when treated with alcohol or acids. Morax found that the bacilli did not retain the color in Gram’s method. Fig. 148.—The Koch-Weeks bacillus in conjunctival secretion. Magnified tooo diameters (Rymowitsch and Matschinsky). Cultivation.—The organism refuses to grow upon any of the ordinary culture-media. Weeks found, however, that if the per- centage of agar-agar used was reduced to o.5 per cent., growths could be secured by incubation at 37°C., and successful transplanta- tions carried on to the sixteenth generation. Abundant moisture | was essential. The method of isolation adopted by Weeks was as follows: “The conjunctival sacs were thoroughly washed with clean water, removing the secretion present by means of absorbent cotton. The patient was ‘then directed to keep the eyes closed. After five or ten minutes had elapsed, the eyes were opened, and the secretion that had formed, lying at the bottom of the cul- de-sac, was removed by means of a sterilized platinum rod and transferred to the surface of the agar. The mass of tenacious secretion was drawn over the surface of the agar and left there, the platinum being thrust into the agar two or three times before removal.” At the end of forty-eight hours a slight haziness appears along the path of the wire, and on the surface of the agar a very small 408 Acute Contagious Conjunctivitis patch is noticeable; this is of a pearly color and possesses a glisten- ing surface. By the formation of small concentric colonies the growth extends for a short distance. At the end of the fourth or fifth day the growth ceases to advance; it is never abundant. The culture dies in from one to three weeks. Pathogenesis.—Both Weeks and Morax have tested the organ- ism for pathogenic activity, and in every case in which pure cultures of it were placed upon the human conjunctiva, typical attacks of the acute conjunctivitis resulted. The organism fails to infect any of the lower animals. Association.—Both Weeks and Morax found the organism in intimate association with a larger club-shaped bacillus, which was regarded as the pseudo-diphtheria bacillus. It seems to be of no pathogenic significance. Tue Morax-AXENFELD BACILLUS In 1896 Morax* found a new bacillus in certain cases of epidemic — subacute conjunctivitis. Immediately afterward Axenfeld* pre- sented to a congress in Heidelberg cultures of the same bacillus that he had isolated from 51 cases of what he called “Diplobacillen- conjunctivitis” that occurred a few months before as an epidemic in Marburg. De Schweinitz and Veasy,t Alt§ and others found the same diplobacillus in America, and many others confirmed the observations in various parts of Europe. It has also been found in Egypt. There is no doubt, therefore, but that this is a widely dis- tributed organism. Morax produced the disease by placing a pure culture of the organism upon the human conjunctiva. He was unable to infect any of the lower animals. In this subacute form of conjunctivitis there is very little secre- tion, and to secure the micro-organism either for microscopic ex- amination or for cultivation recourse must be had to minute flakes of grayish mucus that collect upon the caruncle. Morphology.—The bacillus is small, commonly occurs in pairs or chains. It measures approximately 2 mw in length. It is not motile, has no flagella, and forms no spores. It is somewhat pleo- morphous. Involution forms soon appear in artificial cultures. Staining.—The organism stains by ordinary methods, but does not stain by Gram’s method. Cultivation—The organism grows only upon alkaline blood- serum or upon culture-media containing blood-serum. Morax made his original observation by using Léffler’s blood-serum mixture. The colonies appear in twenty-four hours at 37°C. The blood- *“Ann. de l’Inst. Pasteur,” June, 1896; “Ann. d’Oculist,” Jan., 1897. i Heidelberg Congress,” 1896; “Centralbl. f. Bakt.,” etc., 1897, XXL t “Ophthalmological Record,” 1899 § “Amer, Jour. of Ophithalusslogy * 1898, p. I71. Zur Nedden’s Bacillus 409 serum is almost immediately liquefied, so that the growing colonies appear to be sinking into the medium after thirty-six hours. The entire tube of medium may eventually be liquefied. Upon agar-agar containing serum, grayish-white colonies of small size, resembling colonies of gonococci, are formed. Growth is slow. Bouillon is slowly clouded. Pathogenesis.—The pathogenic and specific nature of the diplo- bacillus was made clear by Morax, who produced the disease in man by placing a pure culture upon the human conjunctiva. ZUR NEDDEN’s BACILLUS This bacillus was the only organism that Haupt* was able to isolate from a neuroparalytic with confluent peripheral ulcera- Fig. 149.—The Morax-Axenfeld diplobacillus of conjunctivitis. Magnified Iooo diameters (Rymowitsch and Matschinsky). tions of the cornea. It seemed to be identical with an organism that zur Nedden had found previously in a case of corneal ulcera- tion in the clinic at Bonn. Morphology.—It is a tiny bacillus, less than 1 yw in length, slightly curved, generally single, but sometimes in pairs and short chains. It is not motile, has no flagella, forms no spores. Staining.—It stains ordinarily, but not by Gram’s method. Cultivation.—It is easily cultivated upon the ordinary laboratory media, the cultures being without characteristic peculiarities. Gelatin js not liquefied. Milk is coagulated. Acid but no gas is formed in glucose media. A thick yellowish growth appears upon potato. No indol is formed. Pathogenesis.—Corneal ulcers were formed in a guinea-pig after artificial implantation in the corneal tissue. Kee . * : “Tnaugural Dissertation,’ Bonn, 1902. 410 Acute Contagious Conjunctivitis MISCELLANEOUS ORGANISMS IN CONJUNCTIVITIS In addition to the foregoing organisms, others not infrequently make their appearance as excitants of conjunctivitis. The most frequent of these being the pueumococcus, the most dangerous, the gonococcus. The former produce a severe conjunctivitis, with _ the formation of a false membrane, the latter the well-known blenorrhea and ophthalmia neonatorum. Streptococci, diphtheria bacilli, staphylococci, meningococci, colon bacilli, Bacillus pneumoniae (Friedlander), and other organisms have been found and appear to be responsible for conjunctivitis CHAPTER XII DIPHTHERIA Bacittus DieHTHERT# (KLEBS-LOFFLER) General Characteristics —A non-motile, non-flagellate, non-sporogenous, non-chromogenic, non-liquefying, aérobic, purely parasitic, pathogenic, toxico- genic bacillus, cultivable upon the ordinary culture media, staining by the ordi- nary methods and by Gram’s method. In 1883 Klebs* demonstrated the presence of a bacillus in the pseudo-membranes upon the fauces of patients suffering from diphtheria, but it was not until 1884 that Léfflert succeeded in isolating and cultivating it. The organism is now known by both their names, and called the Klebs-Léffler bacillus. Morphology.—The bacillus is about the length of the tubercle bacillus (1.5-6.5 4), but about twice its diameter (0.4-1.0 w), has a slight curve similar to that which characterizes the tubercle bacillus, and has rounded and usually clubbed ends. It does not form chains, though two, three, and rarely four individuals may be found conjoined; usually the individuals are separate from one another. The bacillus has no flagella, it is non-motile, and does not form spores. Distinct polar granules can be defined at the ends of the bacilli. Occasional branched forms are observed, though Abbott and Gilder- sleevet do not regard branching as a phase of the normal develop- ment of the organism and do not find it common upon the standard culture media. The bacillus is peculiar in its pleomorphism, for among the well-formed individuals which abound in fresh cultures a large number of peculiar organisms are to be found, much larger than normal, some with one end enlarged and club shaped, some greatly elongated, with both ends similarly and irregularly expanded. These probably represent an involution form of the organism, for they are present in perfectly fresh cultures. The involution of the diphtheria bacillus seems to occur in pro- portion to the rapidity of its growth. Upon Léffler’s serum mix- ture, which seems best adapted for its cultivation, the involution of the organism takes place with great rapidity, so that large clubbed organisms and large organisms with polar granules are very common. On the other hand, upon agar and glycerin agar-agar, where the organism grows very slowly, it usually appears in the form of short spindle and lancet shapes. So different are these forms that * “Verhandlungen des Congresses fiir innere Med.,” 1883. { “Mittheilungen aus dem kaiserlichen Gesundheitsamte,” 2. _ ¢“Centralbl. f. Bakt.,” etc., Dec. 18, 1903, Bd. xxxv, No. 3. 411 412 Diphtheria Fig. 150.—Bacillus diphtheriz, five hours at 36° C. This shows only solid staining orms. Fig. 152.—Bacillus diphtheria, same cul- ture, twelve hours at 36°C. The bacilli stain faintly at their ends, and in some small granules are seen at the tip of the faintly stained oo Fig. 15 4.—Bacillus diphtheriz, same cul- ture, twenty-four hours at 36° C. This shows clubbed and barred forms as well as granular forms. At the lower part of the field is a paired form which shows the char- acteristic clubbing of the distal ends. (Photomicrographs by Mr. Louis Brown. Fig. 151.—Bacillus diphtheriz, same cul- ture, eight hours at 36°C. This also shows solid forms, many of them with parallel ar- rangement. © %s cs A ., oa eH om t teh: ~ A Ave —, Fig. 153.—Bacillus dicheuentes same cul- ture, fifteen hours at 36° C. The bacilli stain more unevenly and the granules are larger. Z forty- eight hours at 36° This is the same bacillus as in the preceding figures, but from a culture where the colonies were discrete. It shows long filamentous forms. Fig. 155. Bacillus diphtheriz, The magnification is the same in all— X 2000. All of the preparations were made from growth on blood-serum.) (Francis P. Denny, in “Jour. of Med. Research.’ Cultivation | 413 a beginner would certainly fail to recognize them as the same species. The small short forms also stain much more uniformly than the large club-shaped bacilli. Staining —The bacillus can readily be stained with aqueous solutions of the anilin colors, but more characteristically with Léffler’s alkaline methylene blue: Saturated alcoholic solution of methylene blue.......... 30 1:10,000 aqueous solution of caustic potash............ 100 Emery prefers Manson’s borax methylene blue. A stock solu- tion which keeps well is prepared by dissolving 2 grams of meth- ylene blue and 5 grams of borax in too cc. of water. This is diluted with ‘from five to ten times its volume of water for ordinary use. An aqueous solution of dahlia is recommended by Roux. ; The Neisser method of staining the diphtheria bacillus, which met with a very cordial reception, is as follows: The prepared cover-glass is immersed for from two to three seconds in Alcohol (96 per cent.)........... 0000s 20 parts Methylene blue.............. 00.0. c cee cee I part «Distilled waters. ccccc cc ce ee ee ee te ee 950 parts Acetic acid (glacial).......... 2.00. cece cee eee 50 parts Then for three to five seconds in Bismarck: browiccnencusew oesunt aoa teen eee I part Boiling distilled water.................000 000005 Soo parts The true diphtheria bacilli appear brown, with a dark blue body at one or both ends; the pseudo-diphtheria bacilli usually exhibit no polar bodies. Park* found that neither the Neisser nor the Roux stain gave any more information concerning the virulence of the bacilli than the Loffler alkaline methylene blue. The bacilli stain well by Gram’s method, which is excellent for their definition in sections of tissue, though Welch and Abbott found that Weigert’s fibrin method and picrocarmin gave the most beau- tiful results. Cultivation—The diphtheria bacillus grows readily upon all the ordinary media, and is very easy to obtain in pure culture, plates not being necessary. It is purely aérobic. Colonies.—Upon the surface of gelatin plates the colonies attain but a small size and appear to the naked eye as whitish points with smooth contents and regular, though sometimes indented, borders. Under the microscope they appear granular and yellowish-brown, with irregular borders. Upon agar-agar and glycerin agar-agar the colonies are slower to develop, larger, more translucent, without the yellowish-white or china-white color of the blood-serum cultures, and are more or less distinctly divided into a small elevated center * “Bacteriology in Medicine and Surgery,” 1900. 414 Diphtheria and a flat surrounding zone with indented edges, and a radiated appearance. ‘The colonies that develop upon Léffler’s blood-serum mixture are rounded, yellowish-white, good sized and more or less confluent when closely approximated. They are smooth, moist and shining on the surface. They are with difficulty differentiated from those of Bacillus hofmanni, the pseudo-diphtheria bacillus. Gelatin.—The growth in gelatin puncture is scanty, not char- acteristic, and consists of small spheric colonies along the line of inoculation. The gelatin is not liquefied. a b ¢c Fig. 156.—Diphtheria bacilli (from photographs taken by Prof. E. K. Dun- ham, Carnegie Laboratory, New York): a, Pseudobacillus; 6, true bacillus; c¢, pseudobacillus. Agar-agar.—Cultures upon the surface of agar-agar slants are usually meager when contracted with those upon Léffler’s blood- serum mixture, and may be whitish in color. They consist of dis- crete and confluent whitish colonies devoid of differential qualities. The oftener the organism is transplanted to fresh agar-agar, the more luxuriant its growth becomes. The growth is rapid and lux- urlant upon glycérin agar-agar. Bouillon.—When planted in bouillon a distinct, whitish, granular pellicle forms upon the surface of the clear medium. The pellicle appears quite uniform when the tube or flask is undisturbed, but it is so brittle that it at once falls to pieces if disturbed, the minute Cultivation — A415 fragments slowly sedimenting and forming a miniature snow-storm in the flask or tube. The organism at times also causes a diffuse cloudiness of the medium, but, not being motile, soon settles to the bottom in the form of a flocculent precipitate which has a tendency -to cling to the sides of the glass, and leave the bouillon clear. No fermentation occurs in bouillon to which sugar is added, though acids are soon formed by which the growth is checked. If, how- ever, the quantity of sugar be too small to check the growth, the acidity gives place to increasing alkalinity at a later period. Fig. 157.—Bacillus diphtheria; colony twenty-four hours old, upon agar-agar X100 (Frankel and Pfeiffer). Spronck* found that the characteristics of the growth of the diphtheria bacillus in bouillon, as well as the amount of toxin produced, vary according to the amount of glucose in the bouillon. Zinno} found that digested brain added to the culture bouillon greatly facilitated the growth of diphtheria and tetanus bacilli and increased the toxin-production. Blood-serum.—The bacillus grows similarly upon blood-serum and Léffler’s mixture, but more luxuriously upon the latter, where large, creamy-white, discrete and confluent, moist, shining colonies form. The rapidity of the growth which is abundant in twenty- four hours, and the appearances presented are quite characteristic. Léffler has shown that the addition of a small amount of glucose to the culture-medium increases the rapidity of growth, and suggests a ti medium which bears his name—Loffler’s blood-serum mixture: , *“Ann. de PInst. Pasteur,” Oct. 2 ; F . 25, 1895, vol. ix, No. 10, p. 758. t “Centralbl. f. Bakt.,” Jan. 4, 1902, XxxI, No. 2, p. ‘42. are V1 416 Diphtheria This mixture is filled into tubes, coagulated, and sterilized like blood-serum, and is one of the best known media to be used in con- nection with the study of diphtheria. Material from the infected throat can be taken with a swab or platinum loop and spread upon the surface of several successive tubes of Léffler’s blood-serum media. Upon the first a confluent growth of the bacillus usually occurs; but upon the third, scattered cream-white colonies suitable for transplantation can usually be found. The studies of Michel* have shown that the development of the culture is much more luxuriant and rapid when horses’ serum instead of beef or calves’ serum is used. Westbrook suggested that the addition of a small amount of glycerin to the preparation of blood-serum would prevent it from drying so rapidly as usual and would have the added advantage of preventing the growth of certain varieties of bacteria not desired. Dubois + carried out a series of observations upon this question and found that 3 to 5 per cent. of glycerin makes a very valu- able addition, as the diphtheria bacilli grow very rapidly and almost in pure culture upon the blood-serum mixture to which it is added. The blood serum is not liquefied or otherwise visibly changed. Potato.—Upon potato it develops only when the reaction is alkaline. The potato growth is not characteristic. Milk.— Milk is an excellent medium for the cultivation of Bacillus diphtheriae. The milk is not coagulated. Litmus milk is useful for detecting the changes of reaction brought about. Alkalinity, which at first favors the development of the bacillus, is soon replaced by acidity that checks it. When the culture becomes old, the reac- tion may again become strongly alkaline. This variation in reaction seems to depend entirely on the transformation of sugar in the media. Vital Resistance.—As the diphtheria bacillus does not form spores, it possesses very little vital resistance and is delicate in its thermic sensitivity. It grows slowly at 20°C., rapidly at 37°C., and ceases to grow at about 40°C. It is killed when exposed to 58°C. for a few minutes. Besson states that when dried in fragments of false membrane it resists high temperatures and has been found alive after exposure to 100°C. for an hour. Drying quickly destroys it, but if organic matter be present it may remain alive a long time. Roux and Yersin were able to keep the bacilli alive in a piece of dry pseudo-membrane, kept in the dark, for five months. Reyes has demonstrated that in absolutely dry air diphtheria bacilli die in a few hours. Under ordinary conditions their vitality, *“Centralbl. f. Bakt. u. Parasitenk.,” Sept. 24, 1897, Bd. xxu, Nos. 10 and 11. t “Seventeenth Annual Report of the Department of Health’ and Charities,” Indianapolis, Ind., 1907. Metabolic Products 417 when dried on paper, silk, etc., continues for but a few days, though sometimes they can live for several weeks. In sand exposed to a dry atmosphere the bacilli die in five days in the light; in sixteen to eighteen days in the dark. When the sand is exposed toa moist atmosphere, the duration of their vitality is doubled. In fine earth they remained alive seventy-five to one hundred and five days in dry air, and one hundred and twenty days in moist air. The organism is highly susceptible to disinfectantsexc ept when dried in false membrane. Metabolic Products.—The diphtheria bacillus forms acids (lactic acid?) in the presence of dextrose, galactose, levulose, maltose, dextrine and glycerin. It also forms acids in meat-infusion bouillon, probably because of the muscle sugarsit contains. In the absence of - sugars it produces alkalies. It is unable to evolve gas from any carbohydrates. It does not coagulate milk; does not liquefy gelatin or blood-serum. Palmirski and Orlowski* assert that the bacillus produces indol, but only after the third week. Smith,f however, found that when the diphtheria bacillus grew in dextrose-free bouillon no indol was produced. Toxin.—The earliest researches upon the nature of the poisonous products of the diphtheria bacillus seem to have been made in 1887 by Léffler,t who came to the conclusion that they belonged to the enzymes. The credit of removing the bacteria from the culture by filtration through porcelain and the demonstration of the soluble poison in the filtrate belong to Roux and Yersin.§ Toxic bouillon prepared in this manner was found to cause serous effusions into the pleural cavities, acute inflammation of the kidneys, fatty de- generation of the liver, and edema of the tissue into which the injection was made. In some cases palsy subsequently made its appearance, usually in the hind quarters. The effect of the poison was slow and death took place days or weeks after injection, sometimes being preceded by marked emaciation. ‘Temperatures - of 58°C. lessened the activity of the toxin and temperatures of 100°C. destroyed it. It was precipitated by absolute alcohol and mechanically carried down by calcium chlorid. Brieger and Frankell| confirmed the work of Roux and Yersin, and concluded that the poison was a toxalbumin. Tangl** was able to extract the toxin from a fragment of diphtheria pseudo-membrane macerated in water. The nature of the diphtheria toxin has been studied by Ehrlichtt *“Centralbl. f. Bakt. u. Parasitenk.,”’ March, 1895. { “Jour. Exp. Med.,” Sept., 1897, vol. 11, No. 5, p. 546. { “Centralbl. f. Bakt.,” etc., 1887, 11, p. 105. § “Ann. de l’Inst. Pasteur,” 1888-1889. all ‘, Berliner klin. Wochenschrift,” 1890, 11-12. Centralbl. f. Bakt.,” etc., Bd: x1, p. 379. tt “Klinisches Jahrbuch,” 1897. _ 27 418 Diphtheria and found to be extremely complex. As it exists in cultures it is composed of equal parts of toxin and toxoid. Of these, the former is poisonous, the latter harmless for animals—or at least not fatal to them. The toxoids have equal or greater affinity for combining with antitoxin than the toxin and cause confusion in testing the unit value or strength of the antitoxin. In old or heated toxin all of the toxin molecules become changed into toxons or toxoids and the poisonous quality is lost though the power of combining with antitoxin remains. The toxin is extremely poisonous, and a filtered bouillon con- taining it may be fatal to a 300-gram guinea-pig in doses of only 0.0005 cc. It is thought not to be an albuminous substance, as it can be elaborated by the bacilli when grown in non-albuminous urine, or, as suggested by Uschinsky, in non-albuminous solutions whose principal ingredient is asparagin. The toxic value of the cultures is greatest in the second week. This soluble toxin so well known in bouillon cultures is probably only one of the poisonous substances produced by the bacillus. An intracellular, insoluble toxic product seems to have been discovered by Rist,* who found it in the bodies of dried bacilli, and observed that it was not neutralized by the antitoxin. Pathogenesis.—The Bacillus diphtheria is pathogenic for man, monkeys, guinea-pigs, rabbits, dogs, cats, cows, and horses. Spar- rows, pigeons and fowls are susceptible to experimental infection; rats and mice are immune. Spontaneous or natural infection is pretty well limited to man. The effects of artificial experimental infection vary with the avenue of infection, the quantity of culture and its virulence. 1. Subcutaneous inoculation in rabbits and guinea-pigs is isis fatal in from seventy-two hours to five days. The animal suffers some rise of temperature in twelve to twenty-four hours, soon is depressed, weak, loses flesh, remains quiet and dies. At the seat of infection there is a swelling caused by combined edema, hemor- rhage and fibrinous exudation. If the culture be of feeble viru- lence so that death does not occur, this area sloughs, and then heals slowly. 2. Intraperitoneal and Intrapleural Infection.—This is not so serious in its results as might be supposed. Some animals recover from doses that might be fatal under the skin. Death does not occur until after a week or twelve days. Fluid of slightly turbid character with flakes of fibrin is found in the peritoneum. 3. Mucous Membrane Inoculations.—When implanted upon the scarified surfaces of the mucous membranes, the bacillus causes the formation of a fibrinous and necrotic pseudo-membrane. Such con- ditions may recover or death may follow after some days. In all cases the bacilli remain fairly well-localized at or near the * “Soc. de Biol. Paris,” 1903, No. 25. Pathogenesis . 419 seat of inoculation and only rarely invade the blood. Death and illness result from toxemia, not from bacteremia. When examined post-mortem, the liver is found enlarged and sometimes shows minute whitish points, which upon microscopic examination prove to be necrotic areas in which the cells are com- pletely degenerated, and the chromatin of their nuclei scattered about in granular form. Similar necrotic foci, to which attention was first called by Oertel, are present in nearly all the organs in cases of death from diphtheria intoxication. No bacilli are present in these lesions. Welch and Flexner* have shown these foci to be common to numerous intoxications, and not peculiar to diphtheria. The lymphatic glands are usually enlarged, and the adrenals enlarged and hemorrhagic. The kidneys show parenchymatous degeneration. Roux and Yersin found that when the bacilli were introduced into the trachea of animals, a typical pseudo-membrane was formed, and that diphtheritic palsy sometimes followed. Diphtheria in man is characterized by a pseudo-membranous in- flammation of the mucous membranes, particularly of the fauces, though it may occur in the nose, in the mouth, upon the genital organs, or upon wounds. Williamsf has reported a case of diph- theria of the vulva, and Nisot and Bumm have reported cases of puerperal diphtheria from which the bacilli were cultivated. It is in nearly all cases a purely local infection, depending upon the pres- ence and development of the bacilli upon the diseased mucous mem- brane, but is accompanied by a serious intoxication resulting from the absorption from the local lesions of a poisonous metabolic product. of the bacilli. The bacilli are found only in the membranous exuda- tion, and are most plentiful in its older portions. The entrance of the diphtheria bacillus into the internal organs can scarcely be regarded as a frequent occurrence, though metastatic occurrence of the organism with and without associated staphylococci and streptococci, and with and without purulent inflammations have from time to time been reported. Diphtheria bacilli were first found in the heart’s blood, liver, spleen, and kidney, by Frosch.t Kolisko and Paltauf|| had already found them in the spleen, and other observers in various lesions of the deeper tissues and oc- casionally in the organs. In the blood and organs it is commonly associated with Streptococcus pyogenes and sometimes with other bacteria. While present in nearly all of the inflammatory sequel of diphtheria, the Klebs-Léffler bacillus probably has very little in- fluence in producing them, the conditions being almost invariably associated with the pyogenic cocci, either the streptococci or * “Bull. of the Johns Hopkins Hospital,” Aug., 1901. { “Amer. Jour. of Obstet. and Dis. of Women and Children,” Aug., 1898. pee fiir Hygiene,” etc., 1893, x1, Heft 1. || “Wiener klin. Wochenschrift,” 1889. 420 Diphtheria staphylococci. Howard* studied a case of ulcerative endocarditis caused by the diphtheria bacillus, and Pearcet has observed it in 1 case of malignant endocarditis, 19 out of 24 cases of broncho- pneumonia, 1 case of empyema, 16 cases of middle-ear disease, 8 cases of inflammation of the antrum of Highmore, 1 case of in- ‘flammation of the sphenoidal sinuses, 1 case of thrombosis of the lateral sinuses, 2 cases of abscesses of the cervical glands, and in esophagitis, gastritis, vulvo-vaginitis, dermatitis, and conjunctivitis following or associated with diphtheria. A case of septic invasion by the diphtheria bacillus is reported by Ucke,t who gives a synopsis of the literature of similar cases. The disease pursues a variable course. In favorable cases the patient recovers gradually, the pseudo-membrane first disappearing, leaving an inflamed mucous membrane, upon which virulent diph- theria bacilli persist for weeks and sometimes for months. Smith* describes the bacteriologic condition of the throat in diphtheria as follows: ‘The microscope informs us that during the earli- est local manifestations the usual scant miscellaneous bacterial flora of the mucosa is quite suddenly replaced by a rich vege- tation of the easily distinguishable diphtheria bacillus. Frequently no other bacteria are found in the culture-tube. This vegeta- tion continues for a few days, then gradually gives way to another flora of cocci and bacilli, and finally the normal condition is reéstablished.” Associated Bacteria.—Streptococcus pyogenes and Staphylococci pyogenes aureus and albus are, in many cases, found in associa- tion with the diphtheria bacillus, especially when severe lesions of the throat exist. In a series of 234 cases carefully and statistically studied by Blasi and Russo-Travali,|| it was found that in 26 cases of pseudo- membranous angina due to streptococci, staphylococci, colon bacilli, and pneumococci, 2 patients died, the mortality being 3.84 per cent. In 102 cases of pure diphtheria, 28 died, a mortality of 27.45 per cent. Seventy-six cases showed diphtheria bacilli and staph- ylococci; of these, 25, or 32.89 per cent., died. Twenty cases showed the diphtheria bacilli and Streptococcus pyogenes, with 6 deaths—3o per cent. In 7 cases, of which 3, or 43 per cent., were fatal, the diphtheria bacillus was in combination with streptococci and pneumococci. The most dangerous forms met were 3 cases, all fatal, in which the diphtheria bacillus was found in combination with Bacillus coli. In 157 cases of diphtheria and scarlatina studied at the Boston * “Amer. Jour. Med. Sci.,”” Dec., 1894. t “Jour. Boston Soc. of Med. Sci.,”” March, 1808. Re f. Bakt. u. Parasitenk., i original, XLVI, Heft 4, March 10, ee a hoon de I’Inst. Pasteur,” 1896, p. 387. Pathogenesis 421 City Hospital by Pearce,* there were 94 cases of diphtheria, 46 cases of complicated diphtheria (29 with scarlet fever, 11 with measles, and 5 with measles and scarlet fever), and 17 cases of scarlet fever (in 3 of which measles was also present). Of the 94 cases of uncomplicated diphtheria, the Klebs-Liéffler bacilli were present in the heart’s blood in 4, twice alone and twice with streptococci. In g cases the streptococcus occurred alone; in 1 case the pneumococcus occurred alone. In the liver the bacillus was found in 24 cases, alone in 12 and together with the strepto- coccus in 12; the ‘streptococcus occurred in 27 cases, alone in 14, with the Klebs-Léffler bacillus in 12, and with Staphylococcus pyogenes aureus in 1. Staphylococcus pyogenes aureus occurred in 4 cases, alone in 3 and associated with the streptococcus in 1. The pneumococcus occurred alone in 1 case. In ‘the spleen the Klebs-Léffler bacillus occurred eighteen times, fifteen times alone and three times associated with the streptococcus. The streptococcus occurred in 24 cases, alone in 21, associated with the Klebs-Léffler bacillus twice, and with Staphylococcus pyogenes aureus once. Staphylococcus pyogenes occurred twice, once alone and once with the streptococcus. The pneumococcus occurred twice alone. ‘ In the kidney the Klebs-Léffler bacillus occurred in 23 cases, in 15 alone, in 5 associated with the streptococcus, and in 2 with Staphylococcus pyogenes aureus. The streptococcus occurred in 26 cases, in 19 of which it was the only organism present. Staphyl- ococcus pyogenes aureus occurred in 8 cases, in 4 of which it was in pure culture. The pneumococcus occurred four times, three times in pure culture and once with the Klebs-Léffler bacillus. In the 46 cases of complicated diphtheria, the heart’s blood showed pure cultures of the streptococcus nine times and the streptococcus associated with the Klebs-Liffler bacillus once. The diphtheria » bacillus occurred alone once. In the liver, in 10 cases streptococcus occurred alone, in 7 cases associated with the Klebs-Léffler bacillus, and in 3 cases with Staphylococcus pyogenes aureus. The diphtheria bacillus occurred in pure culture-in 5 cases. The spleen contained streptococci only thirteen times and mixed with the diphtheria bacillus twice. The diphtheria bacillus was found in pure culture in 5 cases. The kidney contained pure cultures of streptococci in 10 cases, streptococci associated with diphtheria bacilli five times, and with Staphylococcus pyogenes aureus three times. The diphtheria bacillus occurred alone in 7 cases. Staphylococcus pyogenes aureus and the pneumococcus each alone once, and both together once. “The clinical significance of this general infection with the Klebs- * “Jour. Boston Soc. of Med. Sci.,” March, 1898. 422 Diphtheria Léffler bacillus is not apparent. It occurred generally, but not always, in the gravest cases, or those known as ‘septic’ cases. It is probable that it may be due to a diminished resistance to the tissue-cells, or of the germicidal power of the blood. In this series of fatal cases the number of infections with the streptococcus and with the Klebs-Léffler bacillus was about even, though slightly in favor of the streptococcus.” The mixed infections add to the clinical diphtheria the patho- genic effects of the associated bacteria. The diphtheria bacillus probably begins the process, growing upon the mucous membrane, devitalizing it by its toxin, and producing coagulation-necrosis, Whatever pyogenic germs happen to be present are thus afforded an opportunity to enter the tissues and add suppuration, gangrene, and remote metastatic lesions to the already existing ulceration. Diphtheritic inflammations of the throat are not always accom- panied by the formation of the pseudo-membrane, but in some cases a rapid inflammatory edema in the larynx, without a fibrinous surface coating, may cause fatal suffocation, only a bacteriologic examination revealing the true nature of the disease. Lesions.—The pseudo-membrane characterizing diphtheria con- sists of a combined necrosis of the tissues acted upon by the toxin and coagulation of an inflammatory exudate. When examined histologically it is found that the surface of the mucous membrane is chiefly affected. The superficial layers of cells are embedded in coagulated exudate—fibrin—and show a peculiar hyaline degenera- tion. Sometimes the membrane seems to consist exclusively of hyaline cells; sometimes the fibrin formation is secondary to or subsequent to the hyaline degeneration. Leukocytes caught in the fibrin alsobecomehyaline. From thesuperficial layer the process may descend to the deepest layers, all of the cells being included in the coagulated fibrin and showing more or less hyaline degenera- tion. The walls of the neighboring capillaries also become hyaline, and the necrotic mass forms the diphtheritic membrane. The laminated appearance of the membrane probably depends upon the varying depths affected at different periods, or upon differences in the process by which it has been formed. The pseudo-membrane is continuous with the subjacent tissues by a fibrinous reticulum, and is in consequence removed with difficulty, leaving an abraded surface. When the membrane is divulsed during the course of the disease, it immediately forms anew by the coagulation of the in- flammatory exudate. The coagulation-necrosis seems to depend upon the local effect of the toxin. Morax and Elmassian* found that when strong diphtheria toxin is applied to the conjunctiva of rabbits every three minutes for eight or ten hours, typical diphtheritic changes are produced. *“ Ann, de l’Inst. Pasteur,” 1898, p. 210. Specificity 423 Flexner* has made a study of the minute lesions caused by bacterial toxins and especially of the diphtheria toxin, and Council- man, Mallory, and Pearce, of both gross and minute lesions, that the thorough student should read. Specificity Herman Biggs,t in an interesting discussion of the occurrence of the diphtheria bacillus and its relation to diphtheria, came to the following conclusions: 1. “When the diphtheria bacillus is found in healthy throats, investigation almost always shows that the individuals have been in contact with cases of diphtheria. The presence of the bacillus in the throat, without any lesion, does not, of course, indicate the existence of the disease.” 2. “The simple anginas in which virulent diphtheria bacilli are found are to be regarded from a sanitary standpoint in exactly the same way as the cases of true diphtheria.” 3. “Cases of diphtheria present the ordinary clinical features of diphtheria, and show the Klebs-Léffler bacilli.” 4. “Cases of angina associated with the production of membrane in which no diphtheria bacilli are found might be regarded from a clinical standpoint as diphtheria, but bacteriological examination shows that some other organism than the Klebs-Léffler bacillus is the cause of the process.” Any skepticism of the specificity of the diphtheria bacillus on my own part was dispelled by a somewhat unique experience. Without having been previously exposed to diphtheria while ex- perimenting in the laboratory the author accidentally drew a living virulent culture of the diphtheria bacillus through a pipet into his mouth. Through carelessness no precautions were taken to prevent serious consequences and two days later the throat was filled with typical pseudo-membrane which private and Health Board bacterio- logic examinations showed to contain pure cultures of the Klebs- Léffler bacilli. Some have been led to doubt the specificity of the diphtheria bacillus because of the existence of what is called the pseudo-diph- theria bacillus or bacillus of Hofmann (q.v.). Bomstein§ found that though it was possible to modify the activity of virulent bacilli, and bring back the virulence of non-virulent diphtheria bacilli, it was impossible to make the pseudo-diphtheria bacillus virulent. Denny|| also found that the morphology of the two organ- isms was continually different when they were grown upon the same medium for the same length of time, and that the short pseudo- diphtheria bacillus never showed any tendency to develop into the wo Johns Hopkins Hospital Reports,” vi, 259. } “Diphtheria: A Study of the Bacteriology and Pathology of Two Hundred and Twenty Fatal Cases,” 1gor. t “Amer. Jour. Med. Sci.,” Oct. 1896, vol. xx, No. 4, p. 411. § “Archiv Russes de Path.,” etc., Aug. 31, 1902. : || American Public Health Association, 1902. 424 Diphtheria large clubbed forms characteristic of the true diphtheria organism. The chief points of difference between the bacilli are that the pseudo- diphtheria bacillus, when grown upon blood-serum, is short and stains uniformly; that cultures grown in bouillon develop more rapidly at a temperature of from 20° to 22°C. than those of the true bacillus; and that the pseudo-bacillus is not pathogenic for animals. ; Contagion.—The diphtheria bacilli, being always present in the throats of patients suffering from diphtheria, constitute the element of contagion. The results obtained by Biggs, Park, and Beebe in New York are of great interest. Bacteriologic examinations conducted in connection with the Health Department of New York City show that virulent diphtheria bacilli may be found in the throats of convalescents from diphtheria as long as five weeks after the dis- charge of the membrane and the commencement of recovery, and that they exist not only in the throats of the patients themselves, but also in those of their caretakers, who, while not themselves infected, may be the means of conveying the disease germs from the sick-room to the outer world. Still more extraordinary are the observations of Hewlett and Nolen,* that the bacilli remained in the throats of patients seven, nine, and in one case twenty-three weeks after convalescence. The hygienic importance of this ob- servation must be apparent to all readers, and serves as further evidence why thorough isolation should be practised in connection with the disease. / Neumannft found that virulent diphtheria bacilli may occur in the nose with the production of what seems to be a simple rhinitis as well as a pseudo-membranous rhinitis. Such cases, not being segregated, may easily serve to spread the contagion of the disease. Wesbrook, and Wilson and McDanielt have found it convenient to describe three chief types of the diphtheria bacillus as it occurs in twenty-four-hour-old cultures on Léffler’s blood-serum, sent to the laboratory for diagnosis. The classification places all types in three general groups: (a) granular, (b) barred, and (c) solid or evenly staining forms. Each group is subdivided into types based on the shape and size of the bacilli. A study of variations in the sequence of types in series of cultures derived from clinical cases of diphtheria shows that (a) granular types are usually the most predominant forms at the outset of the disease; (6) the granular types usually give place wholly or in part to barred and solid types shortly before the disappearance of diphtheria-like organisms; (c) solid types, by many observers called ‘“pseudo-diphtheria bacilli,” may cause severe clinical diphtheria. Solid types may sometimes be re- * “Brit. Med. Jour.,” Feb. 1, 1896. { “Centralbl. f. Bakt. u. Parasitenk.,” Jan. 24, 1902, Bd. xxx1, No. 2, p. 41. } “Trans. Assoc. Amer. Phys.,” 1900; Trans. Amer. Public Health Asso. , 1900+ Bacteriologic Diagnosis 425 placed by granular types when convalescence is established and just before the throat is cleared of diphtheria-like bacilli. From these data the writers conclude that it is not safe to base an opinion regarding the maintenance of quarantine upon the bacterioscopic findings independently of the clinica] history of the case. The occurrence of true diphtheria bacilli in the throats of healthy persons has been a stumbling-block to many practitioners unin- formed upon bacteriologic subjects, who fail to account for its _ presence and ulso fail to realize how rare its appearance under such circumstances really is. - Park* found virulent diphtheria bacilli in about 1 per cent. of the healthy throats examined in New York city, but diphtheria was prevalent in the city at the time, and no doubt most of the Fig. 158.—Wesbrook’s types of Bacillus diphtheriz: a, c, d, Granular types; a}, cl, d!, barred types; a, c?, d?, solid types. XX 1500. persons in whose throats they existed had been in contact with cases of diphtheria. He very properly concludes that the members of a household in which a case of diphtheria exists, though they have not the disease, should be regarded as possible sources of danger, until cultures made from their throats show that the bacilli have disappeared. Bacteriologic Diagnosis.—It is impossible to make an accu- rate diagnosis of diphtheria without a bacteriologic examination. Such an examination is now within the power of every physician. All that is required is a swab made by wrapping a little absorbent cotton about the end of a piece of wire and carefully sterilizing it ma test-tube, and a tube of Léffler’s blood-serum-medium, that can *“Report on Bacteriological Investigations and Diagnosis of Diphtheria, from May 4, 1893, to May 4, 1894.” “Scientific Bulletin No. 1,” Health De- partment, city of New York. 426 Diphtheria be bought from almost any modern druggist. The swab is intro- duced into the throat and applied to the false membrane, after which it is carefully smeared over the surface of the blood-serum. The tube thus inoculated is stood away in an incubating oven or otherwise kept at the temperature of 37°C. for twelve hours, then examined. If the diphtheria bacillus be present, a smeary, creamy- white layer with outlying colonies will be present. These colonies, if found by microscopic examination to be made up of diphtheria bacilli, will confirm the diag- nosis of diphtheria. There are very few other bacilli that, grow so rapidly upon Loffler’s mixture, and scarcely any other is found in the throat. When no tubes of the blood-serum mixture are at hand, the swab can be re- turned to its tube after hav- ing been wiped over the throat of the patient, and can be shipped to the nearest laboratory. When an early diagnosis is required, Ohlmacher rec- ommends that the micro- scopic examination of the still invisible growth bemade in five hours. A platinum loop is rubbed over the in- oculated surface; the small a Etec amount of material thus se- portent oath or Seeeteeea, De cured is mixed with distil consisting of a pasteboard box containing Water, spread on a cover- a evap site and a ne no with glass, dried, fixed, stained siced gurface on which to write the D2 ith methylene blue and ex amined. An abundance of the organisms is usually found and valuable time is saved pre- paratory to the use of the antitoxin. Diphtheria Antitoxin——Behring* discovered that the blood of animals rendered immune against diphtheria by inoculation, first with attenuated and then with virulent organisms, contained a neutralizing substance (A nti-kérper) capable of annulling the effects of the bacilli or the toxin when simultaneously or subsequently inoculated into susceptible animals. This substance, held in solu- *“Deutsche med. Wochenschrift,” 1890, Nos. 49 and so; ‘Zeitschrift fir Hygiene,” 1892, x1, 1. Diphtheria Antitoxin 427 tion in the blood-serum of the immunized animals, is the diphtheria antitoxin. For the method of preparing see Antitoxins. The serum may be employed for purposes of prophylaxis or for treatment. Prophylaxis.—The serum can be relied upon for prophylaxis in cases of exposure to diphtheria infection. In most cases a single dose of 1000 units is sufficient for the purpose. The protection thus afforded does not continue longer than about six weeks. The transitory nature ak ik of the immunity afforded by prophylactic aye ha" injections of antitoxin is probably de- pendent upon the fact that the antitoxin is slowly eliminated. Treatment.—Diphtheria antitoxin is al- ways to be administered by the hypo- dermic method at some point where the skin is loose. Some clinicians prefer to inject into the abdominal wall; some, into the tissues of the back. A slightly painful swelling is formed, which usually disap- pears ina short time. Ina few cases sud- den death, with symptoms suggesting ana- | phylaxis (q.v.), has followed the injection. \ | Ehrlich asserts that a dose of 500 units | is valueless for the treatment of diphtheria, | 2000 units being probably an average dose : for an adult and 1000 units fora child. It is far better to err on the side of administer- | ing too much than on that of not enough. Forty thousand units have been adminis- tered to a moribund child with resulting cure. The administration of the remedy | should be repeated in twelve hours if the disease is one or two days old, in six hours Dp if three or four days old, in four hours Fig. 160,—Sterilized if still older. The serum may have to be test-tube and swab for given two, three, four, or even more times, eee ee according to the case. Occasionally there tion (Warren). is an outbreak of local urticaria—rarely general urticaria. Sometimes considerable local erythema results. Fever and pain in the joints (serum disease of von Pirquet) also occur, especially if the patients have been previously treated with horse-serum. ; Diphtheria paralysis is said to be more frequent after the use of antitoxin than in cases treated without it. McFarland* has shown that this is to be expected, as the palsies usually occur after bad cases of the disease, of which a far greater number recover when antitoxin * “Medical Record,” New York, 1897. 428 Diphtheria is used for treatment. The subject has been worked over in an in- teresting manner, from the experimental side, by Rosenau.* An interesting collection of statistics upon the antitoxic treatment of diphtheria in the hospitals of the world has been published by Professor Welch,t who, excluding every possible error in the calcu- lations, ‘‘shows an apparent reduction of case-mortality of 55.8 per cent.” Nothing should so impress the clinician as the necessity of begin- ning the antitoxin treatment early in the disease. Welch’s statistics show that 1115 cases of diphtheria treated in the first three days of the disease yielded a fatality of 8.5 per cent., whereas 546 cases in which the antitoxin was first injected after the third day of the dis- ease yielded a fatality of 27.8 per cent. On the other hand, it can scarcely be said that any time is foo late to begin the serum treatment, for the experiences of Burroughs and McCollum in the Boston City Hospital show that by immediate and repeated administration of very large doses of the serum, ap- parently hopeless cases far advanced in the disease, may often be saved. After the toxin has occasioned destructive organic lesions of the nervous system and in the various organs and tissues of the body, no amount of neutralization can restore the integrity of the parts, and in such cases antitoxin must fail. One disadvantage under which the diphtheria antitoxic serum is administered both for purposes of prophylaxis and treatment, is the inability of the operator to find out what may be the already. existing antitoxin content of the patient’s blood. Though it is cer- tain that existing diphtheria is proof that the patient needs the remedy, it is by no means certain that all normal persons exposed to diphtheria in institutions, etc., require it for prophylactic purposes. Some may already possess enough to defend them and the promiscu- ous administration of the serum to every child in an asylum, may re- sult in sensitizing some to the allergizing effect of the horse-serum without just reason. A means by which some knowledge of the nor- mal diphtheria-toxin neutralizing quality of the blood of a healthy individual can be arrived at, has been devised by Schick, { and is now known as Schick’s reaction. It consists in the intracutaneous ad- ministration of a minute dose of diphtheria toxin. If the patient’s blood contains the neutralizing substance, no reaction takes place; if it contain none, a reddened and tumefied circumscribed area ap- pears. W.H. Park uses one-fiftieth of the L+ dose of diphtheria toxin, injecting it into the skin with a very fine hypodermic needle. Kolmer prefers to use one-fortieth of the L+ dose. The presence of one-thirtieth of a unit of antitoxin in 1 cc. of the patient’s blood pre- * “Bulletin No. 38 of the Hygienic peborslery, U.S. Public Health and Marine Hospital Service,” Washington, D. C., 907. { “Bull. of the Johns Hopkins Hospital, ” July and Aug., 1895. £ “ Miinchener. med. Wochenschrift, 1913, p. 2605. Bacilli Resembling the Diphtheria Bacillus 420 vents the reaction. Kolmer* has also made use of the Schick reac- tion for the important purpose of determining how long the -anti- toxin serum injected into the patient remains and confers immunity. When the reaction reappears, the immunity can be supposed to have disappeared, and the patient again becomes susceptible to the infection. : A very interesting paper by Park} shows the effect of the intro- duction of antitoxin upon the death-rate from diphtheria and the advantages of itsemployment. From it the following table is taken: “Combined statistics of deaths and death-rates from diphtheria and croup in New York, Brooklyn, Boston, Pittsburgh, Philadelphia, Berlin, Cologne, Bres- lau, Dresden, Hamburg, Kénigsberg, Munich, Vienna, London, Liverpool, Glasgow, Paris, and Frankfort: Year Population ee (Rte WOOvscrsaceeas ve 16,526,135 I1,059 66.9 T8QTis sewage ase 17,689,146 12,389 70.0 DEQ Bi aig mca ioe solar 18,330,787 I4,200 77.5 TSOFs oa tesa & ae 18,467,970 15,726 80.4 TOO4 se sui4 banon acetone 19,033,902 15,125 790.9 L895 bac a wrdancaicnc 19,143,188 10,657 55.6 189 Osc sieinsatcelalsint 19,489,682 9,651 49-5 TOF se wawk se NEA S48 19,800,629 8,942 45.2 T8083 50465854 ha00 20,037,918 7,170 35 7 TOO cesetinven cate 20,358,837 7,256 35.6 TQOO. eee na ob ates 20,764,614 6,791 32.7 TQO Ey si raiennovsnat waves 20,874,572 6,104 ; 29.2 1902: iene cindn a ante 21,552,398 5,630 / 26.1 L003 cre eeeewnn ss 21,865,290 5,117 23.4 1004: csxeaceag aus 22,532,848 4,017 21.8 DO iS bicsewape 22,790,000 4,323 Ig.0 BacILLI RESEMBLING THE DIPHTHERIA BACILLUS BacitLus HoFrmMaNni The pseudo-diphtheria bacillus (bacillus of Hofmann-Wellenhof§)— Bacillus pseudo-diphthericus—was first found by Léffler|| in diph- theria pseudo-membranes and in the healthy mouth and pharynx. Ohlmacher has found it with other bacteria in pneumonia; Babes, in gangrene of the lung; and Howard,** in a case of ulcerative endo- carditis not secondary to- diphtheria. Park}{ found that all bacilli with the typical morphology of the diphtheria bacillus, found in the human throat, are virulent Klebs- Léffler bacilli, while forms closely resembling them, but more uniform in size and shape, shorter in length, and of more homo- geneous staining properties with Léffler’s alkaline methylene- blue solution, can with reasonable safety be regarded as pseudo- diphtheria bacilli, especially if it be found that they produce an alka- * “Phila. Pathological Society,” Feb. 11, 1915. + “Journal of the Amer. Med. Assoc.,” Feb. 17, 1912, Lvut, No. 7, p. 453. { Introduction of antitoxin treatment. Wiener klin. Woch.,” 1888, No. 3. [ 1000. specimen and heated until it begins to steam, when the stain is washed off in a 20 per cent. solution of crystals of sulphate of copper. The preparation is then dried and mounted in balsam. Hiss finds this stain a useful aid in differentiating the pneumo- coccus from the streptococcus, with which it is easily confounded if the capsules are not distinct, and to which it is probably closely related. Isolation.—When desired for purposes of study, the pneumococcus may be obtained. by inoculating white mice with pneumonic sputum and recovering the organisms from the heart’s blood, or it may be obtained from the rusty sputum of pneumonia by the method em- ployed by Kitasato for securing tubercle bacilli from sputum: A mouthful of fresh sputum is washed in several changes of sterile * Abstract, “Centralbl. f. Bakt. u. Parasitenk.,”’ Bd. xxx1, No. 10, p. 302, March 24, 1902. More complete details appear in a later paper in the “Journal of Experimental Medicine,” v1, p. 338. Cultivation 447 water to free it from the bacteria of the mouth and pharynx, care- fully separated, and a minute portion from the center transferred to an appropriate culture-medium. Buerger,* in conducting a research upon pneumococcus and allied organisms with reference to their occurrence in the human mouth, under the auspices of the Rockefeller Institute, used a 2 per cent. glucose-agar of a neutral, or, at most, 0.5 per cent. phenolphthalein acid titer. ; “The medium was usually made from meat infusion and contained 1.5 to 2 per cent. peptone and 2.4 per cent. agar. Stock plates of these media (serum- agar and 2 per cent. glucose-serum-agar) were poured. The agar or glucose- agar was melted in large tubes and allowed to cool down to a temperature below the coagulation point of the serum. One-third volume of rich albuminous ascitic fluid was added, and the resulting media poured into Petri plates. These were tested by incubation and stored in the ice-chest ready for use. . . . “The plan finally adopted [for inoculating the plates] was as follows: A swab taken from the mouth was thoroughly shaken in a tube of neutral bouillon. From this primary tube, dilutions in bouillon with four, six, and eight loops may be made. A small portion of the dilute mixture was poured at.a point near the periphery of the prepared plates. By a slight tilting motion the fluid was carefully distributed over the whole surface of the plates. Care must be taken to avoid an excess of fluid. It was found that plates made in this way gave a sufficiently thick and discrete distribution of surface colonies.” Cultivation.—The organism grows upon all the culture-media ex- cept potato, but only between the temperature extremes of 24° and 42°C., the best development being at about 37°C. The growth is always meager, probably because of the metabolic formation. of ‘formic acid. The addition of alkali to the culture-medium favors the growth of the pneumococcus by neutralizing this acid.. Hiss and Zinsser} advise that the culture-media used for the pneumococcus be made with 3 to 4 per cent. of peptone. Colonies.—The colonies which develop at 24°C. upon gelatin plates (15 per cent. of gelatin should be used to prevent melting at the temperature required) are described as small, round, circum- scribed, finely granular white points which grow slowly, never attain any considerable size, and do not liquefy the gelatin. If agar-agar be used instead of gelatin, and the plates kept at the temperature of the body, the colonies appear transparent, delicate, and dewdrop-like, scarcely visible to the naked eye, but under the microscope appear distinctly granular, a dark center being sur- rounded by a paler marginal zone. Upon the medium recommended by Buerger for isolating the pneumococcus, the colonies appear in from eighteen to twenty-four hours, the surface colonies being circular and disk-like. When viewed from above, the surface appears glassy with a depressed center. When viewed from the side or by transmitted light, they appear as distinct milky rings with a transparent center. This * “Tour, Exp. Med.,” Aug. 25, 1905, vil, No. 5. t “Text-book of Bacteriology,” 1910, p. 356. 448 é Pneumonia “ring type” is regarded as characteristic and enables the organism to be separated without difficulty from the streptococcus. Gelatin Punctures.—In gelatin puncture cultures, made with 15 instead of the usual ro per cent. of gelatin, the growth takes place along the entire puncture in the form of minute whitish gran- ules distinctly separated from one another. The growth in gelatin is always meager. The medium is not liquefied. Agar-agar and Blood-serum.—Upon agar-agar and blood-serum the growth consists of minute, transparent, semi-confluent, colorless, dewdrop-like colonies. The medium is not liquefied. Upon glycerin agar-agar the growth is more luxuriant. The addition of a very small percentage of blood-serum facilitates growth. Bouillon.—In bouillon the organisms grow well, slightly clouding the medium. With the death of the organisms and their sedimenta- tion, the medium clears again after a few days. Milk.—Milk is an appropriate culture-medium, its casein being coagulated. Alkaline litmus milk is slowly acidified. Potato.—The pneumococcus does not grow upon potato.* Vital Resistance.—The organism usually dies after a few days of artificial cultivation, and so must be transplanted every three or four days. In rabbit’s blood, in sealed tubés kept cold, it can some- times be kept alive for several weeks. Hiss and Zinssert find that when the organism is planted in “calcium-carbonate-infusion broth” and kept in the ice-chest, the cultures often remain alive for several months. Bordoni-Uffreduzzit found that when pneumococci were dried in sputum attached to clothing, and were exposed freely to the light and air, they retained their virulence for rabbits for from nine- teen to ninety-five days. Direct sunlight destroyed their virulence in twelve hours. Guarniere§ found that dried blood containing pneumococci remained virulent for months. The pneumococcus is destroyed in ten minutes by a temperature of 52°C. It is highly sensitive to all disinfectants, weak solutions quickly killing it. ; Metabolic Products.—Hiss|| found that the pneumococcus pro- duces acid from monosaccharids, disaccharids, and such complex saccharids as dextrin, glycogen, starch, and inulin. The fermenta- tion of inulin by pneumococci is a most important means of differentiating it from streptococci. Toxic Products.—Nothing definite is known about the metabolic toxic products of the pneumococcus. Auld** found that if a thin layer of prepared chalk were placed * Ortmann asserts that the pneumococcus can be grown on potato at 37°C, but this is not generally admitted. The usual acid reaction of potato makes it an unsuitable culture-medium. T Loc. cit. / t “Arch. p. 1. Sc. Med.,” 1891, xv. ; “Atti della R. Acad. Med. di Roma,” 1888, Iv. “ Jour. Exp. Med.,” vit, No. 5, Aug. 25, 1905. ** “Brit. Med. Jour.” Jan. 20, 1900. : Pathogenesis 449 upon the bottom of the culture-glass, it neutralized the lactic acid produced by the pneumococcus, and enabled it to grow better and produce much stronger toxin. Macfadyen* found that by freezing cultures of the pneumococcus with liquid air, destroying them by trituration in the frozen state and then extracting the frag- ments with 1 : 1000 caustic potash solution, a toxin whose activity corresponded fairly well with the virulence of the culture could be secured. This toxin killed rabbits and guinea-pigs in doses varying from 0.5 to I cc. It is undoubtedly an endotoxin that is liberated from the bodies of the pneumococci as they undergo autolysis or are dissolved by the enzymic action of the body juices or the cells. The toxin liberated by autolysis has been carefully studied by Rosenow,f who “finds it soluble in ether. It is formed during retrogressive changes in the pneumococci. Heating the clear autolysate to 60°C. for twenty minutes destroys it, while toxic pneumococcus suspensions remain toxic even after boiling. Hydrochloric acid in weak solutions de- stroys the toxicity of pneumococcus autolysates. The toxic sub- stance is absorbed by blood charcoal from which it can again be obtained by shaking with ether. Autolyzed virulent pneumococci and non-virulent pneumonia diminish the toxicity slightly while unautolyzed virulent pneumococci increase it. The toxic sub- stance is probably a base which contains amino groups of nitrogen. Indications have been obtained showing that during pneumococcus infections toxic substances are produced that do not call forth any immunizing response.” Rosenowt found that the autolysate con- tained a proteolytic enzyme. He also found§ that it was capable of producing, in dogs, symptoms strikingly like anaphylaxis, with a striking drop in the blood pressure, pronounced hemorrhages, marked depression of respiration, extreme cyanosis and the pres- ence of CO, in the stomach. Pathogenesis.—If a small quantity of a pure culture of the viru- lent organisni be introduced into a mouse, rabbit, or guinea-pig, the animal dies in one or two days. Exactly the same result can be ob- tained by the introduction of a piece of the lung-tissue from croupous pneumonia, by the introduction of some of the rusty sputum, and frequently by the introduction of human saliva. Postmortem ex- amination of infected animals shows an inflammatory change at the ' point of subcutaneous inoculation, with a fibrinous exudate similar to that succeeding subcutaneous inoculation with the diphtheria bacillus. At times, and especially in dogs, a little pus may be found. The spleen is enlarged, firm, and red-brown. The blood with which the cavities of the heart are filled is firmly coagulated, and, like that in other organs of the body, contains large numbers of the bacteria, * Tbid., 1906, 11. : t“Journal of Infectious Diseases,” 1912, X. 94, 235. t“Journal of Infectious Diseases,” 1912, X. 287. § Ibid., p. 480. 29 450 Pneumonia most of which exhibit a lanceolate form and have distinct capsules. The disease is thus shown to be a bacteremia unassociated with conspicuous tissue changes. In such cases the lungs show no consolidation. Even if the in- oculation be made by a hypodermic needle plunged through the breast-wall into the pulmonary tissue, pneumonia rarely results. Gamaléia* reported that pneumonic consolidation of the lungs of Fig. 170.—Lung of a child, showing the appearance of the organ in the stage of red hepatization of croupous pneumonia. |The pneumonia has been preceded’ by chronic pleuritis, which accounts for the thickened fibrous trabecule extend- ing into the tissue, and which may have had something to do with the peculiarly prominent appearance of the bronchioles throughout the lung. dogs and sheep could be brought about by injecting the pneumococ- cus through the chest-wall into the lung. Tchistowitsch{ stated that by intratracheal injections of cultures into dogs he succeeded in producing in 7 out of 19 experiments typical pneumonic lesions. Montif claimed to have found that a characteristic croupous pneu- *“ Ann, de l’Inst. Pasteur,” 1888, 11, 440. { Ibid., 1890, 111, 285. } “Zeitschrift fiir Hygiene,” etc., 1892, x1, 387. Pathogenesis 451 monia results from the injection of cultures into the trachea of sus- ceptible animals. A very interesting review of the literature of the experimental aspects of the subject, embracing 198 references, will be found in Wadsworth’s paper upon “‘ Experimental Studies on the Etiology of Acute Pneumonitis.’’* The final proof that true pulmonary consolidation, i.e., pneumonia, can be produced experimentally by cultures of the pneumococcus is to be found in a paper byLamarand Meltzer.{ Theseinvestigators etherized dogs, kept the mouth open by means of a large wooden gag, drew the tongue forward by means of hemostatic forceps, and then, seizing the median glosso-epiglottic fold, pulled it forward so that the posterior aspect of the epi- glottis presented an inclined plane. Into this concavity one end of a tube is placed. Under the protection of the left index- finger the tube was directed into the larynx and pushed down slowly and gently through the trachea until a resistance was met with. The inner end of the tube was then found to engage in a bronchus—usually the right bronchus. A pipette containing a liquid culture of the pneumococcus was next attached to the external end of the tube, and by means of a syringe the culture (about 6 cc.) was injected into the bronchus. The syringe was then removed, the piston withdrawn, and the syringe again attached to the pipette. By the injection of air the culture was driven deeper into the bronchi. The tube was then clamped and withdrawn and the animal released. By these means experimental pneumonia, with the typical consolida- tion and lobar distribution, was produced in 42 successive cases. The course of the inflammatory disturbance thus produced was rapid, andin one case nearly complete consolidation had occurred in seven hours. Lesions.—The lesions of .croupous pneumonia of man are almost too well known to need description. The distribution of the disease conforms more or less perfectly to the divisions of the lung into lobes, one or more lobes being affected. An entire lung may be affected, though, as a rule, the apex escapes consolidation and is simply congested. The invaded portion of the lung is supposed to pass through a succession of stages clinically described as (1) con- gestion, (2) red hepatization, (3) gray hepatization, and (4) resolu- tion. In the first stage bloody serum is poured out into the air-cells, filling them with a viscid reddish exudate. In. the second stage this coagulates so that the tissue becomes solid, airless, and approxi- mately like liver tissue in appearance. The third stage is charac- terized by dissolution of the erythrocytes and invasion of the diseased air-cells by leukocytes, so that the color of the tissue changes from ted to gray. At the same time the coagulated exudate begins to soften and leave the air-cells by the natural passages, and the stage of resolution begins. : Jour. Amer. Med. Sciences,” 1904, Cxxvil, p. 851. t “Jour. Exp. Med.,” 1912, xv, No. 2, p. 133. 452 Pneumonia The pneumococci, though present in enormous numbers in the pulmonary lesions, are not confined to them. In practically all cases pneumonia is a blood infection (bacteremia) as well as a pul- monary infection. It is through the blood infection that many of the complications and sequele of the disease are brought about. The pneumococcus is not infréquently discovered in diseased con- ditions other than croupous pneumonia; thus, Foa, Bordoni-Uffre- duzzi, and others found it in cerebro-spinal meningitis; Frinkel, in pleuritis; Weichselbaum, in peritonitis; Banti, in pericarditis; numer- ous observers, in acute abscesses; Gabbi isolated it from a case of suppurative tonsillitis; Axenfeld observed an epidemic of conjunc- tivitis caused by it; Zaufal, Levy, and Schréder and Netter have been able to demonstrate it in the pus of otitis media, and Foulerton and Bonney* isolated it from a case of primary infection of the puerperal uterus. It has also been found in arthritis following pneu- monia, and in primary arthritis without previous pneumonia by Howard.f Interesting statistics concerning the relative frequency of pneumo- coccus infections in adults given by Netter} are as follows: PREWMONI Ass 25666 sigs 8 ok Guay Hed Wie bad dee bed wees s 65.95 Broncho-pneumonia............ 0.000 cece eee eae 15.85 IMGT BIUS) rosie die 8 Bee ay senees Wentaie x tasede satan cae ee seca dh cea 13.00 FEM PY CMAs ssosinca st aedan each w arta SR es a em RI OS 8.53 Ouitis Medias sas clin ais nee des sew slalerobnweie naa date es 2.44 Pndocarditis, seas vas wand adadss a wig MAME Amd AeA EPA OR I.22 Hepatic abscesses o's feaue vex noe seer ade Peea ae enas 1.22 In 46 consecutive pneumococcus infections of children he found: Otitiswtiedia:) ss): asians anienvedhs os amber ee eees 29 Broncho-pneumonia........... 0000: cece eee ee eeeeeeee I2 Meningitis: ses sve s-dcivdanc nanan snnies ceeG: decane ecasaune doh ohio 2 Pheu Onilaies 2.5 acs caotseqrs oe eayhaiaa Kinde SAA Wee a ee mae I MPIC UTS YS cis Si Sisysrie soa ueuhsiuge due aceon me caetataet edee enendreee I Periearditisy 39 cosnes crenanans Gentes © celine di wdels See Padi aidiay I Susceptibility—Not all animals are equally susceptible to the action of the pneumococcus. Mice and rabbits are highly sensitive; dogs, guinea-pigs, cats, andrats aremuch lesssusceptible, though they may also succumb to the inoculation of large doses. Specificity——The etiologic relationship of the pneumococcus to pneumonia is based chiefly upon the frequency of its presence in croupous pneumonia. Netter§ found it 82 times in 82 autopsies upon such cases; Klemperer, 21 times out of 21 cases studied by puncturing the lung with a hypodermic syringe. Weichselbaum ob- tained it in 94 out of 129 cases; Wolf, in 66 out of 70; and Pierce, in 110 out of 121 cases. In about 5 per cent. of the cases it remains localized in the respiratory apparatus; in gs per cent., it invades the * “Trans. Obstet. Soc. of London,” 1903, part 11, p. 128. + “Johns Hopkins Hospital Bulletin,” Nov., 1903. I“ Compte-rendu,” 1889. : § “Compte-rendu,” 1889. Specificity 453 blood. An interesting paper upon this subject has been written by E. C. Rosenow.* The conditions under which it enters the lung to produce pneu- monia are not known. It is probable that some systemic depravity is necessary to establish susceptibility, and in support of this view we may point out that pneumonia is very frequent, and exceptionally severe and fatal, among drunkards, and that it is the most frequent cause of death among the aged. Whether, however, any particular form of vital depression is necessary to predispose to the disease, further study will be required to tell. Virulence.—Pneumococci vary greatly in virulence, and rapidly lose this quality in artificial culture. When it is desired to maintain or increase the virulence, a culture must be frequently passed through animals. Washbourn found, however, that a pneumococcus isolated Fig. 171.—Diplococcus pneumonie. Colony twenty-four hours old upon gelatin. XX 100 (Frankel and Pfeiffer). from pneumonic sputum and passed through one mouse and nine rabbits developed a permanent virulence when kept on agar-agar so made that it was not heated beyond 100°C., and alkalinized 4 cc. of normal caustic soda solution to each liter beyond the neutral point determined with rosolic acid. The agar-agar is first streaked with sterile rabbit’s blood, then inoculated. The cultures are kept at 37.5°C. Ordinarily pneumococci seem unable to accommodate themselves to a purely saprophytic life, and unless continually trans- planted to new media die in a week or two, sometimes sooner. Lambert found, however, that in Marmorek’s mixture (bouillon 2 parts and ascitic or pleuritic fluid 1 part) the organisms would some- times remain alive as long as eight months, preserving their virulence during the entire time. * : . “Jour. Infectious Diseases,” 1904, I, p. 280. 454 Pneumonia Virulence can also be retained for a considerable time by keeping the organisms in the blood from an infected rabbit, hermetically sealed in a glass tube, on ice. Bacteriologic Diagnosis.—It is usually unnecessary to call upon the bacteriologist to assist in making the diagnosis of pneumonia. If, for any reason it be considered necessary, three means are available: 1, the blood culture; 2, the inoculation of animals with the expectoration; 3, the cultivation of the organism from the expectoration. © 1. To make the blood culture, the elbow is encircled with a band, the skin washed and after an application of iodine has been made, a hollow needle is introduced into one of the distended veins, and the blood permitted to drop into a small flask or tube of appropriate media. 2. To inoculate an animal with the sputum, or with fluid drawn from the lung or pleura. A white mouse or a rabbit can be selected as suitable. Both animals are so susceptible that the introduction of one drop beneath the skin is usually fatal in twenty-four to forty- eight hours. Caution must be exercised in using this means of diagnosis, how- ever, as the pneumococcus sometimes occurs in normal saliva, and is a common associated organism in tuberculosis and other respiratory diseases. 3. The recovery of the organism from the sputum can be accom- plished by stroking appropriate media with a platinum wire dipped in the sputum. ‘The characteristic colonies can be picked up and transplanted as soon as they appear. Identification of the Organism.—Wadsworth* has been able to show that agglutination reactions can be obtained by concentrating the pneumococci in isotonic solution and adding the serum. The method does not seem easily applicable for diagnosis. Neufeld and Wadswortht have also found that when rabbit’s bile is added to a pneumococcus culture so as to produce lysis of the organisms, the ad- dition of pneumococcus-immune serum to the clear fluid so obtained results in a specific precipitation. This seems to have little practical importance, however, for purposes of diagnosis. It is, however, of some importance in assisting in the recognition of the pneumococcus and differentiating it from the streptococcus, for when the latter organisms are similarly treated no precipitate takes place. - Buerger§ found that all pneumococci, irrespective of source, were agglutinated by pneumococcus-immune serum, that such serum was capable of agglutinating various pyogenic streptococci, certain atypical organisms, and certain strains of Streptococcus mucosus capsulatus. The sera of pneumonia patients varies in its power to * “Tour. Med. Research,” 1904, x, p. 228. +“Zetschrift fiir Hygiene,’”’ 1902, x1. t Loc. cit. § “Jour. Exp. Med.,” Aug. 25, 1905, vil, No. 5. Immune Serum A455 agglutinate different pneumococci; some strains were aggluti- nated, others not. The sera of normal individuals and of normal rabbits possess no agglutinating power for pneumococci, the atypical organisms, certain streptococci, or Streptococcus mucosus capsulatus. As pneumococci sometimes grow in chains instead of in pairs, and as the capsules are not always more distinct than the capsules that sometimes surround streptococci, it may be necessary to resort to special methods of cultivation for the final identification of the or- ganism. One of the first to be recommended is the use of the blood- agar plate, to which reference has been made in the section upon Streptococcus pyogenes. A second important method, and one that not only differentiates the pneumococcus from the streptococcus, but from the common organisms of similar morphology that infect the mouth, is the inulin- serum water fermentation test of Hiss.* In using this medium, Ruedigert found it best prepared as follows: Dissolve 5 gm. of NaCl, . 20 gm. of Witte’s peptone, and 20 gm. of pure inulin in tooo cc. of distilled water. Add 20 cc. of a 5 per cent. solution of pure litmus, and tube, putting 2 cc. of the mixture into each tube, and sterilize in the autoclave. After sterilization add (with a sterile pipet) 2 cc. of sterile, heated ascitic fluid, or, preferably, heated beef-serum, to each tube, and incubate twenty-four hours before using. Great care must be taken not to use.ascitic fluid that contains fermentable carbohydrates. Each lot must be tested with some strongly fer- mentative bacterium, and the absence of fermentable carbohydrates proved. Ruediger prefers this preparation to the original solution of Hiss because he found that some pneumococci would not grow on the latter. Fermentation of the inulin is regarded as character- istic of the pneumococcus. The pneumococcus produces red colonies upon litmus-inulin-agar plates, which makes their use desirable when pneumococci are to be isolated from saliva, throat secretions, or other material in which similar appearing organisms are apt to occur. Ruediger found no other mouth bacteria that produced red colonies on these plates. Immunity.—Pneumonia is peculiar in that the disease in human beings terminates by crisis as though from some source a supply of antitoxin or other immunizing agent was suddenly liberated, but unfortunately also in that recovery is followed by immunity of such brief duration as to permit the occurrence of frequent relapses. It 1s also well known that many cases show a subsequent predisposition to fresh attacks of the disease. Immune Serum.—G. and F. Klemperer have shown that the serum of rabbits immunized against the pneumococcus protects : “Jour. Amer. Med. Assoc.,” 1906, vol. XLVII, p. 1171. { Tour, of Exp. Med.,” 1905, vol. vi, p. 317. ¢“ Berliner klin. Wochenschrift,” 1891, Nos. 34 and 35. 456 Pneumonia animals infected with virulent cultures. When applied to human medicine, the serum failed to do good. The treatment of pneumonia by the injection of blood-serum from convalescent patients, tried by Hughes and Carter,* has been abandoned as useless and dangerous. Antipneumococcic sera have been experimentally investigated by De Renzi,{ Washbourn,t and Pane.§ Washbourn prepared an antipneumococcus serum that protected rabbits, against ten times the fatal dose of ‘live pneumococci, in doses of 0.3 cc. .In general, the lines upon which he oper- ated were those of Behring, Marmorek’s work with the streptococcus furnishing most of the details. Two cases of human pneumonia seem to have derived some benefit from large doses of this serum. The sera of Pane and De Renzi were not so powerful as those of Washbourn, requiring about 1 cc. to protect a rabbit. McFarland and Lincoln|| succeeded in immunizing a horse against large doses of a virulent culture of the pneumococcus, and obtained a serum of which 0.5 to 0.25 cc. protected rabbits from many times the fatal dose. The experiments by Passler** showed some gain over the earlier work. The antipneumococcic sera thus far produced have given disap- pointing results in clinical application. A leukocytic extract prepared by Hiss and Zinsserft from an aleuronat exudation in the rabbit’s pleura has led to results suf- ficiently encouraging in the treatment of pneumonia in man to war- rant further investigation along similar lines. Rosenowft found that pneumococci suspended in sodium chlorid solutions autolyse rapidly. By means of this autolysis it is possible to separate, at least to a large degree, the toxic from the antigenic parts of the pneumococcus, as the toxic part goes into solution. The injection of the non-toxic and, as it appears, antigenic portion—auto- lyzed pneumococci—causes a marked increase in the immunity curve as measured by the specific increase in pneumococcus opsonin. The injection of such autolyzed pneumococci into 25 patients with lobar pneumonia seemed to have a marked beneficial effect. Sanitation.—Pneumonia is undoubtedly a transmissible disease. Exactly how infection takes place is not known, but seeing that the infectious agent is in the respiratory tract, from which it is easily discharged into the atmosphere during cough, etc., and the facility * “Therapeutic Gazette,” Oct. 15, 1892. ft “Il Policlinico,” Oct. 31, 1896, Supplement. t “Brit. Med. Jour.,” Feb. 27, 1897, p. 510. § “Centralbl. f. Bakt. u. Parasitenk.,” May 29,1897, xxI, 17 and 18, p. 664. || “Jour. Amer. Med. Assoc.,” Dec. 16, 1899, p. 1534. ** “Deutsches Archiv fiir klin. Med.,” Bd. 1905; Lxxxu1, Nos. 3, 4, “Jour. Amer. Med. Assoc.,” May 13, 1905, p. 1538. : tt “Jour. Med. Research,” 1908, XIx, 323. i “Jour. Amer. Med. Assoc.,” June ‘10, tiv, No. 24, p. 1943. Bacillus Capsulatus Mucosus 457 with which it can then be inhaled by those nearby, it seems justifiable to conclude that the primary entrance of the organism into the body is through the respiratory tract. Wood* has shown that “the organ- isms in the sputum do not remain long in suspension and die off rapidly under the action of light and desiccation. In sunlight or diffuse daylight the bacteria in such powder die within an hour, and in about four hours if kept in the dark. The danger of infection from powdered sputum may, therefore, be avoided by ample illu- mination and ventilation of the sick-room in order to destroy or dilute the bacteria, and by the avoidance of dry sweeping or dusting. Articles which may be contaminated and which cannot be cleaned by cloths dampened in a suitable disinfectant should be removed from the patient’s vicinity. Pneumococcus (FRIEDLANDER)—BACTERIUM PNEUMONLE (ZopFrt)—Bacittus CapsuLatus Mucosus (Fascutnef) General Characteristics—An encapsulated, non-motile, non-flagellated, non-sporogenous, non-liquefying, aérobic and optionally anaérobic, non-chromo- genic, aérogenic and pathogenic organism, staining by ordinary methods but not by Gram’s method. This organism was discovered by Friedlinder§ in 1883 in the pulmonary exudate from a case of croupous pneumonia, and, being thought by its discoverer to be the cause of that disease, was called the pneumococcus, and later the pueumobacillus. The grounds upon which the specificity of the organism was supposed to depend were soon found to be insufficient, and the organism of Friedlander is at present looked upon as one whose presence in the lung is, in most cases, unimportant, though it is sometimes associated with and is probably the cause of a special form of pneumonia, which, ac- cording to Stuhlern,|| is clinically atypical and commonly fatal. Frankel points out that Friedlander’s error in supposing his organism to be the chief parasite in pneumonia depended upon the fact that . his studies were made by the plate method, which permitted the dis- covery of this bacillus to be made more easily than that of the slowly growing and more delicate pneumococcus. In the light of present knowledge Friedlander’s bacillus must be looked upon as the type of @ group of organisms varying among themselves in many minor particulars. ; Distribution.—The organism is sometimes found in normal saliva; it Is a common parasite of the respiratory apparatus; not infrequently occurs in purulent accumulations; is occasionally found in feces, and sometimes occurs under external saprophytic conditions. Thus it is probably identical with the “capsulated canal-water bacillus” by Ke Jour. Exp. Med.,” Aug. 25, 1905, vit, No. . 624. t “Spaltpilze,” 1885, p. 66. at ee tence. f. Bakt.,” 1892, etc., XII, p. 304. _Fortshritte der Medizin,” 1883, 22, 715. ll Centralbl. £. Bakt.,” etc. (Originale), July 21, 1904, Bd. xxxv1, No. 4, p. 493- 458 . Pneumonia Mori,* and may belong to the same group in which we find Bacillus aérogenes capsulatus. Morphology.—Though usually distinctly bacillary in form, the organism is of variable length and when paired sometimes bears a close resemblance to the pneumococcusof Frankel and Weichselbaum. It measures 0.5 to 1.5 w in breadth and 0.6 to 0.5 w in length. It frequently occurs in chains of four or more elements and occasionally appears elongated. It is these variations in form that have led to the description of the organism by different writers as a coccus, a bacterium, and a bacillus. It is commonly surrounded by a distinct transparent capsule, hence its name ‘“‘capsule bacillus” and Bacillus capsulatus mucosus. The organism is non-motile, has no spores, and no flagella. It stains well with the ordinary anilin dyes, but does not retain the color when stained by Gram’s method. Fig. 172.—Bacterium pneumonie (modified after Migula). Cultivation.—Colonies.—If pneumonic exudate be mixed with gelatin and poured upon plates, small white spheric colonies appear at the end of twenty-four hours, and spread out upon the surface of the gelatin to form whitish masses of a considerable size. Under the microscope these colonies appear irregular in outline and somewhat granular. The gelatin is not liquefied. Bouillon.—There is nothing characteristic about the bouillon cultures of Friedlander’s bacillus. The medium is diffusely clouded. A pellicle usually forms on the surface and a viscid sediment soon accumulates. Gelatin Puncture.—When a colony is transferred to a gelatin puncture culture, a luxuriant growth occurs. Upon the surface a somewhat elevated, rounded white mass is formed, and in the track * “Zeitschrift fiir Hygiene,” 1888, rv, p. 53. Bacillus Capsulatus Mucosus 459 of the wire innumerable little colonies spring up and become con- fluent, so that a ‘‘nail-growth” results. No liquefaction of the gelatin occurs. Gas bub- bles not infrequently appear in the wire track. The cultures sometimes become brown in color when old. Agar-agar.—Upon the surface of agar- agar at ordinary temperatures a luxuriant white or brownish-yellow, smeary, viscid, circumscribed growth occurs. Blood-serum.—The blood-serum growth is similar to that upon agar. Potato.—Upon potato the growth is lux- uriant, quickly covering the entire surface with a thick yellowish-white layer, which sometimes contains bubbles of gas. Milk is not coagulated as a rule. milk is reddened. Vital Resistance.—The bacillus grows at a temperature as low as 16°C., and, accord- ing to Sternberg, has a thermal death-point of 56°C. Metabolic Products.—Friedlainder’s ba- cillus ferments nearly all the sugars, with the evolution of much gas. It generates alcohol, acetic and other acids, and both CO.and H. According to the best authori- ties the organism does not form indol. There is, however, some difference of opin- ion upon the subject. Perkins* divides the organisms of this group into three chief types according to their reactions toward carbohydrates: I. Bacillus aérogenes type which fer- ment all carbohydrates, with the formation of gas. II. Bacillus pneumonie (Friedlander) type which ferment all carbohy- drates except lactose, with forma- tion of gas. ITI. Bacillus lactis aérogenes type which ferment all carbohydrates except saccharose, with formation of gas. Pathogenesis.—Friedlander found con- siderable difficulty in producing pathogenic Litmus Fig. 173.—Friedlan- der’s | pneumobacillus; gelatin stab culture, showing the typical nail-head appearance and the formation of gas bubbles, not always present (Curtis). changes by the injection of his bacillus into the lower animals. * “Jour. of Infect. Dis.,” 1904, 1, No. 2, p. 241+ 460 Pneumonia Rabbits and guinea-pigs were immune to its action, and the only important pathogenic effects that Friedlander observed occurred in mice, into whose lungs and pleura he injected the cultures, with resulting inflammation. : That Friedlinder’s bacillus may be the cause of true lobar pneu- monia there can be no room for doubt after the demonstrations of Lamar and Meltzer,* who found that its experimental introduction into the bronchi of dogs was followed by true lobar pneumonia. The lesions in these dogs, like those in human beings, were paler in color, the lung tissue less friable, and the exudate more viscid than those caused by the pneumococcus. Pneumonia in man, caused by Bacillus mucosus capsulatus, is atypical clinically, very severe, and often fatal. Curry} found Friedlander’s bacillus in association with the pneumococcus in acute lobar pneumonia; in association with the diphtheria bacillus in otitis media associated with croup- ous pneumonia; and in the throat in diphtheria. In pure culture it was obtained from vegetations upon the valves of the heart in a case of acute endocarditis with gangrene of the lung; from the middle ear, in a case of fracture of the skull with otitis media; and from the throat in a case of tonsillitis. Zinsser has twice cultivated Friedlinder’s bacillus from inflamed tonsils in children. Abelf cultivated it from the discharges of fetid ozena, and sup- posed it to be the specific cause. Occasionally Friedlinder’s bacillus bears an important relation- ship to lobular or catarrhal pneumonia, an interesting case having been studied by Smith.§ The histologic changes in the lung were remarkable in that the ‘‘alveolar spaces of the consolidated areas were dilated and for the most part filled with the capsule bacilli.” In some alveoli there seemed to be pure cultures of the bacilli; others contained red and white blood-corpuscles; in some there was a little fibrin. The bacillus obtained from this case, when injected into the peritoneal cavity of guinea-pigs, produced death in eleven hours. The peritoneal cavity after death contained a large amount of thick, slimy fluid; the intestines were injected and showed a thin fibrinous exudate upon the surface; the spleen was enlarged and softened, and the adrenals much reddened. Cover-glass preparations from the heart, blood, spleen, and peritoneal cavity showed large numbers of the capsule bacilli. Howard|| has also called attention to the importance of this bacil- lus in connection with numerous acute and chronic infectious proc- esses, among which may be mentioned croupous pneumonia, suppura- * “Tour. Exp. Med.,” 1912, xv, 133. t “Jour. Boston Soc. of Med. Sci.,” March, 1898, vol. 1, No. 8, p. 137- { “Zeitschrift fiir Hygiene,” xxt. § “Jour. Boston Soc. of Med. Sci.,”” May, 1898, vol. 11, No. 10, p. 174. || “Phila. Med. Jour.,” Feb. 19, 1898, vol. 1, No. 8, p. 336. Mixed Pneumonias 461 tion of the antrum of Highmore and frontal sinuses, endometritis, perirenal abscesses, and peritonitis. Virulence.—The virulence of the organism seems to vary under different conditions. It is sometimes harmless for the experiment animals, but when injected into mice and guinea-pigs usually pro- duces local inflammatory lesions, and sometimes death from septic invasion. CATARRHAL PNEUMONIA OR BRONCHO-PNEUMONIA This form of pulmonary inflammation occurs in local areas, commonly situated about the distribution of a bronchiole. It cannot be said to have a specific micro-organism, as almost. any irritating foreign matter accidentally inhaled may cause it. The majority of the cases, however, are infectious in nature and result from the inspiration, from higher parts of the respiratory apparatus, of the staphylococci and streptococci of suppuration, Friedlander’s bacillus, the bacillus of influenza, and other well-known organisms. TUBERCULOUS PNEUMONIA The progress of pulmonary tuberculosis is at times so rapid that the tubercle bacilli are distributed with the softened infectious matter throughout the entire lung or to large parts of it, and a distinct pneumonic inflammation occurs. Such a pneumonia may be caused by the tubercle bacillus, or the tubercle bacillus together with staphylococci, streptococci, tetragenococci, pneumococci, pneu- mobacilli, and other organisms accidentally present in a lung in which ulceration and cavity formation are advanced. PLAGUE PNEUMONIA The pneumonic form of plague is characterized by consolidation of the lung histologically and anatomically, indistinguishable from pneumococcic and other extensive pulmonary infections. MIXED PNEUMONIAS It frequently happens that pneumonia occurs in the course of influenza or shortly after convalescence from it. In these cases a mixed infection by the influenza bacilli and pneumococci is commonly found. Sometimes pneumococci and staphylococci simultaneously affect the lung, purulent pneumonia with abscess formation being the conspicuous feature. Almost any combination of bacteria may occur in the.lungs,so that it must be left for the student to work out what the particular effects of each may be. Among the mixed forms of pneumonia may be mentioned those called by lemperer and Levy “complicating pneumonias,” occurring in the course of typhoid fever, etc. CHAPTER XVII INFLUENZA Bacittus INFLUENZA (R. PFEIFFER) General Characteristics—A minute, oer non-flagellated, non-sporog- enous, non-liquefying, non-chromogenic, aérobic, pathogenic bacillus, staining by the ordinary methods, but not by Gram’s method, and susceptible of artificial cultivation, chiefly through the addition of hemoglobin to the culture-media. Notwithstanding the number of examinations conducted to determine the cause of influenza, it was not until 1892, after the great epidemic, that Pfeiffer* found, in the blood and purulent bronchial discharges, a bacillus that conformed, in large part, to the require- ments of specificity. Morphology.—The bacilli are very small, having about the same diameter as the bacillus of mouse septicemia, but only half its length (0.2byo.5 4). They are usually solitary, but may be united in chains of three or four. They are non-motile, have no flagella, and, so far as is known, do not form spores. Staining.—They stain rather poorly except with such concentrated and penetrating stains as carbol-fuchsin and Liffler’s alkaline meth- ylene blue, and even with these more deeply at the ends than in the middle, so that they appear not a little like diplococci. They do not stain by Gram’s method. ; Canonf recommends a rather complicated method for the demon- stration of the bacilli in the blood. The blood is spread upon clean cover-glasses in the usual way, thoroughly dried, and then fixed by immersion in absolute alcohol for five minutes. The best stain is Czenzynke’s: Concentrated aqueous solution of methylene blue......... 40 0.5 per cent. solution of eosin in 70 per cent. alcshol Mepea ke 20 Distilled: Water isasesdso5-sae ted $s eG ene odes mieands wh ea S 40 The cover-glasses are immersed in the solution, and kept in the incubator for from three to six hours, after which they are washed in water, dried, and mounted in Canada balsam. By this method the erythrocytes are stained red, the leukocytes blue; and the bacilli, also blue, appear as short rods or as dumb-bells. Large numbers of bacilli may be present, though sometimes only a few can be found after prolonged search, as they are prone to occur * eee med. Wochenschrift,” 1892, 2; “Zeitschrift fiir Hygiene,” 1893, xiii, 357. ?#Qeatralbl. f. Bakt.,” etc., Bd. x1v, p. 860. 462 Cultivation 463 in widely scattered but dense clusters. They are frequently inclosed within the leukocytes. It is scarcely necessary to pursue so tedious a staining method for demonstrating the bacilli, for they stain well enough for recognition by ordinary methods. Isolation—The influenza bacillus grows poorly upon artificial culture-media, and is not easy to isolate, because the associated bac- teria tend to outgrow it. When isolated it is difficult to keep, as it soon dies in artificial cultures. Pfeiffer found that the organism grew when he spread pus from the bronchial secretions upon serum-agar. Subcultures made from the original colonies did not “take.’”’ By a series of experiments he was able to make the organism grow when he transferred it to agar- agar, the surface of which was coated with a film of blood taken, Fig. 174.—Bacillus of influenza. Smear from sputum (after Heim). with precautions as to sterilty, from the finger-tip. Later it was found that the addition of hemoglobin to the culture-medium was equally efficacious. By, the use of such blood-smeared agar and glycerin-agar the organism can now be successfully cultivated. The isolation is best achieved through the use of bronchial secre- tions, carefully washed in sterile water or salt solution to remove contaminating organisms from the mouth. Cultivation.—Upon blood-spread glycerin agar-agar, after twenty- four hours in the incubator, minute colorless, transparent, dewdrop- like colonies may be seen along the line of inoculation. They look like condensed moisture, and Kitasato makes a special point of the fact that they never become confluent. The colonies may at times be so small as to require a lens for their detection. No growth takes place at room temperature. The organisms die 464 Influenza quickly and must be transplanted every three or four days if they are to be kept alive. The organism is aérobic and scarcely grows at all where the supply of oxygen is not free. In bouillon a scant development occurs, small whitish particles appearing upon the surface, subsequently sinking to the bottom and causing a ‘wooly’ deposit there. Thebacillus grows moreluxuriantly upon culture-media containing hemoglobin or blood, and can be transferred from culture to culture many times before losing vitality. Vital Resistance.—Its resisting powers are very restricted, as it speedily succumbs to drying, and is certainly killed by an exposure to a temperature of 60°C. for five minutes. It will not grow at any temperature below 28°C. Fig. 175.—Bacillus of influenza; colonies on blood agar-agar. Low magnifying power (Pfeiffer). Specificity.—From the fact that the bacillus is found chiefly in cases of influenza, that it is present as long as the purulent secretions of the disease last, and then disappears, and that Pfeiffer was able to demonstrate its presence in all cases of uncomplicated influenza, it seems that his conclusion that the bacillus is specific is justifiable. It is also found in the secondary morbid processes following influenza, such as pneumonia, endocarditis, middle-ear disease, meningitis, etc. Horder* has cultivated it from the valvular vegetations of 2 cases of endocarditis following influenza. Davis} found the influenza bacillus in the respiratory passage of a large number of patients suffering from whooping-cough. * “Path, Soc. of London,” “Brit. Med. Jour.,” April 22, 190 ft “Jour. Infectious Diseases,” 1906, III, 1. ee ce Immunity 465 Pathogenesis.—The bacillus is pathogenic for very few of the laboratory animals. The guinea-pig is susceptible of fatal infec- tion, the dose required to cause death varying considerably. Pfeiffer and Beck* produced what may have been influenza in monkeys by rubbing their nasal mucous membranes with pure cultures. Immunity.—As influenza is a disease that commonly relapses, and from which one rarely seems to acquire protection against future attacks, there must be scarcely any immunity induced through ordi- nary infection. Moreover, the organism once finding its way into the body seems to remain almost indefinitely, especially when, as in Fig. 176.—Bacillus of influenza; cover-glass preparation of sputum from a case of influenza, showing the bacilli in leukocytes. Highly magnified (Pfeiffer). pulmonary tuberculosis, there is already present an abnormal con- dition furnishing discharges or exudates in which it can thrive. Delius and Kollet found that the toxicity of the culture does not depend upon a soluble toxin, but upon an intracellular toxin. The outcome of the researches, which were made most painstakingly, was total failure to produce experimental immunity. Increasing doses of the cultures, injected into the peritoneal cavity, enabled the animals to resist more than a fatal dose, but never enabled them to recover when large doses of living cultures were administered. A.Catanni, Jr.,t trephined rabbits and injected influenza toxin * “Deutsche med. Wochenschrift,” 1893, XXI. t “Zeitschrift fiir Hygiene,” etc., Bd. 1897, xxiv, Heft 2. ft Ibid., Bd., 1896, xxrz1. ; 30 ; 4.66 Influenza into their brains, at the same time trephining control animals, into some of whose brains he injected water. The animals receiving 0.5 to 1 mg. of the living culture died in twenty-four hours with all the nervous symptoms of the disease, dyspnea, paralysis beginning in the posterior extremities and extending over the whole body, clonic convulsions, stiffness of the neck, etc. Control animals in- jected in the same manner with water, and with a variety of other pathogenic bacteria never manifested similarsymptoms. The viru- lence of the bacillus increased rapidly when transplanted from brain to brain. Diagnosis of Influenza.—Wynekoop* ate for diagnosticating influenza and isolating the bacillus, a culture outfit similar to that used for diphtheria diagnosis, except that the serum contains more hemoglobin. The swab is used to secure secretions from the pharynx and tonsils, and from the bronchial secretions of patients with influenza, then rubbed over the blood-serum. In many such cultures minute colonies corresponding to those of the influenza bacillus were found. Those most isolated were picked up witha . . wire and transplanted to bouillon, from which fresh blood-serum was inoculated and pure cultures secured. Carbol-fuchsin was found most useful for staining the bacilli. Wynekoop observed that influenza and diphtheria bacilli sometimes coexist in the throat, and that influenza bacilli are present in the sore eyes of those in the midst of household epidemics of influenza. THE PSEUDO-INFLUENZA BACILLUS Pfeiffert has also described a pseudo-influenza bacillus—a small, non-motile, non-flagellated, non-sporogenous, Gram-negative bacillus—that he found in certain cases of broncho-pneumonia in children. It differed from the influenza bacillus by a slightly greater size, a tendency to grow in chains, and to undergo involution. Martha Wollsteint believes that they are influenza bacilli. *“Bureau and Division Reports,” Department of Health, city of Chicago, Jan., 1899. + ‘Zeitschrift fiir Hygiene,” etc., 1892, XIII t “Jour. Exp. Med.,” 1906, vii. CHAPTER XVIII MALTA OR MEDITERRANEAN FEVER Micrococcus MELITENSIs (BRUCE); Bacrtttus MELITENSIS (BABES) General Characteristics ——A non-motile, non-flagellate, non-sporogenous non-chromogenic, non-liquefying, pathogenic coccus, staining by the ordinary methods, but not by Gram’s method; characterized by remarkably slow growth and by pathogenic action upon monkeys. In 1877, while working in Malta, Bruce* succeeded in finding in every fatal case of Malta fever a micrococcus which could be isolated in pure cultures from the spleen, liver, and kidney, which grew readily on artificial media, and which, when injected into monkeys, produced the disease. Morphology.—Micrococcus melitensis, as Bruce called it, is a round or slightly oval organism measuring about 0.3 w in diameter. It is usually single, sometimes in pairs, but never in chains. When viewed in the hanging drop it is said to exhibit active ‘‘molecular”’ movements, but is not motile and has no flagella. Babest declares it to be a bacillus. Staining.—It stains well with aqueous solutions of the anilin dyes, but not by Gram’s method. Thermal Death Point.—This has been fixed by Dalton and Eyret at 57.5°C. Cultivation.—The best medium for its cultivation is said to be ordinary agar-agar. After inoculating, by a puncture, from the spleen of a fatal case of Malta fever, the tubes should be kept at 37°C. The growth first appears after several days, in the form of minute pearly white spots scattered around the point of puncture and along the needle path. After some weeks the colonies grow larger and join to form a rosette-like aggregation, while the needle tract becomes a solid rod of yellowish-brown color. After a lapse of months the growth still remains restricted to the same area and its color deepens to buff. When the sloping surface of inoculated agar-agar is examined by transmitted light, the appearance of the colonies is somewhat dif- ferent. At the end of nine or ten days, if kept at 37°C., some of the colonies have a diameter of 2 to 3mm. They are round in form, have an even contour, are slightly raised above the surface of the agar- * “Practitioner,” XXXIV, p. 161. t Hoe and Wassermann, “Die Pathogene Mikrodrganismen,” Ill, p. 443- Jour. of Hygiene,” 1904, Iv, p. 157. 467 468 Malta or Mediterranean Fever agar, and are smooth and shining in appearance. On examining the colonies by transmitted light, the center of each is seen to be yellow- ish, while the periphery is bluish-white in color. The same colonies by reflected light appear milky-white. Colonies on the surface of the agar-agar are found to be no larger than hemp-seed after a couple of months of cultivation. When kept at 25°C., no colonies become visible to the naked eye before the seventh day; at 37°C., before the third or fourth day. In bouillon culture kept at 37°C., diffuse clouding of the medium occurs in three or four days. There is no scum on the surface. No indolis formed. In sugar bouillon there is no fermentation. In milk the organism grows slowly without coagulation and with- out acid production. ee was. apie Fig. 177.—Micrococcus melitensis. great slowness, first appearing in about a month, and no liquefac- tion of the medium occurs. No growth takes place on boiled potato. Plate cultures are not adapted to the study of the organism be- cause of its extreme slowness of growth. Bacteriologic Diagnosis.—The specific agglutinative effect of the serum can be made use of for the purpose of diagnosis. This has been studied by Wright,* Birt and Lamb,{ and later by Bassett- Smith.f All of the observers have shown that the agglutinative reaction takes place both with living and dead cultures of the Micrococcus melitensis, but that to,make the diagnosis dilutions of serum equal to about 1 : 30, never greater than 1 : 50, must be used. Birt and * “Lancet,” 1897, March 6; “Brit. Med. Jour.,” 1897, May 15. [pies 1899, II, p. 701. “British Med. Jour.,” 1902, 1, p. 861. Treatment 469 Lamb also arrive at certain conclusions regarding the prognosis based upon a study of the agglutinative phenomena. Their conclu- sions are: 1, Prognosis is unfavorable if the agglutinating reaction is persistently low. 2. Also if the agglutinating reaction rapidly fall from a high figure to almost zero. 3. A persistently high and rising agglutinating reaction sustained into con- valescence is favorable. 4. A long illness may be anticipated if the agglutination figure, at first high, decreases considerably. The agglutination reaction appears early, is available by the end of the first week, and often persists for years after convalescence. The organisms may sometimes be cultivated from the blood taken from a vein, but are more certainly to be secured by splenic puncture. Pathogenesis.—The micro-organism is not pathogenic for mice, guinea-pigs, or rabbits, but is fatal to monkeys, goats, dogs, horses, asses, and mules, when agar-agar cultures are injected beneath the skin. The micro-organism usually seems to be absent from the circulat- ing blood, though Hughes has cultivated it from the heart’s blood of a dead monkey. Bruce not only succeeded in securing the micro-organism from the cadavers of Malta fever, but has also obtained it during life by splenic puncture. Accidental inoculation with Micrococcus melitensis, as by the prick of a hypodermic needle, is almost invariably followed by an attack of the disease. Six cases of this kind in human beings have occurred in connection with bacteriologic work on Malta fever at Netley and two additional at the Royal Naval Hospital at Haslar and in the Philippines.* Treatment.—The treatment of Mediterranean fever by means of bacterio-vaccines has been attempted with what seems to be glit- tering results by Bassett-Smith.+ The report of “British Government Commission for the Investi- gation of Mediterranean Fever,” published by the Royal Society, April, 1907, has greatly elucidated our knowledge of the pathogeny of the disease by showing that the Micrococcus melitensis leaves the body of the patient in the urine and in the milk. It has not been found in the saliva, sweat, breath, or feces. The discovery of the organism in the milk suggested that it might be through milk that the specific organisms were disseminated, and an investigation of the goats at Malta, where the disease is most prevalent, and their milk most generally used, showed that a large percentage of the animals were infected with the specific cocci. ‘The commission has, therefore, concluded that it is by goats’ milk that the disease is commonly disseminated, though they point out that fly-transmission is also - See Wright and Windsor, “Jour. of Hygiene,” 1902, I, p. 413. t “Journal of Hygiene,” 1907, vil, p. 115. 470 Malta or Mediterranean Fever possible. In the Colonial Office Report on Malta in 1907 it was shown that over 4o per cent. of the goats of Malta gave the serum reaction, showing that they had had the disease, while ro per cent. of them were actually secreting the cocci in their milk. The authorities permit no milk to be used in the garrison unless it is boiled, and notice that by this simple measure the incidence of the disease, which was 9.6 in 1905, had fallen to 2 in the corresponding month of 1906. In Report VII. of the Mediterranean Fever Commission (1906-07) we read: “The epidermologists are led to believe that quite 7o per cent. of the cases are due to the ingestion of goat’s milk.” In their opinion ordinary contact with the sick, conveyance of infection by biting insects, house-flies, dust, drain emana- tions, food (other than milk), and water, play a very subordinate part, if any, in setting up Mediterranean fever in man. ‘The excellent results following the preventive measures directed against goat’s milk in barracks and hospitals also point to goat’s milk as being the chief factor. Among the soldiers this resulted in a diminution of about 90 per cent. “For example, in the second half of 1905 there were 363 cases of Mediter- ranean fever, whereas in the corresponding part of 1906 there were only 35 cases. Among the sailors there was also as marked a fall in the number of cases. The Naval Hospital had a bad reputation, as about one-third of the cases of fever occurring in the fleet at Malta.could be traced to residence in this hospital, either as patients suffering from other diseases or among the nursing staff. The goats supplying the hospital were found to be infected, and since their milk was absolutely forbidden, not a single case of Malta fever has occurred. in or been traced to residence in this hospital.” CHAPTER XIX MALARIA Prasmopium MaLariZ (LAVERAN); PLasmoprum Vivax (GRASSI AND FELETTI); PLAsmopiumM Fatcrparum (WELCH) Matazi, or paludism, has been known since the days of ancient medicine, and has always been regarded as the typical miasmatic disease. Its name, mala aria, means “bad air,’’ and is Italian de- rived from the Latin, malus and aer, coming from the Greek dip, air, from dev, to blow. The other name, paludism, from the Latin palus, a “marsh,” refers the disease to the bad air coming from marshes. : It is a disease of extremely wide geographic distribution, and since the supposed requirement, marshy ground, is found in nearly all countries, and the disease is particularly prevalent in the marshy districts of those countries in which it occurs, the connection between the marshes and the disease seemed clear. Indeed, the two are inti-. mately connected, but not in the original sense as will beshown below. _ Both hemispheres, all of the continents, and most of the islands of the sea suffer more or less from malaria, and in many places, especially in the tropics, it is so pestilential as to make the country uninhabitable. Probably no better idea of the wide distribution and severity of the disease can be obtained than by reference to Davidson’s ‘‘Geographical Pathology.”* The disease assumes the form of a fever of intermittent or remittent type, characterized by certain peculiar paroxysms. When typical, as in well-marked intermittent fever, these are ushered in by de- pression, headache, and chilly sensations, which are soon followed by pronounced rigors in which the patient shivers violently, his teeth chattering. The temperature soon begins to rise and attains a height of 102°, 104°, or even 106°F., according to the severity of the case. As the temperature rises the sense of chilliness disappears and gives place to burning sensations. The skin is flushed, hot, and dry. After a period varying in length the skin begins to break out into perspiration, which is soon profuse, the fever and headache disappear and the patient commonly sinks into a refreshing sleep. The frequency of the paroxysms varies with the type of the disease, which, in its turn, can be referred to the kind of infection by which it is caused. The paroxysms exhaust the patient and incapacitate him and may eventually prove fatal, though in by far the greater number of cases the disease gradually expends itself and a partial or complete fecovery ensues. Some cases, known as pernicious, are rapidly fatal, *D. Appleton & Co., New York, 1892. 471 472 Malaria others develop into a chronic cachexia, with profound anemia and complete incapacitation for physical or mental effort. The discovery of Peruvian or Jesuits’ bark, and its introduction into Europe by the Countess del Cinchén, the wife of the Viceroy of Peru, about 1639, marked an important epoch in the study of malarial fever. The isolation of its alkaloids, quinin and cinchona, begun in 1810 by Gomez and perfected in 1820 by Pelletier and Coventou, a second great epoch. But the most important epoch began in 1880, when Charles Louis Alphonse Laveran,* a French physician engaged in the study of malarial fever in Algeria, announced the discovery of a parasite, to which he gave the name Plasmodium malariz, in the blood of patients suffering from the disease. His observations were immediately confirmed, Biitschli recognizing the parasitic nature of the bodies observed. For the discovery he was awarded the Bré- ant prize. Laveran, however, threw no light upon the source of infection, and malaria continued to be described as a miasmatic disease. It was, however, recognized that there were different types of para- sites corresponding to the different clinical forms of the disease, and Golgit succeeded in correlating the various appearances of the para- sites so as to express their life cycles. But in spite of the interesting and important work of Golgi, Celli, Bignami and Marchiafava, and many others, no progress was made in accounting for the entrance of the parasites into the human body. This problem had long interested Sir Patrick Manson, who had devised a theory which, though wrong in detail, proved in the end to open the door to the next important discovery. Finding that the malarial parasites could not be shown to leave the body in any of its eliminations, and remembering that the same was true of the filarial worms and their embryos, Manson came to the conclusion that they must be taken out of the blood by some suctorial insect. The one naturally first considered was the mosquito, which was known to abound wherever malaria prevailed. Examining mosquitoes that had been permitted to distend themselves with the blood containing the parasites, Manson found that in the stomach of the insect the peculiar phenomenon known as “flagellation,”’ long before observed by Laveran, took place in the parasites, giving rise to long, slender, lashing, and, finally, free-swimming filaments. These, he conjec- tured, might be the form in which the parasites left the mosquito to infect the swamp water, with which human infection eventually was brought about. Here Manson failed, but while he was investi- gating he explained the whole matter to Major Ronald Ross, who was soon to go to India, and whom he advised to make the matter a subject for study when he arrived at his destination. Ross{ ac- cepted the opportunity that soon presented itself, and, after a most *“ Accad. d. Méd.,” Paris, Nov. 28 and Dec. 28, 1880. t “R. Accad. di Medicina di Torino,” 1885, x1, 20. ft “Indian Medical Gazette,” xxx1, 14, 133, 401, 448. Malarial Parasites 473 painstaking investigation, the details of which are given in a paper which can be found in the International Medical Annual,* 1890, made the second great discovery inthe parasitology of malarial fever. He found that, as Manson thought, the mosquito is the definitive host of the parasite, but that the matter is much less simple than was imagined, for the organisms taken up by the mosquito undergo a complicated life cycle requiring about a fortnight for completion, after which, not the water into which the mosquito might fall and into which its contained organisms might escape, but the mosquito it- self becomes the agent of infection. In other words, the parasites taken up by the mosquito, after the completion of the necessary de- velopmental cycle, are returned by the mosquito to new human beings, who thus become infected. Thus it was shown that malaria is not a miasmatic disease at all, but that it is an infectious disease whose parasites divide their life cycle between man and the mosquito, each becoming infected by the other. The only réle of the swamp is to furnish the mosquitoes, and since these are only more numerous where swamps are numerous, but may occur without swamps, the not infrequent occurrence of malarial fevers apart from swamps is also explained. Ross further discovered that all mosquitoes are not equally susceptible of infection, and, therefore, not all able to spread the infection. Indeed, he so carefully studied the mosquitoes as to narrow the infectability and infectivity of mosquitoes down to one single family, the Anopheline, and to one single genus, Anopheles. There remained, however, one more important fact to be eluci- dated, and one more mysterious body to be accounted for, viz., the “flagellated” body that had misled Manson. This was found by MacCallum to be but the spermatozoit of the male parasite. While observing one of the malarial parasites of birds—Plasmodium dan- liewskyi—he saw one of these “flagella” swimming away from its parent parasite, and followed it carefully, moving the slide upon the stage of the microscope. It, and others of its kind, approached a large globular parasite, to which one effected an attachment and into which it entered. MacCallum realized that he had observed the sexual fertilization of the organism. In 1900 two demonstrations of momentous importance were made. First, Sambon and Low went to Italy, to one of the most pestilential parts of the Campagna | Romana, and lived there during three months of the most malarious time of the year in a mosquito-proof house, taking every precaution to avoid mosquitoes, and escaped infection; second, anopheles mosquitoes infected in Italy, by biting malarial patients, were taken. to England, where they were permitted to bite Dr. P. J. Manson and Mr. George Warren, both of whom, after a period of incubation suffered from malarial paroxysms and showed plasmodia in their bloods. What may perhaps be regarded as the final step in the per- *E. B. Treat & Co., New York. t “Journal of Exper. Med.,” 1898, 111, 117. 474 Malaria fection of the knowledge of the parasite was reached in 1911, when C. C. Bass* devised a method of cultivating the parasite in its asexual stage, in vitro. Thus from its time-honored place as the typical miasmatic disease, full of mystery and obscurity, malarial fever suddenly had a flood of light thrown upon it by which every peculiarity was fully illuminated. In summarizing the knowledge thus set forth we find the following facts: 1880—Discovery of the Plasmodium malaria by Laveran. 1890—Discovery of its human developmental cycle by Golgi. 1895—Discovery of the mosquito cycle and mode of transmission by Ross. 1898—Discovery of the sexual fertilization of the parasite by MacCallum. t911—Discovery of the method of cultivating the parasites in vitro by C. C. Bass. The interest aroused by Laveran’s original discovery gave a great impetus to the study of hematology with special reference to para- sites, and it soon became evident that the plasmodium was but one of a group of similar parasites. quainted with the following: Disease Quartan fever. Parasite Plasmodium malarie. Plasmodium Tertian fever. vivax. Aestivo-autumnal fever. Plasmodium falciparum. Plasmodium kochi. Plasmodium inui. Plasmodium pitheci. ’ Plasmodium brazilianum, _ Plasmodium cynomolgi. Plasmodium grassii (Pro- teosoma grassi). Plasmodium danliewskyi (Halteridium danliewskyi). Of these we have now become ac- Host Insect host Man. Anopheles, My- zorrhynchus, Myzomyia, Cel- lia. Man. Anopheles, My- zorrh ynchus, Myzomyia, Cellia. Man. Anopheles, My-- zorrhynchus, _Myzomyia, Cellia. Cercopithicus. Unknown. Macacus (Inuus Unknown. cynomolgus). Orang - outang Unknown. (Pithecus sa- tyrus). Brachyrus calores. Unknown. Inuus cynomolgus Unknown. and Inuus nem- istrinus. Sparrows, canary birds, and other small birds. Culex pipens. Owls, hawks, Unknown. crows, and other large birds. * © Journal of the American Medical Association,” 1911, XLVII, 1534+ Malarial Parasites ATS These micro-organisms correspond in all essentials. They are protozoan parasites belonging to the sporozoa and live in the blood (hematozoa) as parasites of the red corpuscles. They all have two life cycles, one which is asexual in the intermediate warm-blooded host, and one that is sexual in the definitive cold-blooded (insect) host. Though the intermediate hosts vary and may be birds or Fig, 178.—Plasmodium falciparum. Odkinetes in the stomach of Anopheles (Grassi). mammals, the insect hosts, so far as known, are always mosquitoes. The mosquitoes become infected by biting and sucking the blood of infected animals; the warm-blooded animals become infected by being bitten by infected mosquitoes, and so on, in endless cycles. The parasites differ but little in the details of structure and de- - velopment, so that the following description may serve as a type for all: From the proboscis of the mosquito, with its saliva, from cells in the salivary glands where they have been harbored, tiny elongate spindles, measuring about 1.5 #in length and o.2 w in breadth, and known as sporozoits, enter the blood of the individual bitten. These sporozoits attach themselves to the red blood-cor- puscles, gradually lose their elongate form, and become irregularly spherical. : There is some difference of opinion as _, Fig. 179-—-Plasmodium fal- h th th littl bodies are sim 1 ciparum. Transverse section whether the € P!Y of the stomach of Anopheles, upon the corpuscles, as Koch believed, showing the odkinetes of the at in the corpuscles, as the majority eras, in vasous sage fe of writers believe, but it isan immate- outer surface (Grassi). rial difference, for the parasite soon makes clear that it is consuming the corpuscle. This little body is known as a schizont. When stained with polychrome meth- ylene-blue, and examined under a high power of the microscope, it appears as a little ring with a dark chromatin dot upon one side. It grows steadily, feeding upon the hemoglobin, which seems to be chemically transformed into fine or coarse granules of a bacillary or tounded form, presumably melanin. In a length of time that 476 Malaria Fig. 180.—Developmental cycle of plasmodium vivax, the tertian malarial parasite. Figures 1 to 17 are magnified 1200 diameters; 18 to 27, only 600 diameters: 1, Sporozoit; 2, penetration of a sporozoit into a red blood-corpuscle; 3 and 4, schizont developing in the red blood-corpuscles; 5 and 6, nuclear division of the schizont; 7, free merozoits; 8 (following the arrows to the left to 3), Merozoits entering red blood-corpuscles, and multiplying by schizogony. 3 to 7; after longer continuance of the disease the sexual forms arise; ga to 124, macrogametocytes; gb to 12b, microgametocytes still in the circulatory blood of man. If the macrogametocytes (12a) are not taken into the alimentary canal of the mosquito, they multiply parthenogenetically (12a, 13¢ to 17c) and the resulting merozoits (17c) become schizonts (3 to 7). The figures below the dotted line represent what takes place in the alimentary canal of anopheles G3 to 17); 13b and 14b the formation of microgametocytes; 13a and 13b, matura- tion of the macrogametes; 15b, a microgamete: 16, fertilization; 17, odkinete; Malarial Parasites 477 varies—twenty-four to forty-eight hours (Plasmodium falciparum), forty-eight hours (Plasmodium vivax), seventy-two hours (Plasmo- dium malarie)—the schizonts mature, becoming nearly as large or quite as large as the corpuscles. The pigment granules now collect at the center and the substance of the parasite divides into a group of equal-sized merozoits, commonly known as spores. Of these there are usually eight in the meroblasts of Plasmodium malaria, from fifteen to twenty-five in those of Plasmodium vivax, and from eight to twenty-five in Plasmodium falciparum. As the spores be- come fully formed and ready to separate, the paroxysm of the disease begins. It ends as the spores are freed and enter new corpuscles to begin the cycle over again. After a good many paroxysms have occurred it may be observed that not all of the schizonts change to meroblasts and form spores. Some remain large spheroidal bodies or, as in Plasmodium falciparum, assume a peculiar crescentic form and remain unchanged in the blood. These are the sexual parasites. The female is usually the larger and is known as the makrogame- tocyte, the male, the smaller, the microgametocyte. These are the bodies which, when removed by the mosquito, lay the foundation of its infection. When they are withdrawn for microscopic examina- tion or exposed to the intestinal juices of the mosquito, the micro- gametocyte becomes tumultuous, its granules are observed to be in a state of active cytoplasmic streaming, and suddenly there burst forth long slender filaments, the microgametes or spermatozoits. These correspond with the flagella of Laveran and others, and are the same bodies that Manson thought might be the form in which the parasite leaves the insect’s body. The microgametes lash vig- orously for a time, then, breaking loose, swim away, and, as MacCallum observed, conjugate with macrogametes, sexually per- fect cells formed from the macrogametocytes by ‘‘reduction divi- sion” and polar body formation, thus fertilizing them. As the re- sult of this fertilization a zygote or odkineteisformed. It assumesa somewhat elongate pointed form and attaches itself to the wall of the mosquito’s stomach. In the course of time it penetrates and appears upon the outside, projecting into the body cavity. It grows larger and rounder, divides into several segments, and even- tually forms an odcyst with many small cells, which break up into myriads of tiny elongate fusiform bodies, the sporozoits. These, in the course of time, seem to find their way to the salivary glands, en- tering into the epithelial cells and taking radial positions about the 18, odkinete on the wall of the mosquito’s stomach; 19, penetration of the gastric epithelium by the odkinetes; 20 to 25, stages of sporogenesis on the outer wall of the mosquito’s stomach; 26, migration of the sporozoits to the salivary glands of the mosquito; 27, salivary gland with sporozoits in the epithelial cells, and escape of the sporozoits from the salivary glands through the insect’s proboscis at the time a human host is bitten; 1, free sporozoit from the mosquito’s saliva in the human blood; 2, penetration of the sporozoit into a red blood-corpuscle, beginning the human cycle again (Lithe). 478 Malaria nuclei, where they remain for a time. Later, they leave the cells with the saliva, and when the mosquito again bites, enter the warm- blooded host to infect it, if of the appropriate species. The whole cycle in the mosquito varies, according to the external temperature, from ten days to a fortnight. The mosquito may re- main alive for more than one hundred days, and must bite frequently . to satisfy its needs. It remains infective so long as the sporozoits remain in the saliva, which is usually as long as the insect is alive. Here it may be remarked that as it is only the female mosquitoes that bite, it is only by them that the infection can be spread. It is an interesting question, not yet solved, whether any of the sporozoits entering into the mosquito’s ovaries can infect its eggs so that a new generation of mosquitoes may be born infective. The longer the human infection persists, the greater the number of gametocytes formed, until sometimes in estivo-autumnal malaria, no schizonts are any longer found, though the blood contains large numbers of gametocytes. In such cases the gametocytes, especially the crescents of estivo-autumnal fever, but sometimes also those of tertian and quartan fever undergo regressive schizogony, by partheno- genesis, in the patient’s blood, and without fertilization suddenly break up into spores which enter the red blood-corpuscles and occa- sion a relapse of the infection that had apparently spent itself. THe Human MAtariIAL PARASITES There are three known forms of human malarial parasites: Plas- modium malarie, Plasmodium vivax, and Plasmodium falciparum. I, Plasmodium Malariz (Laveran,* 1880).—This is the smallest Synonyms.—Oscillaria malarie pro parte, Laveran, r881. Plasmodium var. quartana, Golgi, 1890. Hzemamoeba malaria. Grassi et Feletti, 1892. Hamameeba laverani var. quartana, Labbé, 1894. Plasmodium malarie quart- anum, Labbé, 1899. Hzmomenas malariz, Ross, 1900. Plasmodium golgii, Sambon, 1902. Plasmodium quartane, Billet, 1904; Celli, 1904. of the human malarial parasites. Its occurrence is relatively infre- quent, as is that of the quartan fever that it occasions. The schiz- ogonic period is seventy-two hours long, and as each is completed, a paroxysm of the disease occurs. The parasite, in the red blood-corpuscles, first appears as a tiny ring, at one side of which there is a chromatin dot. At this time the organism cannot be differentiated from Plasmodium vivax. At the end of twenty-four hours the organism seems to extend itself more or - less linearly, and sometimes appears as a long drawn band which crosses the substance of the unchanged corpuscle. In anothertwenty- four hours the breadth of the parasite is two or three times as great; and it has become pigmented. The corpuscle itself is still unchanged. In the last twenty-four hours the parasite enlarges, becomes more or less quadrilateral, finally rounds up, shows depressions upon the sur- *“ Acad. de Med.,” Nov. 23, Dec. 28, 1880. The Human Malarial Parasites | 479 face, corresponding to the divisions into which it is to segment, the pigment gathers at the center, and the substance undergoes cleavage resulting in the formation of from six to fourteen, but usually eight, spores. It is to be noticed that it is not until a few hours before segmentation that the parasite becomes as large as the corpuscle, and that the corpuscle is never enlarged nor bleached by the presence of the parasite. The meroblasts form regular rosettes, or ‘daisy- heads,”’ within the corpuscles. In single infections the parasites are all of the same age and all mature at the same time, so that in any examination of the blood they will all appear uniform. It is, however, sometimes true that the patient may have been infected one day by one mosquito bite, and again infected the next day or the third day by a second mos- quito bite, so that his blood contains two crops of the microparasites, arriving at maturity at different times. This perplexes the clinician g ‘ Fig. 181.—Parasite of quartan malarial fever: a, b,c, d, enlarging intracellular parasites; ¢, f, g, h, segmentating parasites forming a distinct rosette from which the spores separate; 7, macrogametocyte; j, microgametocyte; k, sporozoit. through the variety of parasitic forms in the blood and the abnormal frequency of the paroxysms. The gametocytes of the parasite remain for some time in the red corpuscles without division, but, finally, become free spherical bodies. Two sizes can be made out, the larger, the macrogametocyte or female, the other, the microgametocyte or male. Each has proto- plasm, with a tendency to take a blue-gray color and appear uni- formly granular, except that at some part of the periphery of each there is a circular or semicircular area that is free from granules. This area is larger in the microgametocyte. II. Plasmodium Vivax (Grassi and Feletti,* 1890).—This is the Synonyms.—Oscillaria ‘malarive pro parte, Laveran, 1881. Plasmodium var.’ tertiana, Golgi, 1889. Hzmamoeba vivax, Grassi et Feletti, 1890. Hemamceba laverani var. tertiana, Labbé, 1894. Plasmodium malarie tertianum, Labbé, 1899. Hemamoeba malarie var. magna, Laveran, 1900. Hemameeba malarie var. tertiane, Laveran, 1904. Plasmodium tertiane pro parte, Billet, 1904. most common of the malarial parasites of man, and occasions the “benign” tertian fever. It isa large parasite, the full-grown schizont *“Centralbl. f. Bakt. u. Parasitenk.,” 1890, VII, 396; 1891, X, 449, 481, 517. 480 Malaria (meroblast), ready to form merozoits, and the gametocytes all exceeding the size of the red blood-corpuscles. It matures in forty- eight hours, but not with mathematic precision. In single infections the greater number of the parasites are of the same age and present the same appearance, but various shapes and ages may be found together. In double infections, with paroxysms every day, para- sites of different ages may be found. The youngest form in which the parasite can be observed is that of a tiny ring in a red blood-corpuscle. The periphery of this ring (when the blood is stained with polychrome methylene blue) is outlined with blue, at one side there is a distinct blue dot, and the center appears colorless and like a vacuole. The dot is usually on the side of the vacuole that has the thinner protoplasmic outline. The smallest such rings usually have a diameter equal to about 34 the diameter of the blood-corpuscle. The tiny ring-form, or, as it might better be called, the “‘seal-ring form,” continues’ until the sit Fig. 182. Fig. 183. Figs. 182, 183.—Gametocytes of plasmodium malarie: 85, The macrogametocyte; 86, the microgametocyte (Kolle and Wassermann). schizont becomes half the diameter of the blood-corpuscle, when its protoplasm has begun to increase so rapidly that the vacuole no longer appears to be so conspicuous. The organism also becomes irregular in shape and is actively ameboid, its protoplasm streaming this way and that when examined in fresh blood. At this time it may be noticed that the infected blood-corpuscle is increasing in volume, sometimes becoming twice the normal size, and also be- coming pale in color. It seems also as though the disk shape of the corpuscle was lost, and it had become swollen into a more spherical—sometimes irregular—form. The parasite, which may still show a relic of its original ring-form, now shows plentifully throughout its protoplasm exceedingly fine granules of yellow- brown pigment. When from thirty-six to forty hours old, all trace of the ‘‘seal-ring”’ form disappears, the ameboid action becomes less marked, and the parasites (now three-quarters the size of the en- larged pale and misshapen corpuscles in which they are contained) DESCRIPTION OF PLATES II AND III. ps ite Sto Various forms of malarial parasites: Figs. 1 to 10 inclusive, tertian parasites; Figs. 11 to 19 inclusive, quartan parasites; Figs. 20 to 26 inclusive, estivo-autumnal parasites. : 1.—Normal red blood-cell. 2.—Young tertian ring. 3.—Large ter- tian ring. 4.—Half-grown tertian parasite. 5.—Infected cell showing Schiiffner’s. dots. 6.—Adult tertian parasite. 7.—Beginning sporula- tion. 8.—Sporulation completed. 9.—Tertian microgametocyte. 10. —Tertian macrogamete. 11.—Young quartan ring. 12.—Older quar- tan ring. 13.—Quartan band. 14.—Older quartan band. 15.—Full- grown quartan parasite. 16.—Mature parasite with divided chromatin. 17.—Sporulation completed. 18.—Quartan microgametocyte. 19.— Quartan macrocyte. 20.—Young estivo-autumnal ring. 21.—Large estivo-autumnal ring. 22.—Mature parasite. 23.—Sporulation com- pleted. 24.—Estivo-autumnal microgametocyte. 25.—Estivo-autum- nal macrogamete. 26.—Estivo-autumnal ovoid. ‘ (From Deaderick, ‘‘A Practical Study of Malaria.’’) PLATE II 10 i 12 PLATE III Se : < yo9" 13 14 15 a: om 16 17 18 19 20 21 22 y pee ihn 4, aN j te ee 23 24 25 26 The Human Malarial Parasites 481 appear as irregular, ragged, protoplasmic bodies filled with fine pigment granules. In about forty-five hours they completely fill the enlarged corpuscles, and begin to gather their protoplasm into rounded formations in which the pigment is no longer distributed, but occurs in irregular stripes or gathers together into a rounded clump. In a couple of hours the blood-corpuscle has disappeared and the rounded parasite, larger than normal red corpuscles, with a lobulated surface, and with its pigment granules collected to form one or two rounded masses, is seen to have reached the stage of the meroblast. This does not form the rosette or ‘“daisy-head” shown by the quartan parasite, but might better be compared to a mulberry, and eventuates in the formation of from fifteen to twenty- five small, rounded or ovoid, pale, unpigmented bodies, the mero- Fig. 184.—Parasite of tertian malarial fever: a, b, c, d, e, f, g, Growing pig- mented parasite in the red blood-corpuscles; 4, spores formed by segmentation of the parasite—no rosette is formed, but concentric rings of the cytoplasm divide; i, macrogametocyte; 1, microgametocyte with spermatozoits. zoits or spores. These become freed from the pigment and at- tached to new red corpuscles, in which they are easily recognized as the “tiny-rings” that begin the schizogonic cycle. The game- tocytes of the tertian parasite, the ‘free spheres,” as they are some- times called, are large, rounded or slightly ovoid bodies, with a uniformly dull bluish-gray or grayish-green protoplasm, in the in- terior of which there is always a circular or semicircular area periph- erally or centrally situated, and colorless. Except in this area the pigment is distributed throughout the parasite. The larger or macrogametocyte, the female parasite, measures 10 to 14 uw in diameter. It has a greenish or grayish-green or almost colorless protoplasm, containing an oval or bean-shaped colorless area al- most half as large as the organism itself. Yellowish-brown pig- 31 482 Malaria ment in short, broad rods is sparingly scattered throughout the substance elsewhere. 2 The microgametocyte or male form is approximately the size of a red blood-corpuscle—8 to 9 4 in diameter. It stains more deeply than its mate and contains more and coarser pigment granules. III. Plasmodium Falciparum (Welch,* 1897).—This is the Synonyms.—Oscillaria malarie pro parte, Laveran, 1881. Hemameeba precox, Grassi et Feletti,1890. Laverania malarie, Grassiet Feletti, 1890. Haemamceba malarie precox, Grassi et Feletti, 1892. Hamomenas precox, Ross, 1899. Plasmodium malarie precox, Labbé, 1899. Plasmodium precox, R. Blanchard,. 1900. Hamamoeba malaria var. parva, Laveran, 1900. Plasmodium immacu- latum, Schaudinn, 1902. Laverania precox, Nocard et Leclainche, 1903. parasite of estivo-autumnal or malignant tertian malarial fever. It is a very small parasite, whose occurrence, even multiple occur- rence, in the corpuscles does not change their size or shape. It. does, however, quickly change the appearance of the corpuscles, which become polychromatophilic, and frequently show numerous . small dots—the granulations of Schiiffner—in the corpuscular substance. The first appearance of the schizont is in the form of tiny rings, which appear to lie upon rather than in the corpuscles, and are first seen at the edges. The rings are outlined by extremely fine lines Fig. 185. Fig. 186. Figs. 185, 186.—Gametocytes of plasmodium vivax: 87, The microgametocyte; 88, the macrogametocyte (Kolle and Wassermann). and sometimes seem to be incompletely closed, so that they are like horseshoes rather than circles. They increase to several times the original size without losing the ring shape, and are variously known as “middle-sized rings” and “large rings.”” They are with difficulty differentiated from the “tiny rings” of the tertian parasite. As the “large ring” stage is reached the parasites begin to disappear from the peripheral blood to complete their growth and undergo meroblast formation in the capillaries of the spleen, the brain, and the bone-marrow. Here the full-grown parasites—meroblasts— appear as irregular disks, resembling those of the quartan parasite, * Article “Malaria” in “A System of Practical Medicine by American Authors,” 1897, p. 138. The Human Malarial Parasites 483 but smaller in size. The pigment is gathered toward the center in a little mass, and eight to twenty-five merozoits are formed in a morula or mulberry-like mass similar to those of the tertian para- site. Two or three parasites to the corpuscle are frequent. They are actively ameboid, do not mature simultaneously, and hence Fig. 187.—Parasite of estivo-autumnal fever: a, b, c, Ring-like and _cross- like hyaline forms; d, e, pigmented forms; f, g, segmentary forms; A, i, j, crescents. there are no regularly occurring paroxysms. The duration of the asexual cycle is from twenty-four to forty-eight hours. The gametocytes are striking and characteristic ovoid and cres- centic bodies—crescenis—114 times the diameter of a red blood- corpuscle in length, and about half the diameter of the corpuscle in breadth. The ends color more intensely with methylene blue Fig. 188. Fig. 189. Figs. 188,.189.—Gametocytes of plasmodium falciparum: 91, The microga- metocyte; 92, the macrogametocyte (Kolle and Wassermann). than the middle portion, and the bacillary pigment granules are collected toward the centers. The longer and more slender crescents are usually bent, and the relic of the corpuscle in which they have formed can often be seen forming a line connecting the ends on the concave side. These are the microgametocytes or male elements. { 484 Malaria The macrogametocytes are broader, not curved, and sometimes are ovoidal or prolate spheroidal in shape. The pigment granules are more widely scattered throughout the substance. The cres- cents are most numerous after the fever has lasted for some time or in recurrences of the fever. The fever in this form of malarial infection may be intermittent with daily—quotidian—paroxysms, or with irregular paroxysms, or the fever may be remittent. The infection is sometimes mild, but may be so severe as to be rapidly fatal. In such cases the number of parasites is enormous, the cerebral capillaries become filled with them, and coma quickly comes on and is soon followed by death. Such cases are described as “congestive chills” or “algid”’ cases. Cultivation of the Parasites.—The parasites have been successfully cultivated in blood, prevented from coagulation, by Bass. In the first paper, Bass announced that the cultivation of these parasites was made possible by the maintenance of the culture at 40°C., the selection of such an elevated temperature being based upon the theory that in the bloods of infected human beings, there were specific amboceptors directed against the invading organisms, but unable to effect their destruction until complement is formed. Complement soon appears in the drawn blood, according to Bass, unless the temperature be sufficiently elevated toprevent it, and he finds 40°C. sufficient for the purpose. A later paper by Bass and Johns} gives the details of cultivation as follows: When blood is to be taken from a malarial patient for the purpose of cultivat- ing the parasites, one prepares a sterile 50 per cent. solution of Merck’s dex- trose, in distilled water, and measured into asterilized test-tube, 1 inchin diameter o.1 cc. for each 10 cc. of blood to be collected. The tube, which is called the “defibrinating tube” is provided with a glass rod that passes through the cotton plug to the bottom of the tube. A needle is plunged into the arm vein of the patient, and the infected blood is permitted to flow into the defibrinating tube until the requisite quantity has been collected. The needle is then with- drawn, the arm dressed, and the blood gently stirred or whipped until defibri- nated. In the process of collecting and whipping, the admixture of air with the blood is to be avoided. If only one generation of parasites is to be cultivated, the culture may be grown in the defibrination tube, provided that the contained column of blood be not greater than 1-2 inches. There is no advantage in having a deeper column of blood, but there is danger in having less depth as under such circumstances the parasites die before thestageof segmentationisreached. In casethecolumn is more than the required depth, some of the blood can be pipetted to other tubes and several cultures made. The plasmodia grow in the top layer of the sedi- mented cells, near the clear supernatant serum above. The thickness of the layer of cells in which they live is said to be not more than Wp of an inch. If the cultures are to be continued for numerous generations, precautions must be taken to exempt the parasites from the destructive activities of the leukocytes. The method is therefore varied in this manner: The defibrinated blood 1s, centrifugalized until three layers are formed, clear serum above, leu- kocytesin a thin layer below, and red corpuscles at the bottom. Theclear serum is pipetted off and filled into small cuiture tubes to make a column not deeper than 134 inches. Red blood corpuscles and plasmodia are then drawn up from * Jour. Amer. Med. Asso., 1911, LVIT, 1534. { “Jour. Exp. Med.,” 1912, Xvi, 567. Cultivation of the Parasites 485 the deeper part of the corpuscular layer, thus escaping the leukocytes at the top, and planted at the bottom of each tube of serum. It is thought to be advan- tageous to use culture tubes with flat bottoms. A still better method is the introduction of a paper disk into a half-inch tube, abouthalfan inch below the surface of the serum, and then place one- or two-tenths of a cubic centimeter of corpuscles upon it. Under these circumstances all of the plasmodia are said to grow and segment. Two or three generations of parasites grow in such cultures, then the plasmodia begin to die out, so that if the culture is to be perpetuated, they must be transplanted to freshly prepared blood-corpuscle tubes of the same kind. The method of transplantation recommended is so very simple: a drop of the culture is drawn into a fine (not capillary) glass pipette and then followed by about five times the volume of the fresh corpuscle suspension. These are mixed in the pipette, care being taken not to mix air with the blood, and are then transferred to the new media in the same manner asin making the originalinoculation. Thetransplantation should be done within five hours of the time of maximum segmentation, and therefore every forty- eight hours for the tertian and estivo-autumnal parasites. All species of the plasmodia have been successfully cultivated by these means. The parasites have also been grown in red blood-cells in Lock’s solution, free of calcium chlorid and in the presence of ascitic fluid. According to Bass and Johns, the parasites grow in the corpuscles, not upon them as believed by Koch. They are destroyed in a few minutes in viiro by normal human serum or by all the modifications of it that they have tested. This fact, together with numerous observations of parasites in all stages of de- velopment apparently within the corpuscles render untenable theidea of extra- corpuscular development. Leukocytes phagocytize and destroy malarial para- sites growing in vitro only when they escape from their red-corpuscle capsule or when the latter is perforated or becomes permeable. The substance of the malarial plasmodium is very different in consistency from that of the blood-cells, and therefore they cannot pass through the smallest capillaries like the more yielding fluid-like red blood-cells. That theconsistency of the protoplasm of the parasite is less yielding than that of the red blood-cell is shown by the fact that when a small quantity of aculture containing large ’ parasites is spread over a slide with the end of another slide, the parasites are dragged to the end of the spread though the red blood-cells are left behind. Large estivo-autumnal plasmodia are round or oval; the tertian variety are more or less flattened. As a result of their unyielding consistency, malarial parasites lodge in the capillaries of the body, especially where the current is weakest, and remain and segment. In the meantime other red corpuscles are forced against them and if in a favorable situation, one or more merozoites pass directly into the other cells. When the segmented parasite has become sufi- ‘ciently broken up it can pass through the capillary into the circulating blood where the remaining merozoites are almost instantly destroyed. They further observed that calcium salts added tocultures of estivo-autumnal parasites caused hemolysis of the infected, possibly also of non-infected red blood-cells. Such salts have no effect on the corpuscles of normal blood, pos- sibly because of the precipitation of other substances from the serum. The amount of calcium necessary to cause hemolysis of malarial blood is only slightly in excess of the quantity present in normal blood and possibly might be reached by the ingestion of considerable quantities of calcium in drinking water or food. They speculate that malarial hemoglobinuria may be the result of the presence of an excess of calcium in drinking water. ; Bass and Johns believe that quinine has no direct effect upon the malarial parasites, but effects its curative influence by rendering the substance of the corpuscles more permeable to the all-sufficient destructive influence of the serum. The quinine would then affect only the parasites in the circulation, and not those lodged in the capillaries, which would not be reached until they had segmented. The effect of quinine is said to be defeated by influences such as diet, exertion, etc., which increase the dextrose content of the blood, whereby the permeability of the red blood-cells seems to be decreased. It is hoped. that a better understanding of the principles involved in the treatment of malaria may result from the study of the organism in culture by which empiricism may be exchanged for rationalism. 486 Malaria Animal Inoculation.—The human malarial parasites cannot be successfully transmitted by experimental inoculation to any of the lower animals. Human Inoculation—The blood of one human being contain- ing schizonts, when experimentally introduced into another human being in doses of x to 1.5 cc. transmits the disease. When thus transmitted, an incubation period of from seven to fourteen days intervenes before the disease, which is of the same type as that from which the blood was taken, makes its appearance. Pathogenesis.—The pathogenic effects wrought by the malarial parasite are imperfectly understood. The synchrony of the seg- mentation of the parasite with the occurrence of the paroxysms seems to indicate that a toxic substance saturates and disturbs the economy at that time. Whether it be an endotoxin liberated by the dividing parasite is not, however, known. The anemia that follows infection can be referred to the destruc- tion of the red blood-corpuscles by the parasites which feed upon them and transform the hemoglobin into melanin (?). When great numbers of the parasites are present the destruction is enor- mous, and the number of corpuscles and the quantity of hemoglobin in the blood sink far below the normal. Leukopenia instead of © leukocytosis is the rule, and while the leukocytes have an appetite for the spores of the parasites and often phagocyte and destroy them, their activity is not sufficiently rapid or universal to check their rapid increase. The melanin granules set free during sporulation are also taken up by the leukocytes and endothelial cells, the latter becoming deeply pigmented at times. : The spleen enlarges as the disease continues until it forms the “ague-cake.”” The enlargement may cause the organ to weigh 7. to ro pounds. It appears to result from hypertrophy. The tissue is pigmented. The liver and kidneys are also enlarged and pigmented. Prophylaxis.—With the knowledge of the réle of the mosquito in the transmission of malaria, its prophylaxis becomes a matter of simplicity when certain measures can be systematically carried out. There are two equally important factors to be considered— the human being and the mosquito. The measures must be di- rected toward preventing each from infecting the other. 1. The Human Beings.—In districts where malarial fever pre- vails, the first part of the campaign had perhaps best be directed toward finding and treating all cases of malarial fever, so that the parasites in their blood may be destroyed and the infection of mosquitoes prevented. This is done by the systematic and general use of quinin. All cases of malarial fever should be required to sleep in mosquito- proof houses under nets, and as the mosquitoes are nocturnal and Pathogenesis 487 begin to fly at dusk, the patients should shut themselves in before that time. By thus killing the parasites in the blood, and keeping the mosquitoes from the patients in the meantime, much can be done. But where malarial fever prevails, the mosquitoes are already largely infected, hence the healthy population should also learn to respect the habits of the insects and not expose themselves to their bites, should screen their houses and their beds, and should take small prophylactic doses of quinin to prevent the development of the parasites when exposure cannot be avoided. 2. The Mosquitoes——It is not known that the parasites can pass from one generation of mosquitoes to another, hence the mosquitoes to be feared are those that are already infected. By ‘ Fig. 190.—Anopheles maculipennis: Adult maleat left, female at right (Howard). making the houses mosquito-proof most of the insects can be kept out, while those that get in can be caught and killed. By draining the swamps and destroying all the breeding places in and near human habitations, the number of mosquitoes can be greatly diminished. Fortunately this is particularly true with reference to the mosquitoes most concerned—the anopheles—which fly but short distances. By closing all the domestic cisterns and Teservoirs, cesspools, etc., so that no mosquitoes can get in to breed or get out to bite, and by draining the pools for half a mile in all _ directions from human habitations, the number of anopheles mos- quitoes can be made almost negligible. If at the same time no Mosquitoes are any longer permitted to infect themselves by biting infected human beings, the spread of the disease must be greatly restricted or checked. 488 Malaria MosQuiToEsS AND MALARIAL FEVER In order that the student may be able to differentiate with reasonable accuracy such mosquitoes as come under his observation, a c Fig. 191.—Various mosquitoes in attitudes of repose: a, Culex pipiens; 5, Myzorrhynchus pseudo-pictus; c, Anopheles maculipennis (Manson). ----- Proboscis “SProthorax Mesothorax Scutellum \-+ Metathorax a“ Halteres ~ : First abdominal segment Vy Abdomen “Basal lobes Fig. 192.—External morphology of a female mosquito (Manson). use must be made of tabulations, to correctly use which, however, the student should have some familiarity with insect structure and Mosquitoes and Malarial Fever 489 the general principles of entomology. The best works of reference for this purpose, that have come under observation to the present time are ‘A Text-book of Medical Entomology” by Patton and Cragg, published by the Christian Literature Society for India, London, Madras and Calcutta, 1913, and the ‘ Handbook of Medical Entomology” by Riley and Johannsen, the Comstock Publishing Co., Ithaca, New York, ro15. The mosquitoes comprise a family of dipterous or two-winged insects, included in the family Culicida. They can be recognized, first by their well-known general form, and second by the presence of scales upon some part of the head, thorax, abdomen, and wings. For the rough and ready identification of the larger groups and principal genera, the following table compiled from various authors may answer. For more precise information and for the identifica- tion of the species, of which hundreds are now described, reference must be made to the large works recommended above. CLASSIFICATION (Stitt) There are four subfamilies of CULICID, differentiated according to the er Palpi as long or longer than the proboscis in the male. 1. Palpi as long as the proboscis in the female; proboscis straight...... 0... cece cece eee ee ANOPHELINZ. 2. Palpi as long or shorter than the proboscis; proboscis curved.......... 0... c eee eee eee ee MEGARRHININE. 3. Palpi shorter than the proboscis................ CULICIN A. II. Palpi shorter than the proboscis in the male and female Ap1n 2. Of these the Anopheline is the one family concerned in the transmission of malarial fever, so that it is important to be able to differentiate the genera in- cluded in the family. ANOPHELINE 1. Scales on head only; hairs on thorax and abdomen. 1.Scales on wings large and lanceolate. Palpi only slightly Scaled 6: cing sas ce Gane cana ea oe BSE EO Anopheles. 2. Wing scales small, narrow, and lanceolate. Only a few scales on palpi............... 0000 cece eee Myzomyia. 3. Large inflated wing scales................000--0005 Cycloleppteron. 2. Scales on head and thorax. Scales narrow and curved. Abdomen with hairs, not scales. 1. Wing scales small and lanceolate.................-. Pyretophorus. 3. Scales on head, thorax, and abdomen. Palpi covered with thick scales. 1. Abdominal scales on ventral surface only. Thoracic scales like hairs. Palpi rather heavily scaled....Myzorrhynchus. 2. Abdominal scales narrow, curved or spindle shaped, in tufts and dorsal patches.................05. Nyssorrhynchus. 3- Abdomen almost completely covered with scales and also having lateral tufts...........0..00220 000 Cellia. 4. Abdomen completely scaled............00.0 0s eee Aldrichia. Species of the genera Anopheles, Myzomyia, and Myzorrhynchus, are known to transmit malarial parasites. The Culicine include Stegomyia and Culex, which have some medical interest, as the former transmits yellow fever and the latter, filarial worms. CULICINAE L Posterior cross-vein nearer the base of the wing than the mid-cross-vein. 490 Malaria 1. Proboscis curved in the female................. Psorophora. 2. Proboscis straight in the female: A. Palpi with three segments in the female. a. Third segment somewhat longer than the first €£WO. <2.ccsa pe kecsae ding a Culex. b. The three segments are equal in / lengths: gyawag.cihigen-iiaraindins . . Stegomyia, B. Palpi with four segments in the female. a. Palpi shorter than the third of the proboscis. Spotted wings.......... Theobaldia. b. Palpi longer than the third of the proboscis. Irregular scales on the “WINGSiisah oss he Ys eden eee eeau te Meansonia. C. Palpi with fine segments in the female... . Teniorrhynchus. II. Posterior cross-vein in line with the mid-cross-vein.. .Joblotina. III. Posterior cross-vein further from the base of the wing than the mid-cross-vein.................-00005 Mucidus. Male mosquitoes can at once be recognized by the pennate antennz which appear like plumes on each side of the head. They commonly ‘‘swarm” in flocks, do not suck blood, and are not com- monly found in or about human habitations. Comparatively little is known of their habits. Cohabitation of the sexes occurs but once after which the males commonly die. The females after fecunda- tion require a meal of blood before they become gravid and ready to oviposit. Oviposition takes place in water. During the winter many gravid females hibernate in cellars in a very inactive condi- tion, but are immediately ready to fly to appropriate places and lay their eggs with the return of warm weather. In hot climates some _of them estivate—i.e., become similarly inactive during the dry period, but are ready to fly to the water and oviposit as soon as the rains begin again. The breeding places vary with the species. Fresh water is the usual preference, but a few select pools of brack- ish water, and one or two species prefer salt water. Most of the malaria-bearing species of anopheles prefer pools of fresh clear. water, some prefer running water in small streams with a slow cur- rent. A few breed in large rivers. Some species are notably domes- tic and. oviposite in wells, cisterns, .water-butts, cans and any other available collection of water.. The eggs are laid as the female hovers upon the surface, touching the water from time to time, with the tip of the abdomen, each time depositing an egg. Culex eggs are fastened together side by side to form a kind of minute raft, but anopheles eggs are laid singly and float away independently of one another. If at the time the waters are receding, the eggs catch upon the leaves and stems of plants they may remain alive until the waters rise again before hatching. Dry eggs are sometimes able to remain alive for long periods, and may even be frozen without being killed. Cazeneuve hatched eight larve from eggs obtained by thawing a block of ice taken from a swamp in North China, where the temperature had gone as low as —32°C. When’ conditions are favorable the eggs hatch in two or three weeks. The anopheles larve feed at Mosquitoes and Malarial Fever 491 the surface of the water along the banks where they are protected by the vegetation. They are voracious feeders and satisfy their appetites with all kinds of minute vegetable and animal organisms orremnants. Ina day or two the larve molt for the first time. In Fig. 193.—Pupa of Anopheles maculipennis (Brumpt). to , Brushes “Maxillary palyp Antenna Silky bristles Abdomen A Se Chitinous combs ' an Stigmata we Anal papilla c _. Large bristles \ / a Fig. 194.—Larva of Anopheles maculipennis (Brumpt). five or six days, having grown larger, they molt a second time and pupate. The appearances of the larva and pup are shown in the accompanying diagrams. The pupa floats at the surface of the water, is comparatively inactive and does not feed. If disturbed, it 492 Malaria is capable of swimming vigorously to escape. In about three days the imago issues and is ready to fly. Anopheles do not fly great distances; a few hundred yards is the common range of their activi- ties. They do not always return to the same pools from which they issued, any similar pool or stream is good enough for ovi- Fig. 195.—Method of withdrawing the digestive tube of the mosquito for study (Blanchard). position. After having deposited the first lot of eggs, the female is ready to feed again and produce a new lot. This can go on for a number of broods. How long the insects can live, probably de- pends upon their activities. When actively engaged in reproductive activities they probably live a shorter time than when hibernating Fig. 196.—Method of withdrawing the salivary glands of the mosquito for study (Blanchard). or estivating. It is known that some of them can live the greater part of a year. The mosquitoes used for study and for classification should be mounted dry in the usual way well known to all entomologists. _ Fine entomologic pins (00-000) should be employed for the purpose. The insects should be caught in a wide-mouth bottle containing some fragments of cyanid of potassium, covered with a layer of sawdust, over which a thin layer of plaster of Paris is allowed to solidify. The insects die in a moment or two, can be emptied upon a table, and the pin carefully thrust through the central Mosquitoes and Malarial Fever 493 part of the thorax. As soon as the insect is impaled, the pin should be passed through an opening in a card or between the blades of a forceps until the insect occupies a position at the junction of the middle and upper third. The insect should not be touched with the fingers, as the scales will be brushed off and the limbs broken. Mounted insects must be handled with entomologic forceps, touching the pins only. Every insect thus mounted should have placed upon the pin, at the junction of the middle and lower thirds, a small bit of card or paper, telling where and when and under what circumstances it was taken. The dissection of fresh mosquitoes for determining whether or not they are infected with malarial organisms must be made with the aid of needles mounted in handles. The position of the stomach, intestines, and the salivary glands, and the mode of pulling the insect apart to show them can be learned from the diagram. The organs thus withdrawn and separated from the unnecessary tissue can be fixed to a slide with Meyer’s glycerin-albumin or other albuminous matter, and then stained like a blood-smear, but should be cleared after staining and washing, and mounted in Canada balsam under a cover-glass. Fig. 197.—Imago of Anopheles maculipennis escaping from the pupa case upon the surface of the water (Brumpt). A more certain and more elegant manner of showing the parasites in infected mosquitoes is by pulling off the legs and wings, embedding the insect in paraffin and cutting serial longitudinal vertical sections. _ To infect mosquitoes and study the development of the malarial parasites in their bodies, the insects should be bred from the aquatic larva in the laboratory, to make sure that they do not already harbor parasites. The mosquitoes are allowed to enter a small cage made with mosquito netting, and are taken to the bedside of the malarial patient, against whose skin the cage is placed until the insects have bitten and distended themselves with blood, when they are taken back to the laboratory, kept as many days as may be desired, then killed and sectioned. In this way, remembering that the entire mosquito cycle of de- velopment takes about a fortnight, any stage of the cycle may be observed. CHAPTER XX RELAPSING FEVER SPIRILLUM OBERMEIERI OR SPIROCHAZTA OBERMEIERI OR SPIRO- CHZTA RECURRENTIS (OBERMEIER) General Characteristics.—An elongate, flexible, flagellated, non-sporogenous, actively motile spiral organism, pathogenic for man and monkeys, susceptible of cultivation in special media, stained by ordinary methods, but not by Gram’s method. In 1868 Obermeier* first observed the presence of actively motile spiral organisms in the blood of a patient suffering from relapsing fever. Having made the observation, he continued to study the organism until 1873, when he made his first publication. From 1873 until 1890 it was supposed-that spirocheta rarely played any patho- genic réle. Miller} had, indeed, called attention to the constant presence of Spirocheta dentinum in the human mouth, but it had not been connected with any morbid condition. In 1890 Sacharofft discovered a spirillary infection of geese in the Caucasus, caused by an organism much resembling Spirocheta obermeieri and called Spirocheta anserinum. In 1903 Marchoux and Salimbeni§ found a third disease, fatal to chickens, caused by Spirocheta gallinarum, and found that the spread of the disease was determined by the bites of a tick, Argas miniatus. In 1902 Theiler,|| in the Transvaal, observed a spiral organism in a cattle plague. This has been named. after him by Laveran, Spirocheta theileri. It was found to be disseminated by the bites of certain ticks—Rhipicephalus decolor- atus. Later, what was probably the same organism, was found in the blood of sheep and horses. In 1905 Nicolle and Comte** found a spiral organism infecting certain bats. By this time, therefore, it became evident that spirochetal infections were fairly well dis- seminated among the lower animals and that the spirocheta were of different species with different hosts and intermediate hosts. In 1904 Ross and Milnett+ and Dutton and Toddff studied a peculiar African fever which they were able to refer to a spirocheta *“Centralbl. f.:d. med. Wissenschaft,” 1873. { Microorganisms of the Human Mouth, Phila., 1890, p. 44 et seq. t “Ann. de l’Inst. Pasteur,” 1891, xvi, No. 9, p. 564. § Ibid., 1903, XVII, p. 569. || “Jour. Comp. Path. and Therap.,” 1903, XLVIt, p. 55. ** “Compt.-rendu de la Soc. de Biol. de Paris,” July 22, 1905, LIX, p. 200. tt “British Med. Jour.,” Nov. 26, 1904, p. 1453. ; tt “Memoir xv, Liverpool School of Tropical Medicine,” “Brit. Med. Jour.,”’ Nov. 11, 1905, p. 1259. 494 Relapsing Fever 495 for which Novy* has proposed the name Spirocheta duttoni in memory of Dutton, who lost his life while studying it. In 1905 Kocht while working in Africa discovered a spirocheta that he re- garded as identical with that already described by Ross and Milne and Dutton and Todd. Later studies of the organism convinced C. Frinkel{ that it was a separate species. For it Novy later sug- gested the name Spirocheta kochi. In 1906 Norris, Pappenheimer and Flournoy§ found a spirocheta in the blood of a patient suffering from relapsing fever in New York. This having been extensively studied by Novy, has since been called Spirocheta novyi. With the work of Schaudinn and his associate, Hoffmann,]| the spirocheta came to be regarded as protozoan parasites because of the presence of an undulating membrane; the refusal of most of the organisms to grow upon artificial media, the réle of an inter- mediate host (ticks, etc.) in transmitting them, and the longitudinal mode of division. Fevers characterized by relapses and by the presence of spiro- Fig. 198.—Spirocheta obermeieri from human blood (Kolle and Wassermann). cheta in the blood have been found in northern and northeastern Europe (true relapsing fever with Spirocheta obermeieri), in various parts of equatorial Africa (African relapsing fever with Spirocheta duttoni); in North Africa (Spirocheta berbera); in Bombay and in other parts of India (Spirocheta carteri); in Persia (Spirocheta persica); and in America (Spirocheta novyi). The question, there- fore, arises whether these similar diseases are slight modifications *‘ Jour. Infectious Diseases,” 1906, II, p- 295. t“D J een iy i es i ini eutsche med. Wochenschrift,’’ 1995, XxxI, p. 1865; ‘Berliner klinische Wochenschrift,” 1906, XLII, 185. Med. klin.,” 1907, 111, 928; “Miinchener med. Wochenschrift,” 1907, LIV, 201. fescue Infectious Diseases,” 1906, 111, 266. Il “Deutsche med. Wochenschrift,” Oct., 1905, XXXI, p. 1665; “Arbeiten aus dem kaiserlichen Gesundheitsamte,” 1904, XX, Pp. 387-439. 496 Relapsing Fever of the same thing caused by the same parasite, or whether they are different diseases caused by slightly different parasites. If Nuttall be correct, there are no adequate grounds upon which to conclude that the spirochetes are really different species. On this account, and as the differences between the organisms are minute, it scarcely seems well to devote space to the consideration of each, but better to select the oldest and the best known—Spiro- cheeta obermeieri—as the type, describe it, and then point out such variations as are shown by its close relations. Morphology.—The Spirocheta obermeieri is extremely slender, flexible, spirally coiled, like a corkscrew, and pointed at the ends. Fig. t99.—Spirocheta obermeieri (Novy). Rat blood No. 321a. X r500. It measures approximately 1 w in breadth and 10, 20, or even 40 in length. The number of spiral coils varies from 6 to 20; the di- ameter of the coils varies so greatly that scarcely any two are uni- form. Wladimiroff* doubts the existence of a flagellum, but flagella- like appendages are usually to be seen at one or both ends of the organisms. An undulating membrane attached nearly the entire length of the organism, very narrow, and inconspicuous, forms the chief means of locomotion. The organism is actively motile, and darts about in fresh blood with a double movement, consisting of rotation about the long axis and serpentine flexions. No structure can be made out by our present methods of staining and examining the spirocheta. No spores are found. Multiplication is thought to take place by longitudinal division, though some believe the di- vision to be transverse. *“Kolle and Wassermann’s Handbuch der pathogene Mikroérganismen,” 1903, III, p. 82. Cultivation 497 The Spirocheta duttoni is said by Koch,* in his interesting studies of ‘African Relapsing Fever,” to resemble the Spirocheta obermeieri in all particulars. The Spirocheta novyi with which Novy and Knappf experi- mented, and which they believed to be identical with Spirocheta obermeieri, measured 0.25 to 0.3 w in breadth by 7 to 19 w in length. The number of coils varies from three to six. The shorter forms are pointed, with a long flagellum at one end and a short one at the other. Staining—The spirocheta can be stained with ordinary anilin dye solutions, by the Romanowsky and Giemsa methods, and by the silver methods (see Treponema pallidum). It does not stain by Gram’s method. Fig. 200.—Spirocheta duttoni (Novy).- Tick fever, No. 520. Rat blood. X 1500. Cultivation.— Following the suggestion of Levaditi, Novy and Knappf cultivated Spirocheta obermeieri in collodion sacs in the abdominal cavity of rats, and succeeded in maintaining it alive in this way through twenty consecutive passages during sixty-eight days. They were able to do this in rat serum from which all cor- puscles had been removed by centrifugation, and so proved that no Intercellular developmental stage of the organism takes place. Organisms thus cultivated attenuate in virulence. _ Norris, Pappenheimer, and Flournoy§ believe that they succeeded In securing multiplication of the spirocheta by placing several drops * “Berliner klin. Wochenschrift,” Feb. 12, 1906, xxxtv, No. 7, p. 185. a Jour. Infectious Diseases,” 1906, II, p- 291- { “Jour. Amer. Med. Assoc.,” Dec. 29, 1906, XLVII, p. 2152. § “Journal of Infectious Diseases,” 1906, I, 266. 32 498 Relapsing Fever of blood containing them in 3 to 5 cc. of citrated rat or human blood. A third generation always failed. Noguchi* was the first to achieve the successful cultivation of the spirocheta in artificial culture media. The best success was obtained as follows: Into each of a number of sterile test-tubes 2 X 20cm. in size is placed a fragment of fresh sterile rabbit kidney and then a few drops of citrated blood from the heart of an infected mouse or rat. Following this, about 15 cm. of sterile ascitic or hydrocele fluid are quickly poured into the tubes and the contents of some of the tubes are covered with a layer of sterile paraffine oil, while the rest are left without the oil. The tubes are placed in the incubating oven at 37°C. By these means cultures of Spiro- cheta duttoni, Spirocheta kochi, Spirocheta obermeieri and Spiro- cheta novyi were secured. The maximum growth was obtained in 7,8 org days at 37°C. The presence of some oxygen seemed to be essential. By transplantations to fresh media of the same kind they were all kept growing for many generations during which they did not lose their virulence. Mode of Infection—The means by which Spirocheta obermeieri is transmitted from individual to individual is not definitely known. Tictin} seems to have been the first to believe that the transmission of the disease was accomplished through the intermediation of some blood-sucking insect. He investigated lice, fleas, and bed-bugs, in the latter of which he was able to find the organisms, and through blood obtained from which he was able to transmit the disease to an ape. He was not able to infect apes by permitting infected bed-bugs to bite them. Breinl and Kinghorn and Todd{ madea careful study of the subject, but, like Tictin and their other prede- cessors, were unable to infect monkeys by permitting infected bed- bugs to bite them. Mackie, § Graham-Smith, || Bousfield,** Ed. Sergent and H. Foley, tt studied the louse and found that it was undoubtedly capable of acting as a transmitting agent, and possibly was the only definitive host of the parasite. Nicolle, Blaizot and Conseil{{ studied the North African relapsing fever of Tunis and Algeria, and proved that the body and head lice are undoubtedly the common definition hosts of its spirochete. When the lice were fed upon blood of infected patients, the spirochetes rapidly disappear in their bodies, but after eight days reappear and remain for almost twelve days during which time the insects can transmit the disease. They alsofound that the *“Tournal of Experimental Medicine,” 1912, xvI, 199. + “Centralbl. f. Bakt. u. Parasitenk.,” 1894, 1 Abt., xv, p. 840. t Ibid., Oct., 1906, xi, Heft 6, p. 537. § “Brit. Med. Jour.,” Dec. 14, 1907. | ‘Ann. de l’Inst. Pasteur,” 1910, p. 63. ** Report of the Wellcome Tropical Research Laboratories, 1911, p- 63- Tt “Ann. de l’Inst. Pasteur,” 1910, p. 337- tt “Ann. de l’Inst. Pasteur,”’ Mar. 25, 1913, vol. xxvu, No. 3, p. 204. Mode of Infection 499 infectious agent passes to a new generation of the lice, which are also infective. They also studied a tick, Ornithodorus savignyi, found in those countries, thinking that it might behave like Ornith- odorus moubata toward Spirocheta duttoni, and found that it could transmit the spirochete of the Tripolitan relapsing fever, though apparently not that of the Tunisian fever. When we come to consider Spirocheta duttoni, however, we find our knowledge much further advanced. On Nov. 26, 1904, Dutton and Todd announced that they had discovered a spirillum to be the specific agent in the causation of tick fever in the Congo, andon the same date Ross and Milne* published the same fact. Dutton and Todd subsequently withdrew their claim to priority of the discovery. On Feb. 4, 1905, Ross published in the “ British Medical Journal” the following cablegram from Dutton and Todd, then working on the Congo: ‘‘Spirilla cause human tick fever; naturally infected ornithodorus infect monkey.” It was not until Nov. 11, 1905, that the paper upon the subject was read and published in the same journal by Dutton and Todd, and the etiology of the dis- ease made clear. These observers found that the horse-tick, Ornithodorus moubata (Murray) is the intermediate host of the spirilla or spirocheta causing the disease, and that when these ticks were permitted to bite infected human beings, and then subsequently transferred to monkeys, the latter sickened with the typical infection. The matter received confirmation and addition through the studies of Koch,t who studied the ticks, observed the distribution of the micro-organisms in their bodies, and found that they collected in large numbers in the ovaries, so that the eggs were commonly in- fected and the embryo hexapod ticks hatched from them were in- fective. Not only is this second generation of ticks infected, but Miller has found the third generation also infected by the spiro- cheta, and it is not improbable that the infection is kept on passing from female to offspring through many generations. Leishman, who followed the spirocheta throughout the body of the tick, observed that it entered the ovaries and appeared in the ova in the spiral form, but that in the ova it not infrequently became trans- formed to “coccoid” granules which held together more or less closely like tiny streptococci. He supposed that it was in the granular form that the micro-organism found its wayintotheembryo and so infected the developing nymph. There is reason to believe that this was an error and that the spirals alone are the sources of transmission and infection. What is true of the tick seems to be equally true of the lice, the infective micro-organisms being passed down from generation to generation. Thus, in regard to Spirocheta duttoni we are able to say quite definitely that the tick is the usual if not the only means of dissemination. How the ticks and lice * “British Medical Journal,’ Nov. 26, 1904. t “Berliner klin. Wochenschrift,” Feb. 12, 1906. 500 Relapsing Fever effect the transmission of micro-parasites is to a certain extent in dispute. It was at first supposed that the spirochetes entered the human hosts with the saliva of the respective arthropods, but there is some reason to think that thisis a mistake, and that the scratch- ing of the itching bite conveys the spirocheta deposited upon the skin in the excrement of the arthropod, into the deeper layers and lymphatics through which it reaches the blood. Pathogenesis.—The spirocheta of relapsing fever are pathogenic for man and monkeys, some of them for smaller animals. Novy and Knapp* found their organism and Spirocheta duttoni to be infectious for mice and rats, and attribute the failure of others to discover this to their failure to examine the blood during the first and second days. Fulleborn and Meyer, and Martinf were able successfuly to transmit the spirocheta of Russian relapsing fever to mice after first passing it through apes. Rabbits and guinea- pigs seem to be refractory; white mice susceptible. Man, monkeys, and mice suffer from infection characterized by relapses, and in them the disease may be fatal. Rats never die of the disease and rarely have relapses. The micro-organisms are free parasites of the blood in which they swim with a varying rapidity, according to the stage of the disease. They are present during the febrile paroxysms only, disappearing completely as soon as the crisis is reached. The course of relapsing fever in man is peculiar and characteristic. After a short incubation period the invasion comes on with chill, fever, headache, pain in the back, nausea and vomiting, and some- times convulsions. The temperature rises rapidly and there are frequent sweats. The pulse is rapid. By the second day the tem- perature may be 104° to 105°F. and the pulse 110 to 130. There is enlargement of the spleen. Icteroid discoloration of the conjunc- tiva may be observed. The fever persists with severity and the patient appears very ill for five or six days, when a crisis occurs, and the temperature returns to normal; there is profuse sweating and sometimes marked diarrhea, and the patient at once begins to improve. So rapid is the convalescence that in a few days he may be up and may desire to go out. The disease is, however, not at an end, for on or about the fourteenth day the relapse characteristic of the affection makes its appearance as an exact repetition of what has gone before. This is followed by another apyretic interval, and then by another relapse, and so on. The patient usually re- covers, the mortality being about 4 per cent. The fatal cases are usually old or already infirm patients. The Indian, African, and American varieties present variations of no great importance. The European fever usually ends after the second or third relapse, the African not until after a greater number. * Loc. cit. Tt Loc. cit. The Vectors of Relapsing Fever 501 The spirocheta are present in the blood in great numbers during the febrile stages, but entirely disappear during the intervals. Lesions.—-There are no lesions characteristic of relapsing fever. Bacteriologic Diagnosis.—This should be quite easily made by an examination of either the fresh or stained blood, provided the blood be secured during a febrile paroxysm. The readiness with which the organisms take the stain leaves little to be desired. Novy and Knapp have found that the serum of recovered cases can be used to assist in making diagnosis because of its agglutinating, germicidal, and immunizing powers. Immunity——The phenomena of immunity are vivid and im- portant. At the moment of decline of the fever a powerful bacterio- lytic substance appears in the blood and dissolves the organisms. At the same time an immunizing substance appears. The two do not appear to be the same. The immunizing body affords future protection to the individual for an indefinite length of time. It can be increased by rapidly in- jecting the animal with blood containing spirocheta. Serum con- taining the immunizing body imparts passive immunity to other animals into which it is injected, and, according to Novy and Knapp, establishes a solid basis for the prevention and cure of relapsing fever in man. THE VECTORS OF RELAPSING FEVER I. Ticks The ticks thus far known to act as vectors of relapsing fever are two species of the genus Ornithodorus. Thirteen species of this genus are described in “‘A Text-book of Medical Entomology,” by Patton and Cragg, who give excellent tables for their identification and additional valuable information is to be found in the excellent “Monograph of the Ixodoidea,”’ by Nuttall. Ornithodorus ticks of various species are to be found pretty widely distributed throughout tropical and semitropical regions of both hemispheres. In general, they are most numerous where the temperature is highest and the soil driest. The genus Ornithodorus was described by C. L. Koch and characterized as follows: “‘The body is flat when starving and convex when replete, and may be nearly as broad anteriorly as posteriorly, or pointed and beak-like anteriorly. The margin of the body is not distinct but is of a similar structure to the rest of the integument which is generally mamillated. On the ventral surface there are two well-marked folds; one internal to the coxe, the coxal fold, and the other above the coxe, the supracoxal fold; there is also a transverse pre-anal groove, as well as a transverse postanal groove. Eyes are either absent or present in pairs on the supracoxal fold; one pair between coxe I and II, and the other between coxe ITI and IV. : The Ornithodorus savignyi is the transmitting agent of Spirocheta berbera; Ornithodorus moubata of Spirochzta duttoni. Ornithodorus savignyi—The description given by Patton and Cragg (‘‘A Text- book of Medical Entomology,” 1913, p. 586) is as follows: Integument leathery and covered by distinct non-contiguous mammille and numerous short hairs interspersed. Supracoxal folds well marked, with two eyes on each side. Coxal folds less well marked. Pre-anal groove distinct. The basis capituli broader than long and shorter than the rest of the rostrum. Hypostome with 8lx principal rows of teeth, the external the stoutest. Palps with first andsecond Segments of equal length, third segment the shortest. Coxe contiguous; pro- tarsus and tarsus of legs I, II and III with three well-marked humps; the two proximal humps on tarsus of leg IV are close to each other, while the third is 502, Relapsing Fever separated by an interval of about two and a half times the distance between the first and second. Length 5-12 mm. Width 4-8.5 mm. The female and male resemble each other except that the latter are smaller. Its genital orifice is markedly smaller. In the female the genital orifice is a broad transverse slit which can be made to gape and is guarded by two flaps like valves; in the male the orifice is oval and the valves are absent. The eggs number 50-100, measure 1.3-1.5 mm. in length and o.8-1 mm. in breadth. They are oval, smooth and of a dark brown or black color. a b Fig. 201.—Ornithodorus moubata. Tick that transmits African relapsing fever: a, Viewed from above; b, viewed from below (Murray from Doflein). Fig. 202.—Ornithodorus savignyi. An, anus; cam, camerostome; cx.J, coxa I; cx.II, coxa II; cx.III, coxa III; cx.IV, coxa IV; cx.f., coxal fold; e, eye; g.a., genital aperture; g.g., genital groove. Habitat.—Arabia, Nubia, Egypt, Somaliland, Abyssinia, German East Africa, Cape Colony, Rhodesia, Bechuanaland and Portuguese East Africa. In Indiait is common in the Madras Presidency, in Gujarat, and in many parts of the Bombay Presidency. In Aden it is widely distributed throughout the Hinter- land, where its principal host is the camel. Ornithodorus moubata.—Patton and Cragg describe this tick as follows: Body almost as broad anteriorly as posteriorly; covered with non-contiguous mamille, but with fewer hairs than savignyi. Basis capituli broader than long and shorter than the palps; hypostome with six principal rows of teeth. Tarsiof legs I, II and III with three humps as in savignyi; those on the pro-tarsus are The Vectors of Relapsing Fever 503 Female Male a I» | | | : | c d i Ovum or nit Embryo Fig. 203.—Pediculus capitis, or head-louse. X10. a, Female; 6, male;c, egg cemented to a hair; d) nymph. (From Beattie and Dickson’s “A Text-book of General Pathology,” by kind permission of William Heinemann, Publisher.). Male Female Embryo Ovum Fig. 204.—Pediculus vestimenti, the clothes or body louse. X10. a, Male, b, female; c, nymph; d, egg. (From Beattie and Dickson’s “A Text-book of General Pathology,” by kind permission of William Heinemann, Publisher.) 504 Relapsing Fever subequal, more pointed and about equidistant, while those of savignyi are unequal, less pointed and not equidistant. The tarsus of leg IV in moubata is shorter and thicker than in savignyi, and its humps are nearly equidistant. Eyes absent. Length 8-12 mm.; breadth 6-10 mm. The eggs are ovoid, meas- ure o.8-o.9 mm. in length, are smooth on the surface and dark yellow in color. Habitat.—Africa: from British East Africa to the Transvaal, and across to the Congo; southward. to German East Africa and Cape Colony. It is common in Egypt, Abyssinia and in parts of Somaliland and in Portuguese East Africa. - Ornithodorus savignyi is chiefly a parasite of the camel and only occasionally bites man; Ornithodorus moubata is essentially a human pest. The eggs of these ticks hatch in eight to fourteen days. The larval stage which has sixlegsis spentin the eggs and the creature that emergesis usually a first nym- phalinston, which has eight legs. After hatching it remains inactive for several days, then becomes very active and ready tosuck blood. As it growsit becomes voracious, distending itself with blood, then dropping off, hiding itself for a time, Male . Female Fig. 205.—Pediculus pubis, Phthirius inguinalis or crab-louse. 17. (From Beattie and Dickson’s “‘A Text-book of General Pathology,” by kind permission of William Heinemann, Publisher.) molting, then being ready to feed again. This continues for a number of months, the ticks molting four times before passing from the nymph to theadult stage. : Ornithodorus moubata is a common inhabitant of the native African huts along the caravan routes. To avoid it and escape relapsing fever R. Koch in his African expedition camped near but not in the villages, and avoided the native houses. It lives in the cracks in the mud walls, in the thatch, in the mats and sometimes simply upon the ground where its small size and dull color make it difficult to see. From these hiding places it crawls at night and like a bed-bug attacks the sleeping host, When handled it feigns death, remaining quiet for so long a time that it is hard to believe it alive. The Ornithodorus savignyi is less adapted to the requirements of the spiro- cheta than its relative. Brumpt* found that the spirocheta did not pass through the eggs of O. savigyni to subsequent generations, and that the in- fectivity of the tick itself soon was lost. The spirochete remain indefinitely in O. moubata, and are passed through their eggs to at Jeast three generations. It is, therefore, difficult to be certain that any particular tick is uninfected unless its progenitors be known. The spirocheta pass from female to the ovum and infect the young nymphs as such. The granules observed in the eggs of infected ticks, also occur in those of non-infected ticks and have nothing to do with the spirocheta. ” *“Precis de Parasitologie,” 1910, 538. The Vectors of Relapsing Fever 505 II. Lice Lice are apterous insects formerly classed in the order Hemiptera, but now placed in a separate order, the Anoplura. Two genera, and three species are common-upon human beings. | I. Pediculus (Linn, 1758). In this genus there are two species: 1. Pediculus capitis (de Geer, 1778). This is the head-louse. Itis of a gray color. The abdomen is composed of eight and not of seven segments as was stated by Piaget, and is blackened along the edges. The males and females look much alike, hut the male measures 1.8 mm. in length and 0.7 mm. in breadth, while the female measures 2.7 mm: in length by 1 mm. in breadth. These parasites live in the hair, close to the scalp. Rarely they pass from the scalp to the beard. Still more rarely do they occur upon other hair-covered surfaces. The female produces large eggs, one at a time, which are firmly anchored to the hairs by a mucilaginous secretion. Inthem the embryo develops in about sixteen to eighteen days then escapes as a nymph with proportionally smaller body and larger legs than the adult. There are three molts before the insect reaches maturity. The full and empty eggs occur in great numbers upon the hairs and are known as “nits.” The insects are sometimes present on the head in great numbers and cause intolerable itching. 2. Pediculus vestimenti (Nitzsch, 1818). This is a larger louse of much the same appearance and structure as P. capitis. Indeed there are such minute differences between the two that there issome dispute as to whether they should not form subspecies of the same insect instead of different species of insects. ‘ The size is, however, larger. The male measures 3 mm. in length and 1 mm. in breadth; the female 3.3 mm. in length and 1.14 in breadth. The ‘“‘body louse” as this is commonly called, lives in the clothing, and passes to the skin to feed, then returns again to the seams of the garments. Its eggs are fastened to the fabric of the clothing, not to the skin or hairs. It is sometimes present in great numbers and its bites cause much annoying itching. Both of these lice have been found to be capable of effecting the transmission of the spirocheta of relapsing fever. The infection in the lice is transmitted to its offspring as in the case of Ornithodorus moubata. ; II. Phthirius (Leach, 1815). In this genus there is only one human parasite. Phthirius inguinalis (Ridi, 1668). This pubic louse or “‘crab louse”’ is often incorrectly called Pediculus pubis. It is a shorter, stouter- bodied creature with more powerful legs terminating in large tarsal hooks that give it a crab-like appearance. The thorax and abdomen are compressed and shortened to a heart-like body. The abdomen is composed of six segments, each of which has a pair of stigmata, but the stigmata of the first, second, third, fourth, and fifth segments ap- pear to be inone broad segment. The males measure 1 mm. inlength, the females 1.5mm. These licelive chiefly in the pubic hair and that of the perineum. Rarely they are found in the axilla, the beard, the eye-brows and even upon the eye-lashes. The eggs are fixed to the bases of the hairs as in P. capitis. They hatch in about seven days and the nymphs grow to maturity fifteen days later. '_ The bites of these lice are very irritating and cause severe itching and the eruption of pink papules that sometimes become bluish spots nearly a centimeter in diameter. Such spots known as “ “taches ombrées”’ are frequent in typhoid fever when lice are present. It is not known that this louse can harbor spirocheta or any patho- genic bacteria or protozoa. CHAPTER XXI SLEEPING SICKNESS TRYPANOSOMA GAMBIENSE (DUTTON) TRYPANOSOMA RHODESIENSI (STEPHENS AND FANTHAM) SLEEPING sickness, African lethargy, Maladie du sommeil, Schlafkrankheit, or human trypanosomiasis is a specific, infectious, endemic disease of equatorial Africa characterized by fever, lassi- tude, weakness, wasting, somnolence, coma, and death. The first mention of the disease seems to have been made by Winterbottom.* Sir Patrick Mansonf says that “For upward of a century students of tropical pathology have puzzled over a peculiar striking African disease, somewhat inaccurately described by its popular name, the sleeping sickness. Its weirdness and dreadful fatality have gained for it a place not in medical literature only, but also in general literature. The mystery of its origin, its slow but sure advance, the prolonged life in death that so often characterizes its terminal phases, and its inevitable issue, have appealed to the imagination. of the novelist, who more than once has brought it on his mimic stage, draping it, perhaps, as the fitting nemesis of evil-doing. The leading features of the strange sickness are such as might be pro- duced by a chronic meningo-encephalitis. Slow irregular febrile disturbance, headache, lassitude, deepening into profound physical and mental lethargy, muscular tremor, spasm, paresis, sopor, ulti- mately wasting, bed-sores, and death by epileptiform seizure, or by exhaustion, or by some intercurrent infection. “In every case the lymphatic glands, especially the cervical, are enlarged, though it be but slightly. In many cases pruritus is marked. In all, lethargy is the dominating feature. “In some respects this disease, which runs its course in from three months to three years from the oncoming of the decided symp- toms, resembles the general paralysis of the insane. It differs from this, however, in the absence, as a rule, of the peculiar psychic phenomenon of that disease. There are exceptions, but generally, though the mental faculties in sleeping sickness are dull and slow acting, the patient has no mania, no delusions, no optimism. So far is the last from being the case, that he is painfully aware of his con- dition and of the miserable fate that is in store for him; and he looks as if he knew it.” * «An Account of Native Africans in the Neighborhood of Sierra Leone,” 1803. { “‘The Lane Lectures for 1905,”’ Chicago, 1905. 506 Specific Organism 507 Specific Organism.—The discovery of the specific organisms was foreshadowed by Nepveu,* who recorded the existence of try- panosomes in the blood of several patients coming from Algeria, by Barron,} and by Brault.t In 1g90r Forde received under his care at the hospital in Bathurst (Gambia), a European, the captain of a steamer on the River Gambia, who had navigated the river for six years, and who had suffered several attacks of fever that were looked upon as malarial. The examination of his blood revealed the presence not of malarial parasites, but of small worm-like bodies, concerning the nature of which Forde was undecided.§ Later, Dutton, in conjunction with Forde, examined this patient, whose condition had become more serious, and recognized that the worm- like bodies seen by Forde were trypanosomes. Of these parasites he has written an excellent description, calling them Trypanosoma Fig. 206.—Trypanosoma gambiense (Todd). gambiense.|| The patient thus studied by Forde and Dutton died in England January 1,1903. In 1903 Dutton and Todd** examined tooo persons in Gambia and found similar trypanosomes in the bloods of 6 natives and 1 quadroon. In the same year Mansonj{{ discovered 2 cases of trypanosomiasis in Europeans that had be- come infected upon the Congo. Brumpt{f{ also observed T. gam- biense at Bounba at the junction of the Ruby and the Congo, and Baker§§ observed 3 cases at Entebbe in Uganda. During all this time no connection was suspected between these * “Memoirs, .Soc. de Biol. de Paris,” 1891, p. 49- } “Transactions of the Liverpool Medical Institute,” Dec. 6, 1894. 1“ Janus,” July to August, 1898, p. 41. ¥ “Trypanosomes and Trypanosomiasis,” Laveran and Mesnil, 1907. || See Forde, “Jour. Trop. Med.,” Sept. 1, 1902; Dutton, Ibid., Dec. 1, 1902; Dutton, “Thompson-Yates Laboratory Reports,” 1902, V, 4, part Il, p. 455. _** “First Report of the Trypanosomiasis Expedition to Senegambia,” 1902, Liverpool, 1903. ; tt “Jour. Trop. Med.,” Nov. 1, 1902, and March 16, 1903; “Brit. Med. Jour.,” May 30, 1903. tt “Acad. de Med.,” March 17, 1903. §§ “Brit. Med. Jour.,” May 30, 1903. 508 Sleeping Sickness micro-organisms and African lethargy, and much interest was being taken in a coccus—the hypnococcus—that was being studied by Castellani in Uganda. As Castellani was prosecuting the investi- gation of this organism, he chanced to examine the cerebro-spinal fluid of several negroes in Uganda who were suffering from sleeping sickness, and in it found trypanosomes. Even then, though Cas- tellani* realized that these organisms were connected with sleeping sickness, he did not identify them in his mind with the Trypano- Fig. 207.—Various species of trypanosomes: 1, Trypanosoma lewisi of the rat; 2, Trypanosoma lewisi, multiplication rosette; 3, Trypanosoma lewisi, small form - resulting from the disintegratoin of arosette; 4, Trypanosoma brucei of nagana; 5, Trypanosoma equinum of caderas; 6, Trypanosoma gambiense of sleeping sick- ness; 7, Trypanosoma gambiense, undergoing division; 8, Trypanosoma theileri, a harmless trypanosome of cattle; 9, Trypanosoma transvaliense, a variation of I. theileri; 10, Trypanosoma avium, a bird trypanosome; 11, Trypanosoma damonie of a tortoise; 12, Trypanosoma solee of the flat fish; 13, Trypanosoma granulosum of the eel; 14, Trypanosoma raje of the skate; 15, Trypanosoma rota- feat : frogs; 16, Cryptobia borreli of the red-eye (a fish). (From Laveran and esnil. : * Tbid., May 23, 1903; June 20, 1903. Morphology 509 soma gambiense discovered in the blood by Forde and Dutton, and described the newly discovered organism as Trypanosoma ugan- dense. Kruse,* thinking to honor the discoverer, called it Try- panosoma castellani. Bruce and Nabarrof found the new try- panosome in each of 38 cases of sleeping sickness in the cerebro- spinal fluid, and 12 out of 13 times in the blood. These observers also found that 23 out of 28 natives from parts of Uganda where sleeping sickness is endemic had trypanosomes in their blood, while in 117 natives from uninfected areas the blood examination was negative in every case. They also declared that, contrary to what had been stated, there were no appreciable morphologic differences between Trypanosoma gambiense and Trypanosoma ugandense. Dutton, Todd, and Christy{ arrived at the same conclusion. The matter was finally settled by Thomas and Linton§ and Laveran,]|| who, by means of animal experiments, determined not only the complete identity of the organisms, but their uniform virulence. Early in 1910 J. W. W. Stephens** studied the blood of a rat in- oculated with blood from a patient suffering from sleeping sickness, with which he had become infected in North Eastern Rhodesia, and observed certain definite morphological differences between trypanosomes in it, and Trypanosoma gambiense. Later he and Fantham{} studied this organism with great care and came to the conclusion that it was a new and separate species, and gave it the name Trypanosoma rhodesiense. In this they received the support of Mesnil.tt Morphology.—Trypanosoma gambiense is a long, slender, spindle-shaped, flagellate micro-organism that measures 17 to 28 u in length and 1.4 to 2 min breadth. From the anterior end (that which moves forward as the organism swims) a whip-like flagellum projects about half the length of the organism. The terminal third of the flagellum is free in most cases. The proximal two- thirds are connected with a band of the body substance, which is” continued like a ruffle along one side of the organism to within a short distance of its blunt posterior end, where the flagellum abruptly ends at the blepharoplast. This thin ruffle is known as the un- dulating membrane. By means of the flagellum and the undulat- ing membrane the organism swims rapidly with a wriggling and rotary movement that gives it the name Trypanosome, which means “boring body.” * “Gesell. f. natur. Heilkunde,” 1903. t “Brit. Med. Jour.,” Nov. 21, 1903. fIbid., Jan. 23, 1904, also “ Thompson-VYates and Johnson Lab. Reports,” 1905, V, 6, part 1, pp. 1-45. “Lancet,” May 14, 1904, pp. 1337-1340. | “‘Compt.-rendu de Acad. des Sciences,” 1906, V, 142, P. 1056. . British Medical Journal,” ro12, 1, 1182. tt Proceedings of the Royal Society,” 1910, LXXXIII, 28, 31; 1912, LXXXV, 223; Bulletin of the Sleeping-sickness Bureau,’ 1911-1912, Nos. 33, 38. tt “Brit. Med. Jour.,”” 1912, It, 1185. * 510 _ Sleeping Sickness The protoplasm is granular and often contains chromatin dots that are remarkable for their sizeand number. There is a distinct nucleus of ovoid form that is always well in advance of the centrosome or blepharoplast, and not infrequently is near the center of the organism. There is also a centrosome or blepharoplast, which appears as a distinct, deeply staining dot near the posterior blunt end and from which the flagellum appears to arise. Near this a vacuole is sometimes situated. Trypanosoma rhodesiense differs from Trypanosoma gambiense in that the nucleus is never near the center, rarely far in advance of the blepharoplast, and not infrequently is posterior to the blepharoplast. Staining.—The organisms arte best observed when stained with one of the polychrome methylene-blue combinations—Leishman’s, Wright’s, Jenner’s, Romanowsky’s, Marino’s. To stain them a spread of the blood or cerebro-spinal fluid is made and treated pre- cisely as though staining the blood for the differential leukocyte count or for the malarial parasite. Cultivation.—Trypanosoma lewisi of the rat and Trypanosoma brucei of “‘nagana”’ or ‘‘tsetse-fly”’ disease of Africa have been culti- vated by Novy and McNeal* in mixtures composed of ordinary culture agar-agar and defibrinated rabbit-blood, combined as necessary, I:1, 2:1, 1:2, or 2:3, etc. Theactual culture was made chiefly in the water of condensation collected at the bottom of obliquely congealed media. Laveran and Mesnil found that when blood containing Try- panosoma gambiense was mixed with salt solution or horse-serum, the trypanosomes remain alive for five or six days at the temperature of the laboratory. They live much longer in tubes of rabbit’s blood and agar, sometimes as long as nineteen days, and during this time many dividing forms but no rosettes were observed. But subcultures failed, and eventually the original culture died out. Bayonf has found it easy to cultivate Trypanosoma rhodesiense in Clegg’s ameba-agar (g.v.) and in blood agar-agar containing dextrose. The organisms thus cultivated retain their virulence for rats for a long time. Reproduction.— Multiplication takes place by binary division, the line of cleavage being longitudinal and beginning at the posterior end. The centrosome and nucleus divide, then the flagellum and undulating membrane divide longitudinally, and finally the proto- plasm divides, the two organisms hanging together for some time by the undivided tip of the flagellum. In addition to this simple longitudinal fission, the trypanosomes seem to possess a sexual mode of reproduction. When the well- stained organisms are carefully studied, it is possible to divide them aa Contributions to Medical Research dedicated to Victor Clarence Vaughan,” “Ann, Arbor, Michigan, 1903, p. 549; “ Journal of Infectious Diseases,” 1904, I, P- 1- } “Proc. Royal Society, Series B,” 1912, LXXXv, 482. Transmission 511 into three groups—those that are peculiarly slender, those that are peculiarly broad, and those of ordinary breadth. The fact that conjugation takes place between the first two has led to the opinion that they represent the male and female gametocytes respectively, while the others are asexual. All forms multiply by fission, and conjugation between the gametes is observed to take place only in the body of the invertebrate host. It has not yet been accurately followed in the case of Trypanosoma gambiense, but there is no reason to think that the organism differs in its method of reproduc- tion from Trypanosoma lewisi. Prowazek found that’ when rat blood containing the latter organism was taken into the stomach of the rat louse, Hematopinus spinulosus, the male trypanosome enters the female near the micronucleus and the various parts of _ the two individuals become fused. A non-flagellate odkinete re- sults, and, after passing through a spindle-shaped gregarine-like stage, can develop into an immature trypanosome-like form in the cells of the intestinal epithelium, after which the parasite is thought to enter the general body cavity, and, migrating to the pharynx, enter the proboscis, through which it is transmitted to a fresh host. Another form of multiplication consists in the “shedding” of ’ infective granules. This has beenstudied by Ranken.* The organ- isms from which this is about to take place are observed to. contain three or four, sometimes five or six granules of small size, highly refractile and spherical in shape. They are distinctly within the protoplasm of the trypanosome and swing backward and forward as it makes its lashing movements. When these are closely watched a time comes when one of the granules shoots out. At first the granule is carried about by whatever currents of fluid it happens to meet, having no motility of its own, but soon a dot appears, thena flagellum, and provided with means of locomotion, and now having a pyriform shape, the new embryo parasite swims away. Ranken thinks these granular forms develop in the internal organs and has found them of pyriform shape in the liver, spleen, and lungs. Transmission.—It is well known that the disease does not spread from person to person. In the days when African negroes were imported into America as slaves, the disease often reached our shores, and though freshly arrived negroes and those in the country less than a year frequently died of it, there was no spread of the affection to those that were acclimated. The Europeans that carried the disease from Africa to England and were the first in whose bloods the trypanosomes were found, did not spread it among their fellow countrymen. A case from the Congo that died in a hospital in Philadelphia and came to autopsy at the hands of the author, did not spread the disease in this city. * “Brit. Med. Jour.,” 1912, II, 408. 512 Sleeping Sickness Yet the disease is infectious, and the transfer of a small quantity of the parasite-containing blood to appropriate experiment animals perfectly reproduces it. The present knowledge of the mode of transmission came about through the knowledge of other trypanosome infections that had already been carefully studied and understood. In speaking of nagana, or tsetse-fly disease, Livingstone, as early as 1857, recognized that the flies had to do withit. For years, however, the supposition was that the fly was poisonous and that its venom was responsible for the disease. In 1875 Megnin stated that the tsetse-fly carries a virus, and does not inoculate a poison of its own. In 1879 Drysdale suggested that the fly might be an intermediate host of some blood parasite, or the means of conveying some infectious poison. In 1884 Railliet and Nocard, who suspected the same thing, proved Fig. 208.—Glossina _palpalis. A Fig. 209.—Glossina palpalis before perfect insect just escaped from the and after feeding (Brumpt). pupa (Brumpt). Showing how the wings close over one another like the blades of a pair of scissors. that inoculations with the proboscis of the tsetse-flies were harmless. . The exact connection between the flies and the disease was worked out by Bruce,* who found, first, that flies fed on infected animals, kept in captivity for several days, and afterward placed upon two dogs, did not infect; second, that flies fed on a sick dog, and imme- diately afterward on a healthy dog, conveyed the disease to the latter. The flies were infectious for twelve, twenty-four, and even for forty-eight hours after having fed on the infected animal. It was, therefore, shown that the flies could and did infect, not through something of which they were constantly possessed, but through something taken from the one animal and put into the other; this, of course, proved to be the trypanosome. Further; it was shown that where there were no tsetse-flies, there never was nagana. *“Preliminary Report on the Tsetse-fly Disease or Nagana in Zululand, Ubombo, Zululand,” Dec., 1895; ‘Further Report,” etc., Ubombo, May 29, 1896; London, 1897. Transmission 513 So soon as African lethargy was shown to be a form of trypano- somiasis, the question arose, Was it spread by tsetse-flies? Sambon* and Brumpt} both suggested it, but it was ‘soon discovered that the geographic distribution of the tsetse-fly, Glossina morsitans, that distributes nagana, does not coincide with the geographic distribu- tion of sleeping sickness. There are, however, different kinds of tsetse-flies, and Bruce and Nabarrot first showed that it was not Glossina morsitans, but a different tsetse-fly, Glossina palpalis, that is the most important source of the spread of human trypano- somiasis. They submitted a black-faced monkey (Cercopithicus) to the bites of numerous tsetse-flies caught in Entebbe, Uganda, and found trypanosomes in its blood. Bruce, Nabarro, and Greig§ allowed Glossina palpalis to suck the blood of negroes affected with sleeping sickness and afterward to bite five monkeys (Cercopithicus). At the end of about two months trypanosomes appeared in the blood of these monkeys. They also made maps showing the geographic distribution of African lethargy and of Glossina palpalis, which were found perfectly to correspond. But thenatural history of sleeping sicknessis less simple than these facts make it appear. Kinghorn and Yorke|| observed that in the Luangwa Valley where tsetse-flies (Glossina morsitans) abound, there is much game but few domestic animals. This led them to study the bloods of all the game animals in an attempt to discover how many harbored trypanosomes and what kind they were. The results are interesting, but two are of great importance in the present connection. They discovered that antelopes harbored Trypano- soma rhodesiense, and that it could be transmitted by Glossina morsitans. As Trypanosoma rhodesiense is the more virulent parasite, and as the antelope regularly harbors it and the widely distributed Glossina morsitans distributes it, the likelihood of an early and successful outcome of the campaign against sleeping sickness becomes improbable. The flies are found to become infective in from eleven to twenty- five days after consuming infected blood, and to remain so as long as they continue to live. Bruce, Hamerton, Bateman and Mackie, the members of the “Royal Society Sleeping-sickness Commission” for 1908-9** have found that under experimental conditions the development of the parasites takes place only in about 5 per cent. of infected flies. The shortest time in which their flies became infective was 18 days, the longest 53 days, the average 34 days. An infected fly was kept * OC Jour. Trop. Med.,” July 1, 1903. t“C. R. Soc. de Biol.,” Jan. 27, 1903. . ft “Reports of the Sleeping Sickness Commission of the Royal Society,” 1903, I, II, 11. Ibid., 1903, No. 4, VIII, 3. ie Brit. Med. Jour.,” 1912, 1, 1186. British Medical Journal,” 1910, 1, 1312. 33 514 Sleeping Sickness alive in the laboratory for 75 days and remained infective all that time. Experiments directed toward finding out how long the flies might remain infective in nature indicate that the flies may be able to transmit the parasites for at least two years. It is, of course, not impossible that other flies, especially other species of tsetse-flies, may act as distributing hosts of the trypano- somes, but there is no doubt about the chief agents being Glossina palpalis and Glossina morsitans. With increased entomologic and geographic information it has been found that there are certain districts where these flies abound though the disease is unknown, but that only shows that in those districts the flies are not infected. Tsetse-flies are not, as was formerly supposed, peculiar to Africa, but have been found in Arabia, where African lethargy could no doubt spread should the flies become infected through imported cases of the disease. The inability of the disease to spread in England and America depends upon the absence of tsetse-flies from those countries. It is possible for the disease to be transmitted from human being - to human being through such personal contacts as may afford oppor- tunity for interchange of blood. Thus, Koch observed that ia certain parts of Africa where there were no tsetse-flies the wives of men that had become infected in tsetse-fly countries sometimes developed the disease, probably through sexual intercourse, a probable explanation when one remembers that it is solely or chiefly by such means that a trypanosome disease of horses—Dourine or Maladie du coit, caused by Trypanosoma equiperdum—is transmitted. Transmission to Lower Animals.—Trypanosoma gambiense is infectious for monkeys as well as for human beings. In the monkeys — a disease indistinguishable from the sleeping sickness is brought about. It is also infective for dogs, cats, guinea-pigs, rabbits, rats, mice, marmots, hedgehogs, goats, sheep, cattle, horses, and asses. The lower animals are not, however, so far as is known, subject to natural infection. Trypanosoma rhodesiense, being a more virulent parasite than its close relative, probably infects a greater variety of animals. Among these, in nature, antelopes seem to be commonly infected. Pathogenesis.—The first effect of human trypanosomiasis seems to be fever of an irregular and atypical type, occurring in irregular paroxysms. It was in this early febrile stage of the disease that Forde and Dutton first found the trypanosomes in the circulating blood. The number of organisms in the peripheral circulation is, however, usually so small that it is tedious to look for them. The search may be made in thick smears stained by any blood stain, but it is better to proceed by washing the corpuscles in citrated blood as in preparing to calculate the opsonic index, and to collect the “leukocyte cream” for staining and examination. The trypano- Transmission to Lower Animals 515 somes, which seem to have much the same specific gravity of the leukocytes, appear in greatest numbers where the leukocytes collect. In African natives the trypanosomes may be present in the blood for a long time before any symptomsare discovered, but in Europeans their presence is soon followed by fever. As the infection progresses, the micro-organisms increase in great numbers in the organs, and almost entirely disappear from the blood. The lymph nodes swell and Winterbottom, who first described the disease, called particular _ attention to the enlargement of those of the posterior cervical triangle, which he regarded as of diagnostic significance. When the blood examination fails to reveal trypanosomes, they may frequently be found by puncturing an enlarged lymph node with a dry needle and examining the drop of fluid obtained. Wolbach and Binger* found that the trypanosomes invade the connective-tissue structure of all organs, the reticular tissue of lymph nodes and spleen, and the substance of the brain. The lesions are due to the presence of the flagellated form of the parasite in the tissues. They found the initial cell reaction to be the proliferation of endothelial cells. They believe the discovery of numerous intravascular mitoses of endothelial cells in the lung, liver, spleen and kidney to indicate the source of the increase of the large mono- nuclear leukocytes of the blood in human trypanosomiasis. Lymphocytosis is the rule in trypanosomiasis but is of no diag- nostic importance. As the invasion of the body continues, the trypanosomes dis- appear in large measure from the blood to multiply in the organs. In the spleen, in particular, the parasites assume a different form: a deep band makes its appearance between the nucleus and the blepharoplast. The former becomes surrounded by a large vacuole, and the trypanosome becomes disintegrated and reduced to a nucleus, which represents the latent form of the organism. The nucleus later divides giving rise to a new blepharoplast from which a new flagellum arises, an undulating membrane later forms, and the usual appearance of a trypanosome again develops. When perfected, this new trypanosome enters the circulating blood. At the time that the first indications of somnolence appear, the parasites are present in the cerebro-spinal fluid. The fluid is collected by the technic given in the chapter upon cerebro-spinal meningitis. To find the trypanosomes in the fluid, it should be rapidly centrifugalized for a few minutes and the whitish sediment collected, and examined imme- diately, when the micro-organisms may be studied alive, or the fluid may be spread upon slides and stained according to the technic for blood spreads, when, the trypanosomes being killed, fixed and stained, their structure can be studied to advantage. In studying the morbid anatomy of sleeping sickness, Mott came to the con- * “Jour. Med. Research,” 1912-1913, XXVII, 83. { “British Medical Journal,” Dec. 16, 1899, 0. 516 Sleeping Sickness clusion that the essential lesion is an extensive meningo-encephalitis. To the naked eye, there are scarcely any lesions in sleeping sickness, except the enlargement of the lymph nodes, and even in the nervous system when one looks with care, there is but little to be seen. The Fig. 210.—Photomicrograph of an eosin-methylene-blue-stained section; 1000 diameters. Shows trypanosomes about a small vessel of the cortex of the brain (Wolbach and Binger, in ‘‘ Jour. of Med. Research’’). histological examination of the nervous tissues, on the contrary, shows | that in both the brain and spinal cord there is proliferation and over- growth of neuroglia cells, especially those connected with the sub- | ie 904? HA Fig. 211.—Photomicrograph of Fig. 212.—Trypanosoma gambiense. a Giemsa-stained section; 1000 Formation of the latent stage and diameters, showing a trypano- transformation of the latent stage into some deep in the cortex of the a trypanosome (after Guiart). brain (Wolbach and Binger, in “Jour. of Med. Research”). arachnoid space and the perivascular space, with accumulation and probably proliferation of lymphocytes in the meshwork. Wohlbach and Binger found that the trypanosomes actually escape from the blood-vessels and make their way into the nervous tissue. The Prophylaxis 517 period of lethargy seems to coincide with that at which the parasites are invading and injuring the nervous tissue. Prophylaxis.—Reasoning from knowledge of the successful cam- paigns that have waged against yellow fever and paludism, it at first appeared as though the prophylaxis of sleeping sickness ought to be based partly upon measures taken to prevent the infection of men by tsetse-flies, and partly upon those taken to prevent the infection of the flies by men. To prevent the infection of men by the flies is extremely difficult where naked or half-naked savages are to be dealt with. For Europeans, the customary dress, the avoidance of exposure in bath- ing, the use of mosquito guards, etc., are to be recommended, as well as the erection of habitations and the building of roads, etc., as far as possible from the fly districts. The destruction of the grass and reeds along the river banks, the use of drainage, and the intro- © duction of chickens, to pick up the larve and pupe, have been recommended. To prevent infection of the flies with Trypanosoma gambiense is impossible where, as in some sections of Africa, 50 per cent. of the population of some of the villages already harbor the parasites, and still more impossible when, as is the case with Trypanosoma rhodesiense, the wild animals, especially antelopes which are ex- tremely numerous, continually harbor the parasites and act as reservoirs from which the flies receive a continuous supply. The importance of undertaking radical measures for the prevention of the disease may be imagined when it is understood that in the last few yearsnolessthan a half-million of the natives of the infected districts have died of sleeping sickness. TSETSE FLIES The Tsetse flies are dipterous insects belonging to the family Glossinine, and included in a single genus Glossina. With one exception, G. tachinoides, the entire family lives in tropical and subtropical Africa. About sixteen species of Glossina are now described, for the rough and ready identification of which the following table from Brumpt (‘‘Précis de Parasitologie” 1910, p. 630) will be found useful. For those who desire more accurate information, Austin’s “Handbook of the Tsetse Flies,” the “Sleeping Sickness Bulletin,” and Patton and Cragg’s “Text-book of Medical Entomology” will prove useful books of reference. Tsetse flies are easily recognized by their fly-like appearance, by their hori- zontal proboscis, slender but swollen at the base, and by their habit of resting with the wings crossed like the blades of a closed pair of scissors. z The greater number of the flies occupy sections of country, spoken of as fly belts” or “fly districts,” some of which are permanently infected, others temporarily infected. Such “belts” are usually deep forests along the banks of Streams or on theshores of lakes. The adult flies seem to love the shade, though they fly from it into the hot sun to seek their prey. The large game animals seem to be the natural prey of the flies, though a number of them bite human beings, and one, Glossina palpalis, seems to prefer human blood to all others. The flies seem to attack moving animals by preference. So long as the creature Moves they pursue. When it stands, many of them fly away to the shade again. Both males and females bite. The latter distend themselves with blood until 518 Sleeping Sickness they are so heavy that they can scarcely fly and drop off to the ground. Biting is almost entirely confined to bright sunny weather. On dull or cloudy days the flies remain in the brush. Exceptions are found among the few species that live in arid sections. Such may bite at night. Few of the flies fly far from their native haunts where they seem to prefer to await the coming of their prey, rather than to make excursions after it. Clouds of the flies often arise at the same time and attack the animals in swarms. The flies are larviparous and do not lay eggs. Copulation of the sexes takes place but once, the sperm being retained in a spermatotheca. The eggs are fertilized as they descend from the oviduct to the uterus where they hatchintoalarvaon the fifth day. Thelarva grows rapidly, molts three times and attains its full size by the tenth day, when it is born. The larva at the time of birth is cylindricalin shape, consists of thirteen segments and measures 6-7 mm. in length. It is nearly white but has a black head which is small and incon- spicuous. The larve are usually deposited on the sand of the banks of streams or lakes, and at once burrow into the ground to a depth of an inch or so. In a half hour or an hour the larva changes to a pupa in which state it continues for about a month. The imago or fly then emerges. The average duration of life of theimago fly is about three months, during which time each female bears an average of ten new larve. ’ Glossina palpalis is commonly infested by a flagellate called Crithidia grayi, that seems in some way to pass from fly to fly, and to have nothing to do with the bloods upon which it feeds. It is to be regarded as a parasite of the fly, and should be known lest it be confused with the Trypanosoma of which the fly is the vector. TABLE FOR THE IDENTIFICATION OF THE COMMON TSETSE FLIES Large Species; body measuring more than 12.mm. in length. Pattern on thorax faint; four very distinct black spots... G. longipennis, Pattern on thorax sharp and distinct, no black spots...... G. fusca. Small species; body in general measuring less than 12 mm. in length. All five tarsal joints of the third pair of legs black. Colors dark; antennz black; last two tarsal joints of the first pair of legs black.......-.. 00.00.0000 cece eee G. palpalis. All of the tarsal joints of the first pair of legs yellow... G. bocagei. Very small species; markings like those of G. morsitans on abdomen 3 s4s.geisis 346 soca Fae BEG as oe w Masel rere G. tachinoides. Colors dark; antenne yellow.......... Ee AA Rds M4 Re G. pallicera. Only the last two tarsal joints of the third pair of legs black; all the others yellow. The fifth tarsal joint of the first and second pairs of legs is VEO Wire qeits Yn seroma aman ele dl anid Ng Wy ae kad fgets aan a G. pallidipes. The last two joints of the tarsi of the first and second pairs of legs are black. The yellow band on the abdominal segments takes up one-third of the segment...................000005 G. morsitans. The yellow band on the abdominal segments, takes up . one-sixth of the segment.............0. 00 v eee G. longipalpis AMERICAN TRYPANOSOMIASIS SCHIZOTRYPANUM CrRuzI (CHAGAS) No sleeping sickness has thus far been found to occur upon either of the American continents, though human trypanosomiasis in another form has been observed in Brazil where it has been studied by Chagas.* * “ Archives fiir schifis u. tropen Hygiene,” 1909, Heft 4; abstract ‘“Centralbl. f. Bacteriologie etc. Ref.,” 1909, xLIV, 639; “ Bull. del’Inst. Pasteur,” 1910, VIU, 373. American Trypanosomiasis 519 The disease, which in Minas Gaeras often attacks the entire popu- lation, chiefly affects the children and goes by the local name of TIES ' \ ! { a 2 WP is nce watbaae st Fig. 213.—r1. Glossina papalis 7? X 6. 2. Glossina morsitans, 29 X 6. (Patton and Cragg). Pa AEL SS Abo. Opilagao. In childhood it usually assumes the form of an acute malady characterized by an incubation period of ten days, and by high continued fever, puffiness of the face, enlargement of the 520 Sleeping Sickness thyroid gland, of the lymph nodes and spleen. In some cases meningitis occurs. It is extremely fatal. In adults it is apt to take a more chronic course in which the chief symptoms are enlargement of the thyroid gland, and a myx- edematous condition of the skin. The lymph nodes usually en- large. If the adrenal glands become affected, symptoms resembling Addison’s disease make their appearance. If the heart muscle be invaded by the parasites, its power is diminished and the pulse becomes feeble and irregular. If the nerve-cells or neuroglia cells of the central nervous system be affected through parasitic inva- sion, symptoms occur according to the extent and localization of the disturbance. There is always irregular fever and marked anemia. Chagas found a trypanosome in the peripheral blood of patients suffering from Opilacao, and gave it the name Trypanosoma cruzi. Later studies of the micro-parasite have, however, shown that its method of reproduction differs so strikingly from that of the trypano- somes, that it was necessary to make a generic distinction between the two, and it is now called Schizotrypanum cruzi. Morphology.—The Schizotrypanum is present in the peripheral circulation only during the febrile stages of the disease, when it may be found by the usual methods of staining for trypanosomes. ‘ It is a long slender trypanosome-like organism, with the char- acteristic fusiform shape, with a nucleus, a large blepharoplast, a flagellum and an undulating membrane. No measurements are given, but the parasite is rather small. No dividing forms are observed in the circulating blood. The trypanosomes may be free, may be attached to the erythrocytes or may be partly or entirely in the red corpuscles. They show sexual dimorphism, the males being long and slender, the females shorter and stouter. Reproduction.—Gametogony takes place in the lungs. Such of the trypanosome forms as are caught and retained there, lose the undulating membranes, the two ends curve toward one another forming first a crescent, them unite and form a ring. The female parasites shed the blepharoplasts, and in both male and female parasites the nucleus breaks up into eight secondary nuclei, giving rise to eight merozoits. The merozoits derived from the female parasites have a single nucleus, those derived from the male para- sites, a nucleus and a blepharoplast connected by a fine thread of chromatin. The merozoits thus formed enter into erythrocytes where they eventually develop into the trypanosome forms. Hence is explained the peculiar relation of the trypanosomes to the eryth- rocytes mentioned above. The chief multiplication of the parasites, however, takes place in the cells of the voluntary muscles, the heart muscle, the central nerv- ous system, the thyroid, the adrenal glands and the bone marrow. In these situations, according to Chagas, the parasites take on a American Trypanosomiasis 521 rounded form, and by schizogony give rise to a great number of daughter parasites, each having a nucleus and a blepharoplast. For a time the schizonts are quiescent, then develop flagella and undulating membranes. ‘The infected cells are destroyed. Chagas thinks that gametes are formed only in the lungs. In the definitive host, the Lamus (or Conorhinus) megistis, the sexual conjugation occurs in the mid-gut. The blepharoplast approaches and seems to blend with the nucleus, the undulating membrane disappears and the parasites assume a spherical form. Actual conjugation does not seem to have been observed. Multi- plication takes place by division of these rounded organisms, the daughter parasites becoming flagellated, the flagellum originating from the blepharoplast. Numerous flagellated trypanosome and crithidia forms of the parasite are observed in the hind-gut of the insect. Chagas observed trypanosome forms in the body cavity and in the salivary glands by the insect, and it is probable that it is through these that the infection is transmitted when the insect bites a susceptible animal, though Brumpt thinks the infection may take place through the feces of the bug, especially when these are in some way brought to the conjunctiva. Transmission.—Chagas was able to show that a large bug, Lamus (Conorhinus) megistus, common in the neighborhood in which Opliacao occurs, is the principal definitive host of the parasite. Both males and females of this flying bug are vicious biters and both live upon human blood as well as upon the bloods of other warm- blooded vertebrates. The bugs are common in the thatch and in the cracks between the timbers of the native houses. Whether other species of Lamus may also harbor the parasites is not known. Brumpt* found that Cimex lectularius, Cimex boneti and Ornitho- dorus moubata could also act as definitive hosts. A study of Cimex lectularius, the common bed-bug, as a definitive host of the parasite, was made by Blacklockt who found that only a very occasional bug becomes so infected as to be able to eeeer the transmission. Cultivation.—The parasites are ate cultivated in viiroin the medium recommended for trypanosomes by Novy and McNeal. In culture the organisms resemble those found in the bugs, i.e., round and crithidial forms, or pear-shaped rapidly dividing forms. More than two subcultures can rarely be made before the organisms die out. Pathogenesis.—The Schizotrypanum is pathogenic for certain monkeys (Callithrix), dogs, rabbits and guinea-pigs. Guinea-pigs usually die in five to ten days, though the trypanosome forms are not usually found in the peripheral blood. They are, however, present in larger numbers in the lungs. Monkeys live longer. Trypano- *“Centralbl. f. Bakt. etc. Ref.,” tv, No. 3, p. 75. ft “British Medical Journal,” 1914, 1, 912. 522 Sleeping Sickness some forms of the parasite appear in the blood in about a week, then may disappear. The animals live a month or two. Diagnosis.—As the trypanosomes are present in the circulating Fig. 214.—Schizotrypanum cruzi developing in the tissues of the guinea-pig. 1. Cross-section of a striated muscle fiber containing Schizotrypanum cruzi: Note ividi > —2>-Section~of brain showing -a-Schizotrypanum cyst within a neuroglia cell, containing chiefly flagellated forms. 3. Section through the supra- renal capsule, fascicular zone. 4. Section of brain showing a neuroglia cell filled with round forms of Schizotrypanum. (From Low, in Sleeping Sickness Bulletin, after Vianna.) blood of human beings in somewhat small numbers, and only at certain times, it is unwise to rely upon them as a means of making American Trypanosomiasis 523 the diagnosis, though if they be found the diagnosis is certain. It is usually much better to inoculate 1 or 2 cc. of the blood of the suspected case into a guinea-pig and then make frequent examina- tions of its blood. Here, again, the common absence of trypanosome forms from the blood complicates matters. If none can at any time be found, the muscles of the guinea-pig must be examined for the dividing forms of the parasites, which are usually quite numerous. Prophylaxis.—As the bugs fly it is somewhat difficult to defend the sleeping patient against them, so long as he lives in a carelessly built and thatched country house. Sulphur fumigation and white- washing may help. Well-built habitations with screened windows and the use of mosquito bars should constitute the best defense. Lamus (Conoruinus) Mecistis (BuRN) Patton and Cragg* describe this bug as follows: “Dark brown to black. Pro- notum broadly expanded, with two broad raised red lines extending from the Fig. 215.—Lamus (Conorhinus) megistus (female), the insect host and distributing agent of Schizotrypanum cruzi (Chagas). X 2. middle of the posterior border, and a red spot on the postero-lateral angles of pro- notum, At the anterior border of the prenotum there are six short spines, three on each side; the most anterior are the longest and project on each side of the eyes; two are situated further back, one on each side of the middle line at the origin of the two admedial ridges; the third spine is situated on a ridge at the junction of the middle and anterior third of the pronotum just above the first pair of legs. Scutellum dark brown with two short red lines converging toward the apex, where they meet; apex red, turning upward and bluntly rounded off. Corium and membrane fuscous, the former with one or more red streaks. Connexivum with six well-marked bright red lines, broader in the male; in both sexes the lines ex- tend round to the ventral border. In the male the last segment, except for a central black mark, is entirely red. Length 30 to 32 mm.’ The.L. megistus ‘is almost entirely a domestic insect.” ‘‘The adults enter *“A Text-book of Medical Entomology,” 1913, Pp- 492- 524 Sleeping Sickness inhabited houses but never those that have been abandoned. In houses which are old or badly kept they are to be found in cracks and holes in the walls, where they lay their eggs; the early stages, which are wingless, crawl out of their resting places in the walls so soon as the lights are put out and make their way to the beds of the occupants of the house. The adults behave in the same manner, but as they are powerful fliers, they can reach the people who sleep in hammocks. The bite is said to be painless and to leave no mark.” “ The eggs of L. megistus are of a creamy white color and are laid in batches of from eight to twelve, and as many as forty-five such batches may be laid. Ac- cording to Neiva they hatch in twenty-five to forty days. The larva is of a uniform light color when it emerges, becoming darker later; it takes its first feed from five to eight days after emerging from the egg, and the second from the fifteenth to the twentieth day; it changes its skin (first nymphal stage) after about forty-five days. The second molt takes place during the second or third month, and the third during the fourth or sixth month. Thefourth molt occurs about the rgoth day after the larva has hatched out from the egg; this stage lasts at least forty-two days. Neiva states that this time is the most critical period in its life, and that large numbers of them die. After the next molt the adult stage is reached, and eight days later they are ready to suck blood; egg-laying commences about the fifty-fifth day after the first feed. One female kept under observation by Neiva for about three and a half months laid 218 eggs in thirty-eight batches. Under favorable conditions of food supply the cycle from egg to egg is completed in about 324 days.” This bug, when experimentally infected with Schizotrypanum cruzi, transmitted the infection to monkeys, guinea-pigs, rabbits and dogs. Both males and females bite and may transmit the parasites. CHAPTER XXII KALA-AZAR (BLACK SICKNESS) LEISHMANIA DONOVANI (LAVERAN AND MESNIL) “Kata-Azar,” ‘“Dumdum fever,’ “Febrile tropical spleno- megaly,” ‘‘Non-malarial remittent fever,’ is a peculiar, fatal, infectious disease of India, Assam, certain parts of China, the Malay Archipelago, North Africa, the Soudan and Arabia, caused by a protozoan micro-organism known as Leishmania donovani, and characterized by irregular fever, great enlargement of the spleen, anemia, emaciation, prostration, not infrequent dysentery, occa- sional ulcerations of the skin and mucous membranes, and sometimes cancrum oris. Because of its protean manifestations the disease has been given many names, and has been confused with the various diseases which its symptoms may resemble. It was not until 1900 that it was finally differentiated from malarial fever and came to be regarded as a distinct entity. In 1900 Leishman* noticed in the spleen of a soldier returned from India and suffering from ‘dumdum fever’’—a fever acquired at Dumdum, an unhealthy military cantonment not far from Cal- cutta—certain peculiar bodies. He reserved publishing the observa- tion until 1903, so that it appeared almost simultaneously with a paper upon the same subject by Donovan.t As the publications came from men in different parts of the world, appeared so nearly at the same time, and showed that they had independently arrived at the same discovery, the parasite they described became known as the Leishman-Donovan body. For a long time its nature was not known and its proper classification impossible, but after it had been carefully studied by Rogers,t Ross,§ and others, and its de- velopmental forms observed, it was agreed that it belonged in a new genus of micro-organisms, not far removed from the trypanosomes, and eventually Ross, and then Laveran and Mesnil, honored both of its discoverers by calling it Leishmania donovani, which name has been generally accepted. Morphology.—As seen in a drop of splenic pulp the organism is a minute round or oval intracellular body measuring 2.5 by 3.5 u- When properly stained with polychrome methylene blue (Wright’s, * «Brit. Med. Jour.,” 1903, I, 1252. } Ibid., 1903, 11, 79. } “Quarterly Jour. Microscopical Society,” xtvu, 367; “Brit. Med. Jour.,” 1904, 1, 1249; IL, 645; “Proceedings of the Royal Society,” Lxxvu, 284. § “Brit. Med. Jour.,” 1903, 1, 1401. 525 526 Kala-Azar Leishman’s, or Jenner’s stains) and examined under a high magnifi- cation, it is found that the protoplasm takes a pinkish color and contains two well-defined bright red bodies. The larger of these is ovoid and lies excentrically, its long diameter corresponding to Fig. 216.—Evolution of the parasite of kala-azar: 1 to 5. Parasites of kala- azar. 1 Isolated parasites of different forms in the spleen and liver; 2, division forms from liver and bone-marrow; 3, mononuclear spleen cells containing the parasites; 4, group of parasites; 5, phagocytosis of a parasite by a polynuclear leukocyte. 6 to 15. Parasites from cultures. 6, First changes in the parasites. The protoplasm has increased in bulk and the nucleus has become larger; 7, further increase in size; vacuolization of the protoplasm; 8, division of the en- larged parasite; 9, evolution of the flagella; 10, small pyriform parasite showing flagellum; 11, further development and division of the parasite; 12, flagellated trypanosoma-like form; 13, 14, flagellated forms dividing by a splitting off of a portion of the protoplasm; 15, narrow flagellated parasites which have arisen by the type of division shown in 13 and 14. (From Mense’s ‘Handbuch,’ after Leishman.) the long diameter of the organism. This is regarded as the nucleus. The second body is smaller and of bacillary shape, and usually lies with its: long diameter transverse to the nucleus. This is looked upon as a blephagopliist:. It stains more intensely than the nucleus. Cultivation 527 ‘In addition to these bodies the protoplasm may contain one or two vacuoles. All of the bodies are intracellular, as can easily be determined by examining sections of tissue, but in smears of splenic pulp the cells are broken and many free bodies may appear. The cells in which they occur are lymphocytes, endothelial cells, and peculiar large cells whose histogenesis is obscure. They are rarely to be found in polymorphonuclear leukocytes, and though there has been much discussion upon this point, probably never appear in the red blood-corpuscles. The bodies divide by binary and multiple fission, without r rec- ognizable mitotic changes. When multiple fission occurs, the nucleus divides several times before the protoplasm breaks up. The organism is not motile and at this a has no ee, Fig. 217.—Leishman-Donovan bodies from the spleen of a case of kala-azar. X about 1000. (From Beattie and Dickson’s ‘‘A Text-book of General Path- dlogy,” by kind permission of Rebman, Limited, publishers.) Cultivation.—The organism was first cultivated artificially by Rogers in citrated splenic juice at 17° to 24° C. It can also be cultivated in the blood-serum agar medium used by Novy, McNeal, and Hall for trypanosomes, and in the N. N. N. medium of Nicolle, which has the following composition: Waters cise. dan toasts warden ox deans Aes aiden agg Ge x goo c.c. Salt (N@CI) 35, 5.5 apse cn east veddtacn acta ateers lea Mande i oo 6 gm. Ap ara aries syns ocen ey specs boo EE Ree ba oe _ 16 gm. Dissolve, distribute in tubes, sterilize, and add to the medium in each tube after liquefying and cooling to 40°-so0° C., one-third of its volume of rabbit’s blood obtained by cardiac puncture. Slope the tubes for twelve hours, incubate at 37° C. for five days to test the sterility of the medium, then keep at the se acatree temperature of the laboratory, sealed to prevent evaporation. It is imperative that the material planted be sterile so far.as bacteria 528 Kala-Azar are concerned. Any associated growing bacteria quickly destroy Leishmania donovani. Under conditions of cultivation the appearance of the organism undergoes a complete change. It enlarges, the nucleus increases greatly in size, and a pink vacuole appears near the blepharoplast. In. the course of twenty-four to forty-eight hours the organism elongates, the blepharoplast moves to one end, and from the vacuole ' near it a flagellum is developed, and the organism becomes in about ninety-six hours a flagellate protozoan resembling herpetomonas. It now measures about 20 yp in length and 3 to 4 uw in breadth, its whip or flagellum measuring about 3 u additional. It is also motile, and, like the trypanosomes, swims with the flagellum anteriorly. There i is no undulating membrane. This may be regarded as the perfect or adult form of the organ- ism. It multiplies by a peculiar mode of division first observed by Fig. 218.—Leishmania donovani. Flagellated forms obtained in pure cultures (Leishman). Leishman. Chromatin granules, a larger and a smaller, appear in the protoplasm in pairs, after which, through unequal longitudinal cleavage, long, slender, almost hair-like individuals, containing one of the pairs of chromatin granules, are separated. These were serpentine at first, but later, as they grew larger, a flagellum was thrust out at one end. Distribution.—The Leishman-Donovan body is widely distrib- uted throughout the body of the patients suffering from kala-azar. It occurs in great numbers in the cells of the spleen, of the liver, of the bone-marrow, and in the ulcerations of the mucous membranes and skin. In the peripheral blood they are few and only in the leuko- cytes. They are always intracellular, or when in the circulating blood may be found in indefinite albuminous masses, probably de- stroyed cells. The number in a cell varies up to several hundred, such great aggregations only being found in the peculiar large cells of the spleen. Lesions.—The splenomegaly is the most striking lesion.. The change by which the enlargement is effected is not specific. The Transmission 529 organ is not essentially changed histologically, but seems to be merely hyperplastic. The liver is enlarged, but here, again, specific changes may be absent. In some cases a pallor of the centers of the lobules may depend upon numbers ‘of parasite-containing cells, partly degenerated. The yellow bone-marrow becomes absorbed and red tissue takes its place, as in most profound anemias. Transmission.—Rogers’ observation, that the round bodies grew into flagellate bodies at temperatures much below that of the human body, led Manson to conjecture that the extrahuman phase of the life of the organism took place at similar low temperatures in the soil or in water. Patton* found that a number of cases sometimes occurred in the same house, while neighboring houses were free, and thought this suggested that a domestic insect might be the distribut- ing host. Later, Patton} reported a very thorough study of insects in relation to kala-azar, in which after a long series of experimental investigation, he came to the conclusion that the Indian bed-bug, Cimex rotundatus, is the specific invertebrate host of Indian kala- azar. It seems that in order that the parasites shall mature in the bed-bug, and undergo those changes that shall result in the insect’s infectivity, the bug must receive one full meal of the infected blood. If a second meal is taken, the digestive condition in the bug’s alimen- tary canal is changed, and instead of continuing to develop, the parasites die out. When the conditions are all favorable, Patton found that the flagellates continued to multiply actively from the fifth to the eighth day. By the twelfth day practically all had reached the postflagellate stage and were only found in the stomach of the bed-bug. These results convince Patton that Cimex rotund- atus is the definitive host, but the proof is lacking. No animal is known to be sufficiently susceptible to Leishmania donovani, to acquire anything resembling Kala-azar, therefore there is none that the bug can successfully infect. Human experiment with so fatal a disease being out of the question, the case rests at this point. Rowt has, however, shown that when a monkey, Macacus sinicus, is inoculated cutaneously or subcutaneously with a three- weeks-old culture of Leishmania donovani, a cutaneous or sub- cutaneous lesion may result. This may facilitate future studies with biting insects. It may be, however, that Patton and others are wrongin thinking that the flagellate stage at which the parasites arrive in the bed-bug is the infective stage, and have, therefore, gone astray. Bayon§ points out that Leishmania infantum is infective for dogs and monkeys in the rounded or oval stages, not in the elongate or cultural stages, and that the same may be true of Leishmania dono- * “Scientific Memoirs of the Government in India,” 1907, No. 27. } “Brit. Med. Jour.,” 1912 I, rr94. “Brit. Med. Jour.,” 1912, 11, 1196. § “Brit. Med, Jour.,” 1912, 0, 1197. 34 530 Kala-Azar vani. The fleas, which are the vectors of infantile kala-azar among dogs, show only the rounded and oval forms of the parasites, never the flagellated forms. Quite recently Patton and Donovan have been successful in infect- ing puppies with Leishmania donovani, though the mature dogs seem never to beinfected, the examination of 2000 street dogs in Madras and other cities failing to reveal any of the parasites in either the liver or spleen. Patton inoculated a white rat with 3 cc. of an emul- sion of human spleen containing the oval forms of Leishmania dono- vani from a case of Indian kala-azar, and fifteen days later found the spleen several times the normal size and containing large numbers of the parasites. Diagnosis.—The anemia of kala-azar is usually not profound. The erythrocytes number about 3,000,000 in ordinary cases and the hemoglobin is correspondingly diminished. As in malaria, there is leukopenia, but it is usually more severe, the white corpuscles some- times being as few as 600 to 650 per cubic millimeter of blood. The enlargement of the spleen and liver suggest malaria. The only certain way to make a diagnosis, except in those rare cases where one has the good fortune to find occasional parasites in the leukocytes of the circulating blood, is by hepatic or splenic puncture. A large hypodermic needle should be used, and it should be carefully sterilized. It should by preference be thrust into the liver and a drop of fluid secured for examination. If nothing be found it may later be necessary to puncture the spleen, though it is dangerous because of the probability of subsequent hemorrhage. If decided upon as a justifiable method of examination, the needle is thrust into the spleen, and a bit of splenic pulp secured by firmly withdrawing the piston of the attached syringe. Before making such a puncture, leukemia should be excluded, lest hemorrhage occur. Treatment.—No treatment thus far tried has proved successful. The disease is usually fatal, and in certain parts of India whole towns have been depopulated by it and the fear of it. INFANTILE KALA-AZAR LEISHMANIA INFANTUM (NICOLLE) Pianese* found infantile kala-azar in Italy, and in the children suffering from it he was able to find the Leishmania infantum. Nicolle,t while in Tunis, observed a form of kala-azar that was peculiar to childhood and most frequent in babies of about two years of age. Mesnil has identified the affection with a disease known as “ponos” in Greece. In the spleens of such patients * “Gaz. Intern. di Medicin,” 1905, vim, 8. f “Ann. de l’Inst. Pasteur,” 1909, XXIII, 361, 441. Tropical Ulcer 531 Nicolle found an organism that was not distinguishable either by microscopic examination or by cultivation from Leishmania dono- ‘yani, but, finding that it was infectious for dogs, he came to the con- clusion that it was a separate species, and called it Leishmania infantum. He also found that the dogs in Tunis frequently suf- fered from spontaneous infection from this parasite, and it is possible that it is from the dogs that the children become infected. Further experiments with this parasite by Nicolle and Comte have shown that in the form in which it occurs in the human spleen it is capable of infecting monkeys, and Novy has succeeded in cultivating the organism and infecting dogs with artificial cul- tures containing its flagellate forms. It is now thought by many that infantile kala-azar and Indian kala-azar are identical diseases, caused by identical parasites. In considering the probable source of the disease Stitt* says: “It has been suggested that the Mediterranean basin may have been the original focus of visceral kala-azar and that it spread thence to India by way of Greece and the Russian Caucasus, cases having been re- ported from districts which would join the two foci. Just as chil- dren bear the brunt of malaria in old malarial districts and adults suffer in places in which the disease has been more recently im- ported, so by analogy we may consider the disease as of more recent introduction in India . . . . In the Mediterranean basin there is a natural canine Leishmaniasis and some think the human form may be contracted from the dog through the medium of the flea.” TROPICAL ULCER LEISHMANIA FURUNCULOSA (FIRTH) In India, northern Africa, southern Russia, parts of China, the West Indies, South America, and, indeed, most tropical countries, a peculiar intractable chronic ulceration is occasionally observed, and is variously known as Tropical ulcer, Oriental sore, Biscra boil, Biscra button, Aleppo boil, Delhi boil, Bagdad boil, Jericho boil, and Buton d’Orient. It has long been known as a specific ulcerat- ing granuloma. The lesions, which begin as red spots, develop into papules which become covered with a scaly crust which separates, leaving an ulcer upon which a new crust develops. The lesion spreads and is much larger when the crust again separates. A purulent discharge is given off in moderate quantities and the ulcer becomes deep and perpendicularly excavated. It lasts for months—sometimes a year or more—and gradually cicatrizes, forming a contracting scar that is quite disfiguring when upon the face. The lesions may be single, though they are commonly mul- *Diagnosis and Treatment of Tropical Diseases, 1914, Pp. 75. 532 Kala-Azar Fig. 220.—Helcosoma tropicum, from a case of tropical ulcer (‘‘ Delhi sore”) smear preparation from the lesion stained with Wright’s Romanowsky blood- staining fluid. The ring-like bodies, with white central portions and containing a larger and a smaller dark mass, are the micro-organisms. The dark masses in the bodies are stained a lilac color, while the peripheral portions of the bodies, in typical instances, are stained a pale robin’s egg blue. The very dark masses are nuclei of cells of the lesion. X 1500 approx. (Wright),. (From photograph by Mr. L. S. Brown.) Tropical Ulcer 533 tiple, as many as twenty sometimes occurring simultaneously. It is thought that recovery is followed by immunity. Organism.—In 1885 Cunningham* described a protozoan organ- ism found in the tropical ulcer, the observation being confirmed by Firth,t who called the bodies Sporozoa furunculosa. Later, J. H. Wright} studied a case of tropical ulcer and found bodies pre- cisely like the Leishmania donovani. He gave it the name Hel- cosoma tropicum. The great similarity to the other organisms has led more recent writers to identify it with Leishmania, but as it induces a local and not a general infection like kala-azar, it is now known as Leishmania furunculosa. Cultivation——The organism has been cultivated by Nicolle and Fig. 221.—Oriental sore (Wellcome Research Laboratory). Manceaux§ upon the same media and in the same manner as Leishmania donovani and Leishmania infantum with which these _ investigators believe it to be identical. Cultivation was also success- fully achieved by Row. Pathogenesis.—The virus is pathogenic for man, monkeys such as Macacus simius, M. cynomolgus, M. rhesus and M. inuus, and for dogs. The same effects are produced whether fresh virus from a human ulcer, or from an artificial culture be employed. In dogs the inoculations produce only nodular formations; in monkeys, nodules like those in human beings that go on to ulceration. Intra- peritoneal inoculations usually fail. The most successful inocula- * “Scientific Memoirs by Medical Officers of the Army in India,” 1884, 1. } “British Med. Journal,” Jan. 10, 1891, p. 60. i “Jour. of Med. Research,” 1904, X, 472. § “Ann. de l'Inst. Pasteur,” 1910, XxIV, 683. 534 Kala-Azar tions are made beneath the skin in the neighborhood of the nose. One successful infection with the parasite usually confers immunity; unsuccessful intraperitoneal introduction of large quantities of culture produce no immunity. Transmission.—The disease can be transmitted by inoculation from human being to human being. The usual mode of transmission is not known, but as the lesions usually occur where the body surface is uncovered, it may be that flies or other insects act as vectors of the parasites. Preventive Inoculation.—Jackson* is authority for the statement that “the Jews of Bagdad recognized that tropical ulcer is in- oculable and autoprotective years ago, and practised vaccination of their children upon some portion of the body covered by cloth- ing, in order that their faces and other exposed parts of the body be not disfigured by the ulcers and the resultant scars.” Nicollet sought to vaccinate according to modern methods with killed and living cultures of the organism, and was successful when he first used killed culture, then after a year a live culture, and then three months Jater another live culture. Treatment.—Row{ has endeavored to cure already existing lesions by vaccination, and has met with what seems to be encour- aging success. Cultures of the organism were permitted to grow for seven days, then sterilized with glycerin. Patients can bear 0.25 cc. at a dose, there is little febrile reaction, and the lesions proceed to heal nicely. HISTOPLASMOSIS HisTopLasMA CAPSULATUM (DARLING) In 1906 Darling,§ working at the Isthmus of Panama, observed certain cases presenting pyrexia, anemia, leukopenia, splenomegaly, and emaciation, and bearing a close resemblance to kala-azar. The disease was quite chronic, and it terminated fatally. When ex- amined at autopsy, these cases showed necrosis with cirrhosis of the liver, splenomegaly, pseudo-granulomata of the lungs, small and large intestines, ulceration of the intestines, and necrosis of the lymph nodes draining the injected viscera. The lesions seemed to depend upon the invasion of the endothelial cells of the smaller lymph- and blood-vessels by enormous numbers of a small en- capsulated micro-organism. The organism is small, round or ova] in shape, and measures 1 to4 min diameter. It possesses a polymorphous, chromatin nucleus, basophilic cytoplasm, and achromatic spaces all enclosed within an achromatic refractile capsule. * «Tropical Medicine,” Phila., P. Blakiston’s Son & Co., 1907, p. 478. t‘‘Annales de l’Inst. Pasteur,” Tunis, 1908. t“British Medical Journal,” 1912, 1,540. § “Jour. Amer. Med. Assoc.,” 1906, XLVI, 1283; ‘“‘Archiv of Int. Med.,”’ 1908, mm, 107; ‘Jour. Exp. Med.,”’ 1909, XI, 515. Histoplasmosis 535 The micro-organism differs from the Leishman-Donovan body of kala-azar in the form and arrangement of its chromatin nucleus and in not possessing a chromatin rod. The distribution of the parasite in the body is accomplished by the invasion of the con- tiguous endothelial cells of the smaller blood- and lymph-vessels and capillaries, and by the infection of distant regions by the dis- lodgment of infected endothelial cells and their transportation EO ; Fig. 222,—Histoplasma capsulatum. Mononuclear cells from the lung con- taining many parasites (Darling). (Samuel T. Darling in “Journal of Experi- mental Medicine.”’) thither by the blood- and lymph-stream. Thus the skin, intestinal, and pulmonary nodules may be due to secondary distribution of the parasite. The micro-organism apparently lives for a con- siderable period of time in the tissues, because in the older areas of necrosis there are myriads of parasites all staining well. The mode of infection and portal of entry are unknown. The parasite has neither been cultivated nor transmitted by inoculation. Believing it to be a new parasite, Darling has suggested that it be called Histoplasma capsulatum. CHAPTER XXIII YELLOW FEVER Tue bacteriology of yellow fever has been studied by Domingos Freire,* Carmona y Valle, Sternberg,{ Havelburg,§ and Sanarelli,|| but all of their work has been shown to be incorrect by the interest- ing researches and very conclusive results of Finlay,** Carter,tf Reed, Carroll, Lazear, and Agramonte,{f{ and Reed and Carroll, §§ which have proved the mosquito to be the definitive host of an in- visible micro-organism. Reed, Carroll, Lazear, and Agramonte, |||| constituting a Board of Medical Officers ‘‘for the purpose of pursuing scientific investiga- tions with reference to the acute infectious diseases prevalent on the island of Cuba,” began their work in 1900, at Havana, by a careful investigation of the relationship of Bacillus icteroides to yellow fever. By a most careful technic they withdrew and examined the blood from the veins of the elbow of 18 cases of yellow fever, mak- ing 48 separate examinations on different days of the disease, and preparing 115 bouillon cultures and 18 agar plates, every examina- tion being negative so far as Bacillus icteroides was concerned. They were entirely unable to confirm the findings of Wasdin and Geddings,*** that Bacillus icteroides was present in blood obtained from the ear in 13 out of 14 cases, and concluded that both Sanarelli, and Wasdin and Geddings were mistaken in their deductions. In lieu of the remarkably interesting discoveries of Ronald Ross concerning the relation of the mosquito to malarial infection, the commissioners, remembering the theory of Finlay,{{{ who in 1881 *“Moctrine microbienne de la fievre jaune et ses inoculation preventives,” Rio Janeiro, 1885. tT “Legons sur ]’étiologie et la prophylaxie de la fievre jaune,”’ Mexico, 1885. t “Report on the Etiology and Prevention of Yellow Fever,’”’ Washington, 1891; “Report on the Prevention of Yellow Fever by Inoculation,” Washington, ee Ann. de l’Inst. Pasteur,” 1897. Pe ae Med. Jour.,” July 3, 1897; “Ann. de l’Inst. Pasteur,’”’ June, Sept., and ** “ Amer. Jour. Med. Sci.,” 1891, vol. cir, p. 264; “Ann. de la Real Academia,” 1881, vol. Xvi, pp. 147-169; “Jour. Amer. Med. .Assoc.,” vol. xxxvutr, April 19, 1902, p. 993. Tt “New Orleans Med. Jour.,”” May, 1800. tt “Phila. Med. Jour.,” Oct. 27, 1900; “Public Health,” vol. xxv1, 1900, p. 23. i “Public Health,” 1901, vol. xxvI, p. 113. ||| “Phila. Med. Jour.,” Oct. 27, 1900. *** “Report of the Commission of Medical Officers Detailed by the Authority of the President to Investigate the Cause of Yellow Fever,” Washington, D. C., 1899. Tit “Annales de la Real Academia,” 1881, vol. xVvIII, pp. 147-169. 536 Mosquitoes and Yellow Fever 537 published an experimental research showing that mosquitoes spread the infection of yellow fever, and the interesting and valuable ob- servations of Carter* upon the interval between infecting and secondary cases of yellow fever, turned their attention to the mos- quito. Securing mosquitoes from Finlay and continuing the work Fig. 223.—Stegomyia fasciata (Stegomyia calopus): a, female; 6, male (after Carroll). where he had left it, they found that when mosquitoes (Stegomyia fasciata seu calopus) were permitted to bite patients suffering from yellow fever, after an interval of about twelve days they became able to impart yellow fever through their bites. This infectious char- acter, having once developed, seemed to remain throughout the * “New Orleans Med. Jour.,” May, 1900. 538 Yellow Fever subsequent life of the insect. So far as it was possible to deter- mine, only one species of mosquito, Stegomyia calopus, served as a host for the parasite whose cycles of development in the mosquito and in man must explain the symptomatology of yellow fever. In order to establish these observations, experimental inocula- tions were made upon human beings in sufficient number to prove their accuracy. Unfortunately, Dr. Lazear lost his life from an attack of yellow fever. Reed, Carroll, and Agramonte* came to the following conclusions: 1. The mosquito C. fasciatus [Stegomyia calopus] serves as the intermediate host of the yellow fever parasite. 2. Yellow fever is transmitted to the non-immune individual by means of the bite of the mosquito that has previously fed on the blood of those sick with the disease. ‘ 3. An interval of about twelve days or more after contamination appears to be necessary before the mosquito is capable of conveying the infection. 4. The bite of the mosquito at an earlier period after contamination does not appear to confer any immunity against a subsequent attack. 5. Yellow fever can be experimentally produced by the subcutaneous injection - of blood taken from the general circulation during the first and second days of the disease. 6. An attack of yellow fever produced by the bite of a mosquito confers im- munity against the subsequent injection of the blood of an individual suffering from the non-experimental form of the disease. ; 7. The period of incubation in 13 cases of experimental yellow fever has varied from forty-one hours to five days and seventeen hours. 8. Yellow fever is not conveyed by fomites, and hence disinfection of articles of clothing, bedding, or merchandise, supposedly contaminated by contact with those sick with the disease, is unnecessary. g. A house may be said to be infected with yellow fever only when there are present within its walls contaminated mosquitoes capable of conveying the para- site of this disease. to. The spread of yellow fever can be most effectually controlled by measures directed to the destruction of mosquitoes and the protection of the sick against the bites of these insects. 11. While the mode of propagation of yellow fever has now been definitely determined, the specific cause of the disease remains to be discovered. The probability that Bacillus icteroides is the specific cause and is transmitted by the mosquito is so slight that it need scarcely be considered. All analogy points to the organism being an animal parasite similar to that of malarial fever. With this positive information before us, the prophylaxis of yellow fever and the prevention of epidemics of the disease where sporadic cases occur becomes very simple and may be expressed in the following rules: 1. Whenever yellow fever is likely to occur, the breeding places of mosquitoes should be destroyed by drainage. Cisterns and other necessary collections of standing water should be covered or secured. 2. Houses should have the windows and doors screened and the inhabitants should use bed nets. 3. So soon as a case of fever appears it should be removed in a mosquito-proof ambulance to a mosquito-proof apartment in a well-screened hospital ward and kept there until convalescent. * Pan-American Medical Congress, Havana, Cuba, Feb. 4-7, 1901; Sanitary Department, Cuba, series 3, 1902. Prophylaxis 539 4. The premises where such a case has occurred should be fumigated by burn- ing pyrethrum powder (1 pound per 1000 cubic feet) to stun the mosquitoes, which fall to the floor and must afterward be swept up and destroyed. By these means Major W. C. Gorgas,* without expensive disin- fection and without regard for fomites, has virtually exterminated yellow fever from Havana and from the Canal Zone, Panama, where it was for many years endemic. A practical point connected with the screens is given in the work of Rosenau, Parker, Francis, and Beyer,t who found that to be effective the screens must have 20 strands or 19 meshes to the inch. If coarser than this the stegomyia mosquitoes can pass through. Reed and Carroll{ were the first to filter the blood of yellow fever patients and prove that after it had passed through a Berke- feld filter that kept back Staphylococcus aureus, it still remained infective and capable of producing yellow fever in non-immune human beings. This subject was further investigated by Rosenau, Parker, Francis, and Beyer,§ who found that the virus was even smaller than the first experiment would suggest, as it not only passed through the Berkefeld filter, but also through the Pasteur-Chamberland filter. The filtrates always remained sterile when added to culture-media. The virus has not been artificially cultivated. Prophylaxis.—Guiteras|] has studied the effect of intentionally permitting non-immunes who are to be exposed to the disease to be experimentally infected by being bitten by infected mosquitoes, after which they are at once carefully treated. His first con- clusion was that “‘the intentional inoculation gives the patient a better chance of recovery,” but the danger of death from the ex- perimental infection was later shown to be so great that it had to be abandoned. *International Sanitary Congress held at Havana, Cuba, Feb. 16, 1902: Sanitary Department, Havana, series 4. + Report of Working Party No. 2, Yellow Fever Institute, Bull. 14, May, 1904. t“Am. Med.,” Feb. 22, 1902. § “Bull. No. 14, U. S. Public Health and Marine Hospital Service,’’ Washing- ton, D. C., May, roo4. || “Revista de Medicina Tropical,’ Havana, Cuba, 1902. CHAPTER XXIV TYPHUS FEVER Typuus fever, also known as jail-fever, ship-fever, army-fever, and by a large number of other names, of which about a hundred have been collected by Murchison,* has long been known, but was probably not recognized as a definite disease before 1760, when Gaultier de Sauvage endeavored to give it individuality, or 1769 when Cullum of Edinburgh defined it. Its eventual separation from typhoid fever, with which it continued to be confused, was the result of the studies of Gerhard “On the Typhus Fever which occurred in Philadelphia in the Spring and Summer of 1836, Etc.” f The Germans still speak of typhus abdominalis, meaning typhoid or enteric fever, and typhus exanthematicus, meaning the typhus fever of the present day. TheSpanishand Mexicans callit éabardillo. The disease is largely a disease of poverty, filth and crowding, and is of frequent occurrence both in sporadic and epidemic form where such conditions occur permanently or temporarily. Its most common epidemic occurrence is therefore among the slums, in jails, in ships, in asylums, in hospitals and in armies. With the improved hygienic conditions of the present time its occurrence in consider- able epidemics is much diminished, and it is not to be expected in sanitary dwellings, among cleanly people or in well-regulated institutions. It is undoubtedly transmissible and therefore infectious, but it early became clear that the infection was not air-borne and did not readily pass from individual to individual. Further,it seems clear that the survival of an attack confers immunity against future infection. Though its infective and micro-organismal nature is clear, the specific micro-organism has not yet been discovered. This is not because it has not been made the subject of much investigation in many countries by capable men, but rather because of peculiar circumstances that make the discovery difficult, if not impossible. The early investigations of the subject were confined to dem- onstrating the truly infectious nature of a disease whose transmissi- bility was so uncertain as to permit the escape of large numbers of those exposed to it. In 1876 Moczutkowskit inoculated himself with the blood of a * “A Treatise on the Continued Fevers of Great Britain,” 3d edition, 1884, D. 161. t Amer. Jour. of the Med. Sciences, 1836, xix, p. 283; 1837, xx, Dp. 289. }‘‘Allgemeine Med. Central Zeitung,” 1900, LXVIII, 1055. 540 Transmission 541 patient suffering from typhus fever, and developed the disease eighteen days later. In 1907 Otero* endeavored to induce the dis- ease in human beings by inoculation. In one out of four attempts he was successful. Experiments with a not infrequently fatal malady made upon human beings being immoral and inexpedient, it became necessary to find some animal susceptible to the disease, with which further experiments could be prosecuted. In 1909 Nicollet succeeded in producing the disease in a chim- panzee by inoculating it with human blood. Later{ he was able to transmit the disease from the chimpanzee, and still later from human beings, to Macacus sinicus by inoculating with human blood. In 1909 Anderson and Goldberger§ were successful in transmitting the disease to monkeys, by inoculating them with human blood. Other workers corroborated these results, and thus it became clear that the suspicion that the disease was infectious was correct, and that the infectious agent was in the blood with which it could be carried over to new men and animals and reproduce the disease. Later Nicolle, Couer and Conseil|| were able to transmit the disease to guinea-pigs. In Mexico, Gavefio and Girard** were able to carry the infection through 11 transplantations from guinea-pig to guinea-pig, and still find it infective for monkeys. Still, however, the micro-organism could not be found. Two additional pfoblems therefore became important for solution. First, what was the nature of this virus that could not be found, second, how did it naturally pass from patient to patient? In October, 1910, Nicolle, Couer and Conseil} f{ instead of working with artificially defibrinated blood, permitted the blood to coagulate spontaneously, then passed it through the most porous kind of a Berkefeld filter, and successfully infected one out of two monkeys injected with the filtrate. After other series of experiments, these investigators came to the conclusion that the serum of artificially defibrinated blood, when filtered, was always without infective power, and that of spontaneously coagulated blood, commonly so,and that hence, though the virus of the disease is a filterable virus, it consists of organisms so large as to be commonly held back by the coarsest Berkefeld filters. It may be too small to be visible never- theless, at least to such methods of observation as are now in vogue. In regard to the transmission of the disease the investigators had before them the usual exemption of physicians, nurses, attendants *“Mem. pres. a l’Acad. de Med. de Mex.,” 1907. } ‘‘Ann. de I’ Inst. Pasteur,” 1910, XxIV. t“‘Compt.-rendu Acad. d. Sciences de Paris,” 1910. “Public Health Reports,” 1909, XXIV, Pp. 1941. || “Ann. de l’Inst. Pasteur,” 1910, XXV, 97. **«Publ. de ’Inst. Bact. Noc. Mex.,” 1910, Nov. 9. Tt “Ann, de l’Inst. Pasteur,” 1911, XXV, 97. 542 Typhus Fever and others who cared for patients suffering from the disease, as contrasted with its persistent spread to new patients at the foci of infection. They also had the recently gained knowledge of the part played by insects and arthropods in the transmission of malaria, relapsing fever, African lethargy, etc., the whole matter being of such nature as to make the conclusion that the infection was trans- mitted by an insect host, a justifiable one. The first to work upon this problem were Nicolle, Couer and Conseil,* the selected insects being pediculi. They permitted lice to feed upon the blood of an infected monkey, and then upon a healthy monkey. The healthy monkey contracted typhus fever. In the same year, and working independently, Goldberger and Andersont made two attempts to infect healthy monkeys by per- mitting lice fed upon cases of typhus fever in men, to bite them. They had partial success—the monkeys became diseased but no immunity tests were made for confirmation of the nature of the disease. : Ricketts and Wildert working in Mexico succeeded in transmitting typhus fever from man to monkeys by means of lice—Pediculus vestimenti. They also succeeded in transmitting the disease to a monkey by scarifying its skin and applying the abdominal contents of some infected lice, so that it was proved by them that the cause of infection was in the lice. Later Nicolle and Conseil§ also suc- ceeded in infecting a monkey by the bites of infected lice. Wilder|| further found that the infectious agent passes from the infected lice to a second generation of insects, as does the spiro- cheta of relapsing fever to subsequent generations of ornithodorus ticks. Wilder failed in experiments directed toward infecting monkeys by fleas or bed-bugs. In the experiments recorded by Wilder, the transmission of typhus fever to monkeys, by lice, was successful in 7 out of 10 attempts. It required 17 lice to infect a monkey. In one case a monkey seemed to be immunized by being bitten by very young lice. Goldberger and Anderson** also experimented with the head louse Pediculus capitus and succeeded in showing that it too takes up the typhus fever virus and may pass it on from human being to monkey, and hence probably from man to man. A description of the lice will be found in the chapter upon “Re- lapsing Fever.” *“Compt.-rendu de |’Acad. des Sciences de Paris,’’ 1909, CXLIx, 486. ¢ ‘Public Health Reports,” 1910, XXV. ee Amer. Med. Asso.,” 1910, LIV, 1304. § “Compt. -rendu. de l’Acad. des Sciences de Paris,” 1911, CLII, 1522. all’ ‘Journal of Infectious Diseases,” 1911, IXI. “Public Health Reports,” 1912, XXVII. CHAPTER XXV PLAGUE Bacittus PEstis (YERSIN, KrrasaTo) General Characteristics——A minute, pleomorphous, diplococcoid and elongate, sometimes branched, non-motile, non-flagellated, non-sporogenous, non-liquefy- ing, non-chromogenic, aérobic, pathogenic organism, easily cultivated artificially, and susceptible of staining by ordinary methods, but not by Gram’s method. Plague, bubonic plague, pest, black plague, ‘‘black death,” or malignant polyadenitis is an acute epidemic infectious febrile disease of an intensely fatal nature, characterized by inflammatory enlargement and softening of the lymphatic glands, marked pul- monary, cerebral and vascular disturbance, and the presence of the specific bacillus in the lymphatic nodes and blood. The history of plague is so full of interest that many references to it appear in popular literature. The student can scarcely find more profitable reading than the “History of the Plague Year in London,” by DeFoe, and readers of Boccacio will remember that it was the plague epidemic then raging in Florence that led to the isolation of the group of young people by whom the stories of the Decameron were told. During the reign of the Emperor Justinian the plague is said to have carried off nearly half of the population of the Roman Em- pire. In the fourteenth century it is said to have destroyed nearly twenty-five millions of the population of Europe. Epidemics of less severity but attended with great mortality appeared in the sixteenth, seventeenth, and eighteenth centuries. In 1894 an epidemic broke out in the western Chinese province of Yunnan and reached Canton in January, 1894, thus escaping from its en- demic center and began to spread. It can be traced from Canton to Hongkong. In 1895 it appeared also in Amoy, Macao, and Foochoo. In 1896 it had reached Bombay and reappeared in Hong- kong. In 1897 Bombay, the Madras Presidency, the Punjab, and Madras were visited. In 1898 the disease spread greatly through- out India and into Turkestan, and by sea went to Madagascar and Mauritius. In 1899 it extended still more widely in India and China, Japan and Formosa, and succeeded in disseminating as widely as the Hawaiian Islands and New Caledonia on the east, Portugal, Russia, and Austria on the west, and Brazil and Para- guay on the south. In 1900 it had spread to nearly every part of the world. In those places in which sanitary measures could not be carried into effect the people died in great numbers—thus in India 543 544 Plague in rgor there were 362,000 cases and 278,000 deaths. In the first six months of the epidemic of 1907, the deaths in India were much more numerous, reaching a total of 1,062,908. Where’ sanitary precautions are possible and co-operation between the people and the authorities can be brought about, as in New York, San Fran- cisco, and other North American and European ports, the disease remains confined pretty well within limits and does not spread. -An interesting account of ‘“‘The Present Pandemic of Plague” by J. M. Eager, was published in 1908 in Washington, D. C., by the U.S. Public Health and Marine Hospital Service.. Plague is an extremely fatal affection, whose ravages in the hospital at Hongkong, in which Yersin made his original observa- tions, carried off 95 per cent. of the cases. The death-rate varies in different epidemics from 50 to 90 per cent. In the epidemic at Fig. 224.—Axillary bubo. (Reproduced from Simpson’s ‘“‘A Treatise on Plague,” 1905, by kind permission of the Cambridge University Press.) Hongkong in 1894 the death-rate was 93.4 per cent. for Chinese, 77 per cent. for Indians, 60 per cent. for Japanese, too per cent. for Eurasians, and 18.2 per cent. for Europeans. It affects both men and animals, and is characterized by sudden onset, high fever, pros- tration, delirium, and the occurrence of exceedingly painful lym- phatic swellings—buboes—affecting chiefly the inguinal nodes, though not infrequently the axillary, and sometimes the cervical, nodes. Death comes on in severe cases in forty-eight hours. The pneumonic form is most rapidly fatal. The longer the duration of the disease, the better the prognosis. Autopsy in fatal cases re- veals the characteristic enlargement of the lymphatic nodes, whose contents are soft and sometimes purulent. Wyman,* in his very instructive pamphlet, “The Bubonic * Government Printing Office, Washington, D. C., 1900. Specific Organism 545 Plague,” finds it convenient to divide plague into (2) bubonic or ganglionic, (b) septicemic, and (c) pneumonic forms. Of these, the bubonic form is most frequent and the pneumonic form most fatal. Specific Organism.—The bacillus of bubonic plague was inde- pendently discovered by Yersin* and Kitasatot in the summer of 1894, during an epidemic of the plague then raging at Hongkong. There seems to be little doubt but that the micro-organisms de- scribed by the two observers are identical. Ogatat states that while Kitasato found the bacillus in the ‘blood of cadavers, Yersin seldom found it in the blood, but always in the enlarged lymphatic glands; that Kitasato’s bacillus retains the color when stained by Gram’s method; Yersin’s does not; that Kitasato’s bacillus is motile; Yersin’s non-motile; that the colonies of Kitasato’s bacillus, when grown upon agar, are round, irregular, Fig. 225.—Bacillus of bubonic plague (Yersin). grayish white, with a bluish tint, and resemble glass-wool when slightly magnified; those of Yersin’s bacillus, white and transparent, with iridescent edges. Ogata, in his investigations, found that the bacillus corresponded with the description of Yersin rather than that of Kitasato, and it is certain that of the two the description given by Yersin is the more correct. In the “Japan Times,” Tokio, November 28, 1899, Kitasato explains that, his investigations being made upon cadavers that were partly putrefied, he was led to believe that the bacillus first invaded the blood. Later studies upon living subjects showed him the error of this view and the correctness of Yersin’s observation that the bacilli first multiply in the lymphatics. Both Kitasato and Yersin showed that in blood drawn from the *“ Ann, de l’Inst. Pasteur,” 1894, 9. ts 9 ‘ t Preliminary notice to the bacillus.of bubonic plague, Hongkong, July 7, 1894. }“Centralbl. f. Bakt. u. Parasitenk.,” Sept. 6, 1897, Bd. xxi, Nos. 6 and 7, p. 170. 35 546 ' Plague finger-tips and in the softened contents of the buboes the bacillus. may be demonstrable. Morphology.—The bacillus is quite variable. Uusally it is short and thick—a ‘‘coco-bacillus,” as some call it—with rounded ends. Its size is small (1.5 to 2 wu in length) and 0.5 to 0.75 uw in breadth. It not infrequently occurs in chains of four or six or even more, and is occasionally encapsulated. It shows active Brownian movements, which probably led Kitasato to consider it motile. Yersin did not regard it as motile, and was correct. Gordon* claims that some of the bacilli have flagella. No spores are formed. Staining.—It stains by the usual methods; not by Gram’s method. When stained, the organism rarely appears uniformly colored, be- ing darker at the ends than at the center, so as to resemble a dumb- bell or diplococcus. The bacilli sometimes appear vacuolated, Serpe Fig. 226.—Bacilli of plague and phagocytes, from human lymphatic. gland X 800 (Aoyama). and nearly all cultures show a variety of involution forms. Kitasato has compared the general appearance of the bacillus to that of chicken-cholera. Involution forms on partly desiccated agar-agar not containing glycerin are said by Haffkine to be characteristic. The microbes swell and form large, round, oval, pea-shaped, spindle-shaped or biscuit-like bodies which may attain twenty times the normal size, and gradually lose the ability to take the stain. Such involu- tion forms are not seen in liquid culture. Cultivation.—Pure cultures may be from the blood or from the softened contents of the buboes, and develop well upon artificial media. The optimum temperature is about 30°C. The extremes at which growth occurs are 20° and 38°C. *“Centralbl. f. Bakt. u. Parasitenk.,” June 24, 1897, Bd. xx, Nos. 20 and 21. ~ Bouillon 547. -Bouillon.—In bouillon a diffuse cloudiness was observed by Kitasato, though Yersin observed that the cultures resembled ery-. sipelas cocci, and contained zodglea attached to the sides and at the bottom of the tube of nearly clear fluid. Fig. 227—Bacillus pestis. Highly virulent culture forty-eight hours old, from the spleen of a rat. Unstained preparation (Kolle and Wassermann). Haffkine* found that when an inoculated bouillon culture is allowed to stand perfectly at rest, on a firm shelf or table, a char- acteristic appearance develops. In from twenty-four to forty- eight hours, the liquid remaining limpid, flakes appear underneath Fig. 228.—Bacillus pestis. Involution forms from a pure culture on 3 per cent. sodium chlorid agar-agar. Methylene-blue (Kolle and Wassermann). the surface, forming little islands of growth, which in the next twenty-four to forty-eight hours grow into a jungle of long stalactite- like masses, the liquid remaining clear. In from four to six days these islands become still more compact. If the vessels be dis- * “Brit. Med. Jour.,” June 12, 1897, p. 1461. 548 Plague turbed, they fall like snow and are deposited at the bottom, leaving the liquid clear. Colonies.—Upon gelatin plates at 22°C. the colonies may be observed in twenty-four hours by the naked eye. They are pure white or yellowish white, spheric when deep in the gelatin, flat when upon the surface, and are about the size of a pin’s head. The gelatin is not liquefied. Upon microscopic examination the borders of the colonies are found to be sharply defined. The contents be- come more granular as the age increases. The superficial colonies are occasionally surrounded by a fine, semi-transparent zone. Klein* says that the colonies develop quite readily upon gelatin made from beef bouillon (not infusion), appearing in twenty-four hours, at 20°C., as small, gray, irregularly rounded dots. Magnifica- tion shows the colonies to be serrated at the edges and made up of Fig. 229.—Stalactite growth of bacillus pestis in bouillon. (Reproduced from Simpson’s ‘‘A Treatise on Plague,’’ 1905, by kind permission of the Cam- bridge University Press.) : short, oval, sometimes double bacilli. Some colonies contrast markedly with their neighbors in that they are large, round, or oval, and consist of longer or shorter, straight or looped threads of bacilli. The appearance was much like that of the young colonies of Proteus vulgaris. At first these were regarded as contaminations, but later their occurrence was regarded as characteristic of the plague bacillus. The peculiarities of these colonies cannot be recognized after forty- eight hours. Gelatin Punctures.—In gelatin puncture cultures the develop- ment is scant.. The medium is not liquefied; the growth takes place in the form of a fine duct, little points being seen on the surface and in the line of puncture. Sometimes fine filaments project into the gelatin from the central puncture. Abel found the best culture-medium to be 2 per cent. alkaline *“Centralbl. f. Bakt. u. Parasitenk.,” July 10, 1897, xx1, Nos. 24 and 25. Vital Resistance 549 peptone solution containing 1 or 2 per cent. of gelatin, as recom- mended by Yersin and Wilson. Agar-agar.—Upon agar-agar the bacilli grow freely, but slowly, the colonies being whitish in color, with a bluish tint by reflected light, and first appearing to the naked eye when cultivated from the blood of an infected animal after about thirty-six hours’ incubation at 37°C. Under the microscope they appear moist, with rounded uneven edges. The small colonies are said to resemble tufts of glass-wool. Microscopic examination of the agar-agar culture shows the presence of chains resembling streptococci. Upon glycerin-agar the development of the colonies is slower, though in the end the colonies attain a larger size than those grown upon plain agar. Hankin and Leumann* recommended, for the differential diagnosis of the plague bacillus, a culture-medium prepared by the addition of 2.5 to 3.5 per cent. of salt to ordinary culture agar-agar. When transplanted from ordinary agar-agar to the salt agar-agar, the in- volution forms so characteristic of the bacillus occur with ex- ceptional rapidity. In bouillon containing this high percentage of salt the stalactite formation is beautiful and characteristic. Blood-serum.—Upon blood-serum, growth, at the temperature of the incubator, is luxuriant and forms a moist layer, of yellowish- gray color, unaccompanied by liquefaction of the serum. Potato.—Upon potato no growth occurs at ordinary temperatures. When the potato is stood in the incubator for a few days a scanty, dry, whitish layer develops. Vital Resistance.—Kitasato found that the plague bacillus did not seem able to withstand desiccation longer than four days; but Rappaportt found that they remained alive when kept dry upon woolen threads at 20°C. for twenty-three days, and Yersin found that although it could be secured from the soil beneath an infected house at a depth of 4 to 5 cm., the virulence of such bacilli was lost. Kitasato found that the bacillus was killed by two hours’ ex- posure to 0.5 per cent. carbolic acid, and also by exposure to a temperature of 80°C. for five minutes. Ogata found the bacillus instantly killed by 5 per cent. carbolic acid, and in fifteen minutes by 0.5 per cent. carbolic acid. In 0.1 per cent. sublimate solution _ it is killed in five minutes. According to Wyman, the bacillus is killed by exposure to 55°C. for ten minutes. The German Plague Commission found that the bacilli were killed by exposure to direct sunlight for three or four hours; and Bowhill{ found that they are killed by drying at ordinary toom temperatures in about four days. 4. Centralbl. f. Bakt. u. Parasitenk.,” Oct., 1897, Bd. xx11, Nos. 16 and 17, p. 38. t Quoted by Wyman. t “Manual of Bacteriological Technique and Special Bacteriology,” 1899, p. 197- 4 550 : Plague Wilson* found the thermal death-point ‘of the organism one or two degrees higher than that of the majority of non-sporulating pathogenic bacteria, and that the influence of sunlight and desicca- tion cannot be relied upon to destroy it. Rosenauft found temperature the most important factor, as it dies quickly when kept dry at 37°C., but remains alive for months when kept dry at 19°C. Sunlight kills it in a few hours. A tem- perature of 70°C. is invariably fatal in a short time. Metabolism.—The bacillus develops best under aérobic con- ditions though it develops to a slight extent also under anaérobic conditions. In glucose-containing media it does not form gas. No indol is formed. Ordinarily the culture-medium is acidified, the acid reaction persisting for three weeks or more. Ghon,t Wernicke,§ and others who have studied the toxic . products of the bacillus all incline to the belief that it forms only endotoxin. Kossee and Overbeck,|| however, believe that there is, in addition, .a soluble exotoxin that is of importance. Bielonovsky** finds that broth, agar, and serum cultures of the plague bacillus possess the property of hemolyzing the blood of normal animals. The hemolytic power of filtrates of plague cultures increases up to the thirteenth or fourteenth day, then gradually di- minishes, but without completely disappearing. The hemolysins are notably resistant to heat, not being destroyed below 100°C. Experimental Infection.—Mice, rats, guinea-pigs, rabbits, and monkeys are all susceptible to experimental inoculation. When blood, lymphatic pulp, or pure cultures are inoculated into them, the animals become ill in from one to two days, according to their size and the virulence of the bacillus. Their eyes become watery, they show disinclination to take food or to make any bodily effort, the temperature rises to 41.5°C., they remain quiet in a corner of the cage, and die with convulsive symptoms in from two to seven days. If the inoculation be made intravenously, no lymphatic enlargement occurs; but if it be made subcutaneously, the nearest lymph nodes always enlarge and suppurate if the animal live long enough. The bacilli are found everywhere in the blood, but not in very large numbers. Rats suffer from both an acute septicemic and a chronic form of the disease. In the former an infiltration or watery edema can be observed in a few hours about the point of inoculation. The autopsy shows the infiltration to be made up of a yellowish gelatinous exuda- * “Journal of Medical Research,” July, 1901, vol. vr, No. 1, p. 53. } Bulletin No. 4 of the Hygienic Laboratory of the U. S. Marine Hospital Service, 1901. : t Wien, 1808. § “Centralbl. f. Bakt.,” etc., 1898, xxiv. { “Arbeiten aus d. Kaiserl. Gesundheitsamte,” 1901, xvuzt. * “Arch. des Sci. Biol.,” Petersb., 1904. St. Tome x, No. 4. Mode of Infection BST tion. The spleen and liver are enlarged, the former often pre- senting an appearance similar to that observed in miliary tuber- culosis. Sometimes there is universal enlargement of the lymphatic glands. Bacilli are found in the blood and in all the internal organs. Skin eruptions may occur during life, and upon the inner abdominal walls petechie and occasional hemorrhages may be found. The intestine is hyperemic, the adrenals congested. Serosanguinolent effusions may occur into the serous cavities. In the latter, they sometimes have encapsulated caseous nodules in the submaxillary glands, caseous bronchial glands, and fibroid pneumonia, months after infection. In all such cases virulent plague bacilli are present. In and about San Francisco the extermination of rats for the eradication of the plague was unexpectedly complicated by the discovery that other rodents with which the rats came into contact also harbored the plague bacilli. McCoy and Smith* found this to be true of the prairie dog, the desert wood rat, the rock squirrel, and the brush rat. To insure security against the recurrence of the disease among men necessitates continued observation of these animals and the extermination of diseased colonies, as well as their complete extermination in the neighborhood of human habitations. Devell} has found frogs susceptible to the disease. Mode of Infection.—The plague bacillus may enter the body by inhalation, from an atmosphere through which it is disseminated, under which circumstances it usually causes the pneumonic type of the disease which is not unlike other forms of pneumonia. The lung is consolidated, enormous numbers of plague bacilli occur in the sputum, the fever is high, and death occurs in a few days. Plague pneumonia does not necessarily imply infection through inhalation of the bacilli, however, for it occasionally occurs as a complication in the bubonic form of the disease. Klein found that animals fed upon cultures of the bacillus or upon the flesh of animals dead of the disease became ill and died with typical symptoms. Simond has confirmed his results and it is not improbable that the disease is sometimes acquired by rats through feeding upon their companions that have died of it. The micro-organisms seem able to penetrate any of the mucous mem- branes, so that infection usually follows their application to the un- injured conjunctiva, nasal, buccal, vaginal or gastro-intestinal surfaces. _ Cutaneous and Subcutaneous Inoculation—All susceptible ani- mals quickly become infected if a needle infected with ‘a culture of the bacilli or with material from a bubo or other infective lesion be used to puncture or scratch the skin. Wyssokowitsch and Zabolotnyt found monkeys highly susceptible to plague, especially * “Journal of Infectious Diseases,”’ 1910, VII, p. 374. t “Centralbl. f£. Bakt. u. Parasitenk.,”’ Oct. 12, 1897. 552 Plague when subcutaneously inoculated. When an inoculation was made with a pin dipped in a culture of the bacillus, the puncture being made in the palm of the hand or sole of the foot, the monkeys always died in from three to seven days. In these cases the local edema observed by Yersin did not occur. They point out the interest attaching to infection through so insignificant a wound and without local lesions. Weichselbaum, Albrecht and Gohn have found that rats may be infected by rubbing the infective material upon the surface of the shaved skin, the method being employed for making a diagnosis of the disease in suspected cases. Rats and mice in- Antepygidial bristle Abdomen Thorax Head Katona 2a : : , Eye Pygidium SSS 3S S54 ie —— + Ocular bristle Aw oy ry. f 5 pe"), Oral bristle Stigmata -4\\qy~ fa, NA of ‘i Ho n> --8 S25 po ee i Penis Mil X “Sie (\ axillary palp In\ . \ Maxilla Y y titt--. Hip or coxa iN -- Trochanter ‘ Ay ++ Femur LS te eeg Tarsi Vs 7 ys fy ,- 7 7, Fig. 230.—Xenopsylla cheopis (male) (from Rothschild). fected through the skin usually die in two or three days, guinea- pigs in two to five days, rabbits in three to eight days. The facility with which dermal infection could be brought about, quickly suggested that the skin might be the common route, and that biting insects might act as vectors. Yersin showed that flies taking up the bacilli may die of the in- fection. Macerating and crushing a fly in bouillon, he not only succeeded in obtaining the bacillus, but infected an animal with it. Nuttall,* in repeating Yersin’s fly experiment, found his observa- tion correct, and showed that flies fed with the cadavers of plague- . infected mice die in a variable length of time. Large numbers of plague bacilli were found in their intestines. He also found that bed-bugs allowed to prey upon infected animals took up large *“Centralbl. f. Bakt. u. Parasitenk.,” xx1, No. 24, Aug. 13, 1807. Mode of Infection 553 numbers of the plague bacilli and retained them for a number of days. These bugs did not, however, infect healthy animals when allowed to bite them; but Nuttall was not satisfied that the number of his experiments upon this point was great enough to prove that plague cannot be thus spread. Vergbitski,* however, was more successful and a bed-bug that he caused to bite a patient suffering from plague, subsequently transmitted the disease to a rat. It is quite possible that mosquitoes and biting flies may transmit it. As epidemics of human plague are commonly preceded by epi- demics among the rats which die in great numbers, it early became a question whether the plague among them was not caused by the bites of fleas, and whether it might not also be fleas that infected man. M. Herzogt has shown that pediculi may harbor plague bacilli and act as carriers of the disease. Ogata found plague bacilli in fleas taken from diseased rats. He crushed some fleas between sterile object-glasses and introduced the juice into the subcutaneous tissues of a mouse, which died in three days with typical plague, a control-animal remaining well. Some guinea-pigs taken for experimental purposes into a plague district died spontaneously of the disease, presumably because of flea infection. Galli-Valeriot and others think that the fleas of the mouse and rat are incapable of living upon man and do not bite him, and that it is only the Pulex irritans, or human flea, that can transmit the disease from man to man. Tidswell,§ however, found that of too fleas collected from rats—there were four species, of which three—the most common kinds—bit men as well as rats. Lisbon found that of 246 fleas caught on men in the absence of plague, only one was a rat flea, but out of 30 fleas caught upon men in a lodging- house, during plague, 14 were rat fleas. This seems to show that as the rats die off their fleas seek new hosts, and may thus contribute to the spread of the disease. That fleas can cause the transmission of plague from animal to animal has been proved by experiments made in India. These experiments, which are published as ‘‘ Reports on Plague Investiga- tions in India,” issued by the Advisory Committee appointed by the Secretary of State for India, the Royal Society, and the Lister Institute, appear in the “Journal of Hygiene” from 1906 onward.** It seems from these experiments that human fleas (Pulex irritans) do not bite rats, but that the rat fleas of all kinds do, though not *“Tour, of Hygiene,” 1904, VTII, 185. t “Amer. Jour. Med. Sci.,” March, 189s. ¥Ibid., xxv, No. 1, p. 1, Jan. 6, 1900. } “British Medical Journal,” June 27, 1903. Times of India,” Nov. 26, 1904. ** “ Tournal of Hygiene,” Sept., 1906, vol. v1, p. 421; July, 1907, vol. vit, p. 324; ec., 1907, vol. VII, p. 693; May, 1908, vol. vit, p. 162; 1909, vol. 1x; 1910, vol. X} 1911, vol, x1. 554 Plague willingly, bite men. By placing guinea-pigs in cages upon the floor of the infected houses, the fleas of all kinds quickly attack them with resulting infection, but if the guinea-pigs are kept in flea- proof cages, or if the cages are surrounded by ‘‘tangle-foot,” or “sticky fly-paper,” the fleas, not being able to spring over the barrier, are caught on the sticky surfaces and do not reach the guinea- pigs, which then remain uninfected. What is true of the guinea- pigs is undoubtedly true of the rats; the disease is transmitted from rat to rat by the fleas. When the rats die, the fleas being hungry, jump upon any convenient warm-blooded animal to satisfy their appetites, and when human beings become their victims, infection may follow the bites. It is now clearly demonstrated that though Pulex irritans, the human flea, prefers to bite human beings, and Xenopsylla cheopis, the rat flea, prefers to bite rats, under stress of necessity preferences are set aside and miscellaneous feeding prac- tised by these and probably all other fleas. A peculiar circumstance attending flea infection has been discovered by Bacot and Martin* who find that when Xenopsylla cheopis and Ceratophyllus fasciatus are fed upon septicemic plague blood, the re- spective fleas suffer from a temporary obstruction at the entrance of the stomach, caused by a massive growth of the plague bacilli. This culture appears to start in the intercellular recesses of the proventriculus and grows so abundantly as to choke this organ and extend into the esophagus. Fleas in this condition are not prevented from sucking blood, as the pump is in the pharynx, but they only succeed in distending an already contaminated esophagus, and on the cessation of the pumping act, some of the blood is forced back into the wound. Such fleas are persistent in their endeavors to feed and this renders them particularly dangerous. Bacott found that infected fleas remained infectious when starved for forty-seven days, and that when they were subse- quently permitted to feed upon mice, another period of ene days might supervene before the mice became infected. The cutaneous and subcutaneous inoculation in man is followed - by lymphatic invasion with bubo formation. Beyond this lymphatic barrier but few bacilli get so that in the greater number of cases with buboes there is little blood infection. However, should the bacilli be highly virulent or the patient exceptionally susceptible, the septicemic form of the disease may supervene, and the case progress to a rapidly fatal termination. Intravenous and Intraperitoneal Inoculations produce rapidly fatal septicemic forms of plague. Kleint found that intraperitoneal injection of the bacillus into guinea-pigs was of diagnostic value, producing a thick, cloudy, * “The Journal of Hygiene, ” Plague Supplement, 11, 1914, p. 423. t “Journal of Hygiene,” Plague Supplement, No. rv, Jan., 1915, p. 770. t “Centralbl. f. Bakt. u. Parasitenk.,” xx1, No. 24, July 10, TED Be 849. Diagnosis 555 peritoneal exudate rich in leukocytes and containing characteristic chains of the plague bacillus, occurring in from twenty-four to forty-eight hours. . Diagnosis.—It seems possible to make a diagnosis of the disease in doubtful cases by examining the blood, but it is admitted that a good deal of bacteriologic practice is necessary for the purpose. Abel found that blood-examinations may yield doubtful results because of the variable appearance of the contained bacilli, which may easily be mistaken for other bacteria. He deems the best tests to be the inoculation of broth cultures and the subsequent inoculation into animals, which, he advises, should have been pre- viously vaccinated against the streptococcus. Kolle* has suggested a method valuable both for the diagnosis of the disease and for estimating the virulence of the bacillus. It is as follows: ‘The skin over a portion of the abdominal wall of the guinea-pig is shaved, care being taken to avoid the slightest injury of the skin. The infective material is carefully rubbed into the shaved skin. Important, in order rightly to understand the occurrence of plague infection, is the fact disclosed here in the case of guinea-pigs, that by this method of inoculation the animals present the picture of true bubonic plague—that is to say, the pro- duction of nodules in the various organs, principally in the spleen. In this manner guinea-pigs, which would not be affected by large subcutaneous injections, even amounting to 2 mg. of agar culture (equal to a loop) of low-virulence plague bacillus, may be infected and eventually succumb.” The postmortem appearance of the body of a plague-infected — rat is as follows: Subcutaneous hemorrhages occur in about 40 ' per cent. of the animals and are most frequently to be seen in the submaxillary region. Buboes are present in the majority of cases, usually in some one locality, and commonly about the neck. The liver may show necrotic changes which have the appearance of an excessive deposit of fat, and a condition of the greatest importance in diagnosis is the occurrence of small necrotic foci scattered over its surface and throughout its substance. The spleen is firm and does not collapse like a soft normal spleen; granules or nodules may be well marked in it and may be confluent. The kidneys and suprarenal capsules are often congested. Hemorrhages are fairly common in the lungs and visceral pleura. The presence of pleural effusion is very characteristic and of great value in diagnosis. In naturally infected plague rats, the most important features for purposes of diagnosis are: 1. A typical bubo—most commonly in the neck. 2. Granular liver—not seen except in plague rats. * “See Havelburg, “Public Health Reports,” Aug. 15, 1902, vol. xvi, No. 33, P. 1863. } See “Journal of Hygiene,” 1907, VII, 324. 556 Plague 3. Hemorrhages beneath the skin and i in the internal organs are very suggestive. 4. Pleural effusion. In putrid rats, bubo, granular liver and pleural effusion may persist and are of great significance. A microscopical examination of scrapings from buboes and spleen and inoculation tests will clinch the diagnosis (Besson). Virulence.—By frequent passage through animals of the same species the bacillus can be much increased in virulence. Kolle recommended rats for this purpose, and, indeed, declared that without the use of rats it is impossible to keep cultures at a high grade of virulence. According to the researches of the Advisory Committee for the study of plague in India, this is an error. The virulence of plague bacilli for rats is subject to very little change. Their members in investigating the question made twenty-six passages from rat to rat, by subcutaneous inoculation, during eighty-nine days, and found the original virulence of the organism unchanged. Yersin found that when cultivated for any length of time upon culture-media, especially agar-agar, the virulence was rapidly lost and the bacillus eventually died. On the other hand, when con- stantly inoculated from animal to animal, the virulence of the bacillus is much increased. Knorr, Yersin, Calmette, and Borrel* have shown that the bacillus made virulent by frequent passage through mice is not in- creased in virulence for rabbits. This no doubt depends upon the sensitivity of the bacillus to the protective substances of the body juices, immunization against those of one animal not necessarily protecting the organism against those of other animals. Sanitation.—A disease that may be transmitted from man to man by atmospheric infection and inhalation, that can be transported from place to place by fomites, that occurs in epidemic form among the lower animals as well as among men, and that can be trans- mitted from man to man and from lower animals to man by biting insects, must inevitably become a source of anxiety to the sanitarian. The preventive measures must take account of men, rats, and goods. If vessels are permitted to visit and leave plague-stricken ports, means must be taken to see that all passengers are healthy at the time of leaving and have remained so during the voyage, and provision should be made at the port of entry for the disinfection of the cargo before the goods are landed. But the rats must be given special consideration, for, so soon as the vessel reaches port some of them jump overboard and swim to the shore, carrying the disease with them. When a vessel visits a plague port, every pre- caution should be taken to prevent the entrance of rats, first by * “Ann, de l’Inst. Pasteur.,” July, 1895. Immunity 557 anchoring in the stream instead of tying to the dock; by carefully scrutinizing the packages taken from the lighters to see that there are no rats hidden among them; by placifg large metal shields or reversed funnels about all anchor chains, hawsers, and cables so that no rats can climb up from the water in which they are swim- ming at night. Arrangements should also be made for rat destruc- tion on board the ship by means of sulphurous oxid or other poi- sonous vapors to rid the ship of rats before the next port is reached. Passengers and crew should also be kept in quarantine before ming- ling with society. It is much more easy to keep plague out of a port than to combat it when it has entered, for under the latter condition are involved the isolation of the patients in rat-free and vermin-free quarters, the disinfection of the premises and goods where the case arose, and an immediate warfare upon the rats and other small animals of the neighborhood. To emphasize how difficult the latter may be it is only necessary to point out that plague reached San Francisco in May, 1907, during which year there were 156 cases and 76 deaths. Every precaution was taken to prevent its spread, and though the extermination of rats was practised at great expense and with the utmost thoroughness, the disease spread to the ground squirrels and other small rodents, and in 1914 plague-infected rodents were still to be found in the outskirts . of the city. Immunity.—An attack of plague usually exempts from future attacks. Artificial immunity may therefore be induced in both man and the lower animals by a variety of methods. I. Active Immunity—Haffkine* followed his plan of preventive inoculation as employed against cholera, and has invented a method of prophylaxis based upon the use of devitalized cultures. Bouillon cultures are grown in flasks for six weeks; small floating drops of butter being employed to make the “islands” of plague bacilli float. Successive crops of the island-stalacite growth are pre- cipitated by agitating the flasks. In this manner an “intense extra- cellular toxin,” containing large numbers of the bacilli is prepared. After testing the purity of the culture by transplantation to agar- agar, it was killed by exposure to 65°C. for one hour and received an addition of o.5 per cent. of phenol. The preparation was used in doses of 2 to 3 cc. as a preventive inoculation. A more thorough and prolonged immunity resulted from the administration of a second dose ten days after the first. An interesting collection of statistics, showing in a convincing manner the value of the Haffkine prophylactic, is published by Leumann, of Hubli. The figures, together with a great deal of interesting information upon the subject, can be found in the paper upon “A Visit to the Plague Districts in India,” by Barker and Flint.t * “Brit, Med. Jour.,” June 12, 1897; “India Medical Gazette,” 1897. t “New York Med. Jour.,” Feb. 3, 1900. 553. Plague — The German Plague Commission* believed that an important improvement in the vaccine could be brought about by the use of: the method now generally employed in making bacterio-vaccines (q.v.). They therefore caused the bacilli to grow in Roux bottles upon the surface of agar-agar for forty-eight hours, washed off the bacteria with bouillon or physiological salt solution so that 1 cc. of the suspension contained about 2.5 mg. of bacilli, and then heated the suspension for an hour or so at 65°C. After heating, 0.5 per cent. of phenol was added. This mode of preparation has the advantage of excluding the possibility of the accidental growth of tetanus bacilli and other micro-organisms in the culture. The vaccine appeared to give excellent results in Brazil where it was extensively used. Haffkine, however, considers his method preferable because of the greater quantity of immunizing metabolic products of the bacilli contained in the fluid cultures on account of their prolonged growth. The immunity conferred by the Haffkine prophylactic is supposed to last about a year. The preparation must never be used if the person has already been exposed to infection, and is in the incuba- tion stage of the disease, as it contains the toxins of the disease, and therefore greatly intensifies the existing condition. When injected into healthy persons it always produces some fever, slight local swellings, and malaise. Kolle and Ottot from experimental studies of plague immunity in rats, came to the conclusion that a prophylactic injection con- sisting of a culture of attenuated plague bacilli would have a much more powerful and lasting effect than one consisting of a killed bacilli. The same conclusion was reached by Kolle and Strong{ and the first use of living cultures for preventive inoculation in human beings was by Strong§ who found them to be devoid of danger, and is hopeful regarding their efficacy. Besredkal| advises the use of a killed culture sensitized by the application of immune serum. Such vaccine seems to be productive of long enduring immunity when tried upon experimental animals. Rowland** is under the impression that the essential immunizing antigen is in the bacterial nucleoproteins. These he extracts from the bacterial cells by treating them while moist with anhydrous sodium sulphate, freezing, permitting the water to be absorbed by the chemical, thawing, and then filtering off the fluid at 37°C. The filtrate thus obtained is highly toxic, fatal to rats in minute doses and capable of effecting immunization. II. Passive Immunity against plague, through the employment * “ Arbeiten aus dem Kaiserl. Gesundheitsamte,” 1899, Xv1. Tt “Deutsche med. Wochenschrift,” 1903, p. 493; ‘Zeitschrift fiir Hygiene,” 1903, XLV, 507. t “Deutsche med. Wochenschrift,” 1906, XXXII, 413. “Jour. Medical Research,” N. S., 1908, XVII, 325. | , Bull. de Inst. Pasteur,” 1910, VIII, 241. “Jour. of Hygiene,” 1912, x11, 344. The Plague Fleas 559 of the serums of experimentally immunized animals for hypo- dermatic injection into man was tried soon after the discovery of the plague bacillus. Kitasato’s experiments first showed that it was possible to bring about immunity against the disease, and Yersin, working in India, and Fitzpatrick, in New York, have successfully immunized large animals (horses, sheep, and goats). The serum of the immunized animals contains specific agglutinins and bacteriolysins as well as an antitoxin, capable not only of pre- venting the disease, but also of curing it in mice and guinea-pigs and probably in man. Study of plague serums has been conducted by Yersin, Calmette and Borrel,* but their value as a prophylactic lacks demonstration. Wyssokowitsch and Zabolotny,t used 96 monkeys in the study of the value of the “‘plague serums,” and found that when treatment was begun within two days from the time of inoculation the animals could be saved, even though symptoms of the disease were marked. After the second day the treatment could be relied upon. The dose necessary was 20 cc. of a serum having a potency of1:10. If toolittle serum was given, the course of the disease was retarded and_the animal improved for a time, then suffered a re- lapse, and died in from thirteen to seventeen days. The serum also produced immunity, but of only ten to fourteen days’ duration. Immunity lasting three weeks was conferred by inoculating a monkey with an agar-agar culture heated to 60°C. If too large a dose of such a culture was given, however, the animal was enfeebled and remained susceptible. a THE PLAGUE FLEAS Fleas were formerly classed as a suborder of the Diptera, or two-winged in- sects, and because they had no wings, were known as Aphaniptera. At the present time they constitute an order by themselves, the Siphonaptera. Every flea undergoes a complete metamorphosis. It begins its life history as a minute, oval, pearly-white egg measuring about 0.6 mm. in length, that falls from the body of the female to the floor or ground. The eggs of fleas are not cemented to the hairs like those of lice, but drop to the ground where the larva lives. More or less eggs are therefore always scattered about where dogs, cats, rats, mice or other animals that harbor fleas are to be found, and more or less larve and pupe are likewise to be found in such places. In the course of from five to ten days, a minute, active caterpillar-like larva emerges from the egg to feed upon such organic matter as it may find for the six to eight weeks of this stage. During the larval period the skin is shed three or four times. When full grown, the larva empties its alimentary canal, spins itself a tiny silken cocoon, sometimes including minute bits of rubbish or grains of sand in its structure, sheds its skin for the last time, and becomes a pupa. As such it is inactive for from two to eight weeks, according to external conditions of temperature and moisture, then opens the cocoon and emerges from the pupa shell, a perfect in- sect—the flea proper. The adult fleas, both males and females, have soft exoskeletons at first, but soon they harden, through the formation of chitin, to the well-known tough and brittle armor. The male differs from the female in being smaller and in its shorter abdomen. ‘ *«“ Ann, de l’Inst. Pasteur,” 1895, Ix, 589. T Loc. cit. 560 Plague Both insects hop about in search of the appropriate warm-blooded hosts upon whose blood they are to live. Each kind of flea has a preferred host, but the tastes of all are more or less cosmopolitan, so that in the absence of the preferred host, another kind of warm-blooded creature will do. Adult fleas live solely by sucking blood. The longevity of a flea varies according to conditions of temperature and mois- ture Life is longest when the temperature is high and the ground not too dry. They may live for months without feeding; when regularly fed they can live at least a year and ahalf. The longevity of the fleas in the adult stage, the long periods of abstention from food that they may suffer without dying, and the ac- cessions to their numbers that may occur through the perfection of their embry- onal fellows in the same place, explain why families returning to their closed city houses, or going to their closed country houses, sometimes find them after months of desertion, occupied by a welcoming host of fleas. They are the progeny of Be em Fig. 231.—Various fleas, magnified about 30 diameters. The specimens are treated with hot 20 per cent. caustic potash for a few minutes, dehydrated in alcohol, cleared in xylol and mounted in balsam. a, Ceratophyllus fasciatus 7; b, Ceratophyllus fasciatus, ? ;c, Leptopsylla musculi, #; d, Leptopsylla musculi, 2 (Bacot, in Journal of Hygiene, “Plague Supplement m1, 1914”). the fleas of the former dog, cat, rat or mouse tenants, that have matured or survived the interval and are now hungry because the removal of the family months before, was probably followed by the withdrawal of the rats and mice no longer able to find food in the deserted habitation. To get rid of such fleas is often a perplexing question. A way to accomplish it is to place a cage containing a cat or a guinea-pig, or a trap containing living rats or mice on the floor of a room and surround it by sticky fly-paper. Fleas when empty and hungry, were found by Strickland* to be able to jump 4 inches; those recently fed only 3 inches. In their endeavors to reach the caged animals the fleas jump upon the fly-paper and are caught. This can be done in several rooms of the house and soon cleans up the fleas. During such periods of fasting the sexes do not copulate and no ova are pro- duced. As soon as blood is taken, copulation takes place, and if the blood be * “Journal of Hygiene,” 1914, xIv, p. 120. The Plague Fleas 561 that of the preferred host, ovulation follows in about twenty-four hours. The eggs are relatively large, and small numbers are produced. In the case of Sarcopsylla penetrans, a flea that has no known interest in con- nection with plague transmission, the female after copulation imbeds itself in the skin of the host and suffers an enormous saccular distension of the abdomen where many ova are produced. Ordinary fleas never imbed themselves but sim- ply bite and suck blood, leaping off of the host when satisfied. Epidemics of plague among men are commonly preceded by epizootics of plague among rats. The mortality of the rats being high and their number diminishing, many fleas are unprovided for and seek human hosts upon whom to satisfy their appetites. In this way, the plague which was at first transmitted by the fleas to the rats, is now transmitted to men. Human fleas may also trans- i TPE Fig. 232.—Various fleas, magnified about 30 diameters. The specimens are treated with hot 20 per cent. caustic potash for a few minutes, dehydrated in alcohol, cleared in xylol and mounted in balsam. a, Ctenocephalus canis, @; b Ctenocephalus canis, 2; c, Ctenocephalus felis, #; d, Ctenocephalus felis, @ (Bacot, in Journal of Hygiene, “Plague Supplement 11, 1914”). mit the infection from man to man, but the bulk of the transmission probably takes place through rat fleas. When the plague spreads from the rat to ground squirrels or to marmots, rare fleas may engage in the transmission of the disease from animal to animal and ae man to man, but ordinarily it is the common rat fleas that are responsible or it. : Both rats and fleas vary in prevalence and in relative frequency in different parts of the world. Thus there are three common rats: Mus decumanus, the brown or sewer rat, Mus rattus, the black or house rat and Mus norvegius, the Norway rat. In Northern Europe, the Mediterranean coast, Egypt and North America, the Norway rat has colonized more or less successfully. Where it Preponderates Ceratophyllus fasciatus isa common flea. Where Mus decumanus and Mus rattus alone are found, or are preponderant, Xenopsylla cheopis is the common flea. In the Orient, Xenopsylla cheopis is the chief flea that is to be taken into account in plague transmission. The dog flea Ctenocephalus canis 36 : 562 Plague is common everywhere as is Pulex irritans, the human flea. It is likely that any or all of these engage in plague transmission when once an epidemic has started, but the most active vector of the disease, the world over, and the most important agent in starting human epidemics of plague is Xenopsylla cheopis. Much interesting and valuable information concerning the biology, bionomics Gite a Vo Bis co oe. a No ee Fig. 233.—Various fleas, magnified about 30 diameters. The specimens are treated with hot 20 per cent. caustic potash for a few minutes, dehydrated in alcohol, cleared in xylol and mounted in balsam. a, Pulex irritans, 7; b, Pulex irritans, ? ;c, Xenopsylla cheopis, “; d, Xenopsylla cheopis, 2 (Bacot, in Journal of Hygiene, ‘‘ Plague Supplement 11; 1914”’). and relation of rats and fleas to plague, will be found in the “Reports of the India Plague Commission” many of which are to be found in the “Journal of Hygiene,” vols. I-XIV. The following illustrations and tabulations will enable the student to identify the common genera of fleas. For more intimate systematic study he must be referred to ‘A Text-book of Medical Entomology,” by Patton and Cragg.* * “Christian Literature Society of India, London, Madras and Calcutta,” 1913. Table for Identification of Fleas 563 TABLE FOR THE IDENTIFICATION OF THE FLEAS CONCERNED IN PLAGUE TRANSMISSION Family —PULICIDZ. Subfamily—PULICINA, All have eyes. A. Have no combs or spines on head, thorax or abdomen. a, The meso-sternite is narrow and has no rod-like incrassa- tion from the insertion of the coxa upward.............. Pulex. b. The meso-sternite has a rod- like incrassation from the insertion of the coxa up- WAR ie dordiauies ga evden see 8 Xenopsylla, B. With combs. c. Combs on the prothorax ODL Vira vase ceased vera e Ceratophyllus. d. Combs on the prothorax and on the gena or lower margin of the face.......... Ctenocephalus, OTHER MICRO-ORGANISMS OF THE PLAGUE GROUP The Bacillus pestis is a member of a group of organisms col- lectively known as the bacilli of hemorrhagic septicemia. Two of these organisms are of sufficient interest to deserve special mention. 564 Micro-organisms of the Plague Group Bacittus CHOLERZ GALLINARUM (PERRONCITO); BacILius’ CHOLER#; BacrtLttus AvicipuM; BacrLLus Avi- SEPTICUS; BACILLUS OF RABBIT SEPTI- cEMIA; BACILLUS CUNICULICIDA General Characteristics.—A non-motile, non-flagellated, non-sporogenous, non-liquefying, non-chromogenic, aérobic bacillus, pathogenic for birds and mammals, staining by the ordinary methods, but not by Gram’s nethod, pro- ducing acids, indol, and phenol, and coagulating milk. The barnyards of both Europe and America are occasionally visited by an epidemic disease known as “‘chicken-cholera,” Huhnercholera, or cholera de poule, which rapidly destroys pigeons, turkeys, chickens, ducks, and geese. Rabbit- warrens are also at times affected and the rabbits killed. The bacillus responsible for this disease was first observed by Perroncito* in 1878, and afterward thoroughly studied by Toussaint and Pasteur. _ Morphology.—The organisms are short and bzoad, with rounded ends, measur- ing 1 X 0.4 to 0.6 4, sometimes joined to produce chains. Pasteur at first regarded them as diplococci, because the poles stain intensely, a narrow space between them remaining almost uncolored. This peculiarity is very marked, and careful examination is required to detect the intermediate substance. The bacillus does not form spores, is not motile, and has no flagella.t Staining.—The organism stains with ordinary anilin dye solutions, but not by Gram’s method. Cultivation.—Colonies.—Colonies upon gelatin plates appear after about two days as small, irregular, white points. The deep colonies reach the surface slow- ly, and do not attain to any considerable size. The gelatin is not liquefied. The colonies appear under the microscope as irregularly rounded yellowish-brown disks with distinct smooth borders and granular contents. Sometimes there is a distinct concentric arrangement. Gelatin.—In gelatin puncture cultures a delicate white line occurs along the entire path of the wire. Upon the surface the development is much more marked, so that the growth resembles a nail with a good-sized flat head. If the bacilli be planted upon the surface of obliquely solidified gelatin, a much more pronounced growth takes place, and along the line of inoculation a dry, granular coating is formed. There is no liquefaction of the medium. Bouillon.—The growth in bouillon is accompanied by a slight cloudiness. Agar.—This growth, like that upon agar-agar and blood-serum, is white, shining, rather luxuriant, and devoid of characteristics. Potato.—Upon potato no growth occurs except at 37°C. It is a very insig- nificant, yellowish-gray, translucent film. Milkis acidulated and slowly coagulated. Vital Resistance.—The bacillus readily succumbs to the action of heat. and dryness. The organism is an obligatory aérobe. Metabolic Products.—Indol and phenol are formed. Acids are produced in sugar-containing media, without gas formation. - Pathogenesis.—The introduction of cultures of this bacillus into chickens, geese, pigeons, sparrows, mice, and rabbits is sufficient to produce fatal septice- mia. Feeding ghickens, pigeons, and rabbits with material infected with the bacillus is also sufficient to produce the disease. Guinea-pigs, cats, and dogs seem immune, though they may succumb to large doses if given intraperitoneally. The organism is probably harmless to man. Fowls ill with the disease fall into a condition of weakness and apathy, which Causes them to remain quiet, seemingly almost paralyzed, and the feathers ruffled up. The eyes are closed shortly after the illness begins, and the birds gradually fall into a stupor, from which they do not awaken. The disease is fatal in from twenty-four to forty-eight hours. During its course there is profuse diarrhea, with very frequent fluid, slimy, grayish-white discharges. * “ Archiv. £. wissenschaftliche und praktische Thierheilkunde,” 1879. { “‘Compte-rendu de l’Acad. de Sci. de Paris,” vol. xc. t Thoinot and Masselin assert that the organism is motile. ‘“Précis de Mi- crobie,” 2d ed., 1893. Chicken-Cholera 565 Lesions.—The autopsy shows that when the bacilli are introduced subcuta- neously a true septicemia results, with the formation of a hemorrhagic exudate and gelatinous infiltration at the seat of inoculation. The liver and spleen are enlarged; circumscribed, hemorrhagic, and infiltrated areas occur in the lungs; the intestines show an intense inflammation with red and swollen mucosa, and occasional ulcers following small hemorrhages. Pericarditis is frequent. The bacilli are found in all the organs. If, on the other hand, the disease has been produced by feeding, the bacilli are chiefly to be found in the intestine. Pasteur found that when pigeons were inoculated, into the pectoral muscles, if death did not come on rapidly, portions of the muscle (sequesira) underwent degeneration and appeared anemic, indurated, and of a yellowish color. Immunity.—Pasteur* discovered that when cultures are allowed to remain undisturbed for several months, their virulence becomes greatly lessened, and new cultures transplanted from them are also attenuated. If chickens be inocu- lated with such attenuated cultures, no other change occurs than a local inflam- Fig. 234.—Bacillus of chicken-cholera, from the heart’s blood of a pigeon. X 1000 (Frankel and Pfeiffer). matory reaction that soon disappears and leaves the birds protected against future infection with virulent bacilli. From these observations Pasteur worked out a system of protective vaccination in which the fowls are first inoculated with attenuated, then with more active, and finally with virulent, cultures, with re- sulting protection and immunity. Use has been made of this bacillus to kill rabbits in Australia, where they are pests. It is estimated that two gallons of bouillon culture will destroy 20,000 rabbits, irrespective of infection by contagion. The bacillus of chicken-cholera may be identical with organisms found in various epidemic diseases of larger animals, and, indeed, no little confusion has arisen from the description of what is now pretty generally accepted to be the same organism as the bacillus of rabbit septicemia (Koch), Bacillus cuniculicida * An interesting account of Pasteur’s experiments upon chicken-cholera can be found in the “Life of Pasteur,” by Vallery-Radot, translated by Mrs. R. s. Devonshire, 1909. Popular Edition, New York, Doubleday, Page and Co. 566 Micro-organisms of the Plague Group (Fliigge), bacillus of ‘“Wildseuche” (Htippe), bacillus of “‘ Biiffelseuche” (Oriste- Armanni), etc. Bacitius SursEpticus (LOFFLER AND ScHitTz) General Characteristics——A non-motile, non-flagellated, non-sporogenous, non-liquefying, non-chromogenic, aérobic and optionally anaérobic bacillus, pathogenic for hogs and many other animals, staining by the ordinary methods, but not by Gram’s method. It produces a slight acidity in milk, but does not coagulate it. The bacillus of swine-plague, or Bacillus suisepticus of Léffler and Schiitz* and Salmon and Smith,{ but slightly resembles the bacillus of hog-cholera (q.v.), though it was formerly confounded with it and at one time thought to be iden- tical with it. The species have sufficient well-marked characteristics, however, to make their differentiation easy. Swine-plague is a rather common and exceedingly fatal epidemic disease. It not infrequently occurs in association with hog-cholera, and because of the lack of sufficiently well-characterized symptoms—sick hogs appearing more or less alike—is often mistaken for it. The confusion resulting from such faulty diagnosis makes it difficult to determine exactly how fatal either may be in uncomplicated cases. : Morphology.—The bacillus of swine-plague much resembles that of chicken- cholera. It is a short organism, rather more slender than the related species, not possessed of flagella, incapable of movement, and producing no spores. It is an optional anaérobe. Staining.—The bacillus stains by the ordinary methods, sometimes only at the poles, then closely resembling the bacillus of chicken-cholera. It is not colored by Gram’s method. Cultivation.—In general, the appearance in culture-media is very similar to that of the hog-cholera bacillus. Kruse,t however, points out that when the bacillus grows in bouillon the liquid remains clear, the bacteria gathering to form a flocculent, stringy sediment. The organism does not grow upon ordi- nary acid potato, but if the reaction of the medium be alkaline, a grayish-yellow patch is formed. In milk a slight acidity is produced, but the milk is not coagulated. Vital Resistance.—The vitality of the organism is low, anditis easily destroyed. Salmon says that it soon dies in water or when dried, and that the temperature for its growth must be more constant and every condition of life more favorable than for the hog-cholera bacillus. The organism is said to be widely distributed in nature, and is probably present in every herd of swine, though not pathogenic except when its virulence becomes increased or the vital resistance of the animals © diminished by some unusual condition. Rabbits, mice, and small birds are very susceptible to the infection, usually dying of septicemia in twenty-four hours; guinea-pigs are less susceptible, except very young animals, which die without exception. Chickens are more immune, but usually succumb to large doses. Hogs die of septicemia after subcutaneous injection of the bacilli. There is a marked edema at the point of injection. If injected into the lung, a pleuropneumonia follows, with multiple necrotic areas in the lung. In these cases the spleen is not much swollen, there is slight gastro- intestinal catarrh, and the bacilli are present everywhere in the blood. Animals can be infected only by subcutaneous, intravenous, and intraperi- toneal inoculation, not by feeding. As seen in hogs, the symptoms of swine-plague closely resemble those of hog- cholera, but differ in the occurrence of cough, swine-plague being prone to affect the lungs and oppress the breathing, which becomes frequent, labored, and pain- ful, while hog-cholera is chiefly characterized by intestinal symptoms. The course of the disease is usually rapid, and it may be fatal in a day or two. Lesions.—At autopsy the lungs are found to be inflamed, and to contain numerous small, pale, necrotic areas, and sometimes large cheesy masses I OF * “ Arbeiten aus dem kaiserlichen Gesundheitsamte,” 1. t ‘Zeitschrift f. Hygiene,” x. t Fliigge’s “Die Mikrodrganismen, 1896,” p. 410. Swine-plague 567 2 inches in diameter. Inflammations of the serous membranes affecting the pleura, pericardium, and peritoneum, and associated with fibrinous inflammatory . deposits on the surfaces, are common, There may be congestion of the mucous membrane of the intestines, particularly of the large intestine, or the disease in this region may be an intense croupous inflammation with the formation of a fibrinous exudative deposit on the surface. A hemorrhagic form of the disease is said to be common in Europe, but, according to Salmon, is rare in the United States. CHAPTER XXVI ASIATIC CHOLERA SPrRILLUM CHOLER& AsraTIc&@ (Kocu*) General Characteristics.—A motile, flagellated, non-sporogenous, liquefying, non-chromogenic, non-aérogenic, parasitic and saprophytic, pathogenic, aérobic and optionally anaérobic spirillum, staining by ordinary methods, but not by Gram’s method. Cholera is a disease endemic in certain parts of India and prob- ably indigenous in that country. Though early mention of it was made in the letters of travelers, and though it appeared in medical literature and in governmental statistics more than a century ago, we find that little attention was paid to the disease, except in its disastrous effect upon the armies, native and European, of India and adjacent countries. The opening up of India by Great Britain in the last century has made scientific observation of the disease possible and has permitted us to determine the relation its epidemics bear to the manners and customs of the people. The filthy habits of the Oriental people, their poverty, crowded condition, and peculiar religious customs, are all found to aid in the distribution of the disease. Thus, the city of Benares drains into the Ganges River by a most imperfect system, which distributes the greater part of the sewage immediately below the banks upon which the city is built and along which are the numerous “ Ghats”’ or staircases by which the people reach the sacred waters. It is a matter of religious observance for every zealot who makes a pilgrimage to the “sacred city” to take a bath in and drink a quantity of this sacred but polluted water, and it may be imagined that the number of pious Hindoos who leave Benares with “comma bacilli” in their intestines or upon their clothes must be great, for there are few months in the year when the city is exempt from the disease. The pilgrimages and great festivals of both Hindoos and Moslems, by bringing together enormous numbers of people to crowd in close quarters where filth and bad diet prevail, cause a rapid increase in the number of cases during these periods and facilitate the distribu- tion of the disease when the festivals break up. Probably no more favorable conditions for the dissemination of a disease can beimagined than occurs with the return of the Moslem pilgrims from Mecca. The disease extends readily along the regular lines of travel, visiting town. after town, until from Asia it has frequently extended into *“T)eutsche med. Wochenschrift,” 1884-1885, Nos. 19, 20, 37, 38, and 39. 568 Distribution 569 Europe, and by steamships plying foreign waters has several times been carried to our own continent. Many cases are on record which show conclusively how a single ship, having a few cholera cases on board, may be the starting-point of an outbreak of the disease in the port at which it arrives. The most recent great epidemic of cholera began in 1883. From Asia it spread westward throughout Europe, extended by means of the steamship lines to numerous of the large ports, of which Ham- burg in Germany suffered most acutely, and even extended to some of the ports of Africa and America. Russia probably suffered more than any other European country, and it is estimated that in that country there were no less than 800,000 deaths. During 1o11 the disease again appeared in Europe and invaded the countries along the Mediterranean coasts. Fig. 235.—Cholera spirilla. Specific Organism.—The discovery of the spirillum of cholera was made by Koch while serving as a member of a German com- mission appointed to study the diseascin Egyptand India in 1883-84. Since its discovery the spirillum has been subjected to much careful investigation, and an immense amount of literature, a large part of which was stimulated by the Hamburg epidemic of 1892, has accumulated. Distribution.—The cholera spirilla can be found with great regularity in the intestinal evacuations of cholera cases, and can often be found in drinking-water and milk, and upon vegetables, etc., in cholera-infected districts. There can be little doubt that they find their way into the body with the food and drink. Cases in the literature show how cholera germs enter drinking-water and are thus distributed; how they are sometimes thoughtlessly sprinkled over green vegetables offered for sale in the streets, with infected 570 Asiatic Cholera water from polluted gutters; how they enter milk with water used to dilute it; how they appear to be carried about in clothing and upon food-stuffs; how they can be brought to articles of food by flies that have preyed upon cholera excrement; and other interesting modes of infection. The literature is so vast that it is scarcely possible to mention even the most instructive examples. A bacteri- ologist became infected while experimenting with the cholera spirilla in Koch’s- laboratory. It is commonly supposed that the cholera organism may remain alive in water for an almost unlimited length of time, but experiments have not shown this to be the case. Thus, Wolffhiigel and Riedel have shown that if the spirilla be planted in sterilized water they grow with great rapidity after a short time, Fig. 236.—Spirillum of Asiatic cholera, from a bouillon culture three weeks old, showing long spirals. > 1000 (Frankel and Pfeiffer). and can be found alive after months have passed. Frankel, how- ever, points out that this ability to grow and remain vital for long periods in sterilized water does not guarantee the sdme power of growth in unsterilized water, for in the latter the simultaneous growth of other bacteria serves to extinguish the cholera spirilla in a few days. Morphology.—The micro-organism described by Koch, and now generally accepted to be the cause of cholera, is a short rod 1 to 2 w in length and o.5 w in breadth, with rounded ends, and a distinct curve, so that the original name by which it was known, the “comma bacillus,” applies very well. One of the most common forms is that in which two short curved individuals are conjoined in an S-shape. When the conditions of nutrition are good, multiplication by fission progresses with rapidity; but when adverse conditions arise, long Staining 571 spiral threads—unmistakable spirilla—develop. Frankel found that the exposure of the cultures to unusually high temperatures, the addition of small amounts of alcohol to the culture-media, and other unfavorable conditions lead to the production of spirals instead of “commas.” The cholera spirilla are actively motile, and in hanging-drop preparations can be seen to swim about with great rapidity. Both comma-shaped and spiral organisms move with a rapid rotary motion. The presence of a single flagellum attached to one end can be demonstrated without difficulty. AN & VDSS oO weN x SOs NOS swe ae ws = 2 ais = AK ‘ ~ . ~ - Rs = ~e a S . oe ‘ . Sine BS ee x ~~ at ~ ~ = > soe 2 5 we oo a sq ~ x i i a ~ x x . s - ~ = e ZO ae 4 *. + = - x Fig. 237.—-Cover-glass preparation of a mucous floccule in Asiatic cholera. X 650 (Vierordt). Involution-forms of bizarre appearance are common in old and sometimes in fresh cultures. Many individuals show by granular cytoplasm and irregular outline that they are degenerated. Cholera spirilla from various sources differ in the extent of involution. In partially degenerated cultures containing long spirals, Hiippe observed, by examination in the “hanging-drop,” certain large spheric bodies which he described as spores (arthrospores). Koch and, indeed, all other observers fail to find spores in the cholera organism, and the nature of the bodies described by Hiippe must be regarded as doubtful. Staining.—The cholera spirillum stains well with the ordinary aqueous solutions of the anilin dyes, especially fuchsin. At times the staining must be continued for from five to ten minutes to se- cure homogeneity. The organism does not stain by Gram’s method. It may be colored and examined while alive; thus, Cornil and 572 Asiatic Cholera Babes, in demonstrating it in the rice-water discharges, “spread out one of the white mucous fragments upon a glass slide and allow it to dry partially; a small quantity of an exceedingly weak solu- tion of methy] violet in distilled water is then applied to it, and it is flattened out by pressing down a cover-glass, over which is placed a fragment of filter-paper, which absorbs any excess of fluid at the margin of the cover-glass. The characteristics of comma bacilli so prepared and examined with an oil-immersion lens ( X 700-800) are readily made out because, though they take up enough stain to color them, they still retain the power of vigorous movement, which would be entirely lost if the specimen were dried, stained, and mounted in the ordinary fashion.”’ Fig. 238.—Spirillum of Asiatic cholera; colonies two days old upon a gelatin plate. X 35 (Heim). Isolation of the Organism.—One of the best methods of securing a pure culture of the cholera spirillum, and also of making a bacterio- logic diagnosis of the disease in a suspected case, is probably that of Schottelius. A small quantity of the fecal matter is mixed with bouiilon and stood in an incubating oven for twenty-four hours. If the cholera spirilla are present they will grow most rapidly at the surface of the liquid where the supply of air is good. A pellicle will be formed, a drop from which, diluted in melted gelatin and poured upon plates, will show typical colonies. Cultivation.—The cholera organism is easily cultivated, and grows luxuriantly upon the usual laboratory media. Colonies.—The colonies grown upon gelatin plates are character-' istic and appear in the lower strata of the gelatin as small white Cultivation 573 dots, which gradually grow out to the surface, effect a slow lique- faction of the medium, and then appear to be situated in little pits with sloping sides. The appearance suggests that the plate is full of little holes or air-bubbles, and is due to the slow evaporation of the liquefied gelatin. Under the microscope the colony of the cholera spirillum is fairly well characterized. The little colonies that have not yet reached the surface of the gelatin soon show a pale yellow colorand an irregular contour. They are coarsely granular, the largest granules being in the center. As the colony increases in size the granules do the same and attain a peculiar transparent appearance suggestive of powdered glass. The slow liquefaction causes the Fig. 239.—Spirillum cholere asiatice; gelatin puncture cultures aged forty- eight and sixty hours (Shakespeare). colony to be surrounded by a transparent halo. As the liquefied gelatin evaporates, the colony begins to sink, and also to take on a peculiar rosy color. Gelatin.—In puncture cultures in gelatin the growth is also quite characteristic. It occurs along the entire puncture, but best at the surface, where it is in contact with the atmosphere. Lique- faction of the medium begins almost at once, keeps pace with the growth, but is always more marked at the surface than lower down. The result is the formation of a short, rather wide funnel at the top of the puncture. As the growth continues, evapora- tion of the medium takes place slowly, so that the liquefied gelatin is lower than the surrounding solid portions, and the growth ap- pears to be surmounted by an air-bubble. 574 Asiatic Cholera The luxuriant development of the spirilla in the liquefying gelatin is followed by the formation of considerable sediment in the lower third or half of the liquefied area. This solid material consists of masses of spirilla which have probably completed their life-cycle and become inactive. Under the microscope they exhibit the most varied involution-forms. The liquefaction reaches the sides of the tube in from five to seven days, but is not complete for several weeks. Agar-agar.—When planted upon the surface of agar-agar the spirilla produce a grayish-white, shining, translucent growth along the entire line of inoculation. It is in no way peculiar or char- acteristic. The vitality of the organism is retained much better upon agar-agar than upon gelatin, and, according to Frankel, the organism can be transplanted and grown when nine months old. Blood-serum.—The growth upon blood-serum is also without | distinct peculiarities; gradual liquefaction of the medium occurs. Potato.—Upon potato the spirilla grow well, even when the reaction is acid. In the incubator, at a temperature of 37°C., a transparent, slightly brownish or yellowish-brown growth, some- what resembling that of glanders, is produced. It contains large numbers of long spirals. Bouillon.—In bouillon and in peptone solution the cholera organ- isms grow well, especially upon the surface, where a folded, wrinkled pellicle is formed, the culture fluid remaining clear. Milk.—In milk the growth is luxuriant, but does not visibly alter its appearance. The existence of cholera organisms in milk is, however, rather short-lived, for the occurrence of acidity destroys them. Vital Resistance.—Although an organism that multiplies with great rapidity under proper conditions, the cholera spirillum does not possess much resisting power. Sternberg found that it was killed by exposure of 52°C. for four minutes, but Kitasato found that ten or fifteen minutes’ exposure to 55°C. was not always fatal to it. In a moist condition the organism may retain its vitality for months, but it is very quickly destroyed by desiccation, as was found by Koch, who observed that when dried in a thin film its power to grow disappeared in a few hours. Kitasato found that upon silk threads the vitality might be retained longer. Abel and Claussen* have shown that it does not live longer than twenty or thirty days in fecal matter, and often disappears in from one to three days. The organism is very susceptible to the influence of carbolic acid, bichlorid of mercury, and other germicides, and is also destroyed by acids. Hashimoto} found that it could not live longer than fifteen minutes in vinegar containing 2.2-3.2 per cent. of acetic acid. *“Centralbl. f. Bakt. u. Parasitenk.,” Jan. 31, 1895, vol. xvu1, No. 4. ° t “Kwai Med. Jour.,” Tokyo, 1893. cc Pathogenesis 595 According to Frankel, the organisms in the liquefied cultures all die in eight weeks, and cannot be transplanted. Kitasato, how- ever, has found them living and active on agar-agar after from ten to thirty days, and Koch occasionally found some alive after two years. This low vital resistance of the microbe is very fortunate, for it enables us to establish satisfactory quarantine for the prevention of the spread of the disease. Excreta, soiled clothing, etc., are readily rendered harmless by the proper use of disinfectants. Water and food are rendered innocuous by boiling or cooking. Vessels may be disinfected by thorough washing with jets of boiling water discharged through a hose connected with a boiler, and baggage can be sterilized by superheated steam. Metabolic Products.—Indol is one of the characteristic metabolic _ products of the cholera spirillum. As the cholera organisms also produce nitrites, all that is necessary to demonstrate its presence in a colorless solution is to add a drop or two of chemically pure sul- phuric acid, when the well-known reddish color will appear. The organism also produces acid in milk and other media. Bitter has also shown that the cholera organism produces a peptonizing and probably also a diastatic ferment. Toxic Products.—Rietsch thinks the intestinal changes depend upon the action of the peptonizing ferment. Cantani, Nicati and Rietsch, Van Ermengem, Klebs, and others found toxic effects from cultures administered to dogs and other animals. Several toxic metabolic products of the spirilla have been isolated. Brieger,* Brieger and Frinkel,t Gamaléia,t Sobernheim,§ and Villiers have studied more or less similar toxic products. The real toxic sub- stance is, however, not known. Pathogenesis.—Through what activity the cholera organism provokes its pathogenic action is not yet determined. The organ- isms, however, abound in the intestinal contents, penetrate spar- ingly into the tissues, but slightly invade the lymphatics, and almost never enter the circulation; hence it is but natural to conclude that the first action must be an irritative one depending upon toxin- formation in the intestine. In the beginning of the disease the small and large intestines are deeply congested, almost velvety in appearance, and contain liquid fecal matter. The patient suffers from diarrhea, by which the feces are hurried on and become extremely thin from the ad- mixture of a copious watery exudate. As the feces are hurried out, more and more of the aqueous exudate accumulates, until the intes- tine seems to contain only watery fluid. The solitary glands and Peyer’s patches are found enlarged and the mucosa becomes macer- * “Berliner klin. Wochenschrift,” 1887, p. 817. t “Untersuchungen iiber die Bakteriengifte,” etc., Berlin, 1890. + “Archiv de méd. exp.,” Iv, No. 2. § “Zeitschrift fiir Hygiene,” 1893, XIV, 145. 576 Asiatic Cholera ated and necrotic, its epithelium separating in small shreds or flakes. The evacuations of watery exudate rich in these shreds con- stitute the characteristic ‘‘rice-water discharges” of the disease. As the disease progresses, the denudation of tissue results in the formation of good-sized ulcerations. Perforations and deep ulcer- ations are rare. Pseudo-membranous formations not infrequently occur upon the abraded and ulcerated surfaces. The other mucous membranes of the alimentary apparatus become congested and abraded; the parenchyma of the liver, kidneys, and other organs become markedly degenerated, so that the urine becomes highly albuminous and very scanty in consequence of the anhydremia. The cardio-vascular, nervous, and respiratory systems present no characteristic changes. So far as is known, cholera is a disease of human beings only, and never occurs spontaneously in the lower animals. Intraperitoneal injection of the virulent cultures produces fatal peritonitis in guinea-pigs. Supposing that the lower animals were immune against cholera because of the acidity of the gastric juice, Nicati and Rietsch,* Van Ermengem, and Kochf have suggested methods by which the micro-organisms can be introduced directly into the intestine. The first-named investigatorsligated the common bile-duct of guinea- pigs, and then injected the spirilla into the duodenum with a hypo- dermic needle, with the result that the animals usually died, some- times with choleraic symptoms. The excessively grave nature of the operation upon such a small and delicately constituted animal as a guinea-pig, however, greatly lessens the value of the experiment. Koch’s method of infection by the mouth is much more satisfactory. By injecting laudanum into the abdominal cavity of guinea-pigs the peristaltic movements of the intestine can be checked. The amount necessary for the purpose is large and amounts to about i gram for each 200 grams of body-weight. It completely nar- cotizes the animals for a short time (one to two hours), but they re- cover without injury. The contents of the stomach are neutralized after administering the opium, by introducing 5 cc. of a § per cent. aqueous solution of sodium carbonate through a pharyngeal catheter. With the gastric contents thus alkalinized and the peris- talsis paralyzed, a bouillon culture of the cholera spirillum is intro- duced through the stomach-tube. The animal recovers fromthe manipulation, but shows an indisposition to eat, is soon observed to be weak in the posterior extremities, subsequently is paralyzed, and dies within forty-eight hours. The autopsy shows the intestine congested and filled with a watery fluid rich in spirilla—an appear- ance which Frankel declares to be exactly that of cholera. In man, as well as in these artificially infected animals, the spirilla are * “Deutsch. med. Wochenschrift,” 1884. T Ibid., 1885. Detection of the Organism 577 never found in the blood or tissues, but only in the intestine, where they frequently enter between the basement membrane and the epithelial cells, and aid in the detachment of the latter. Issaéff and Kolle found that when virulent cholera spirilla are injected into the ear-veins of young rabbits the animals die on the following day with symptoms resembling the algid state of human cholera. The autopsy in these cases showed local lesions of the small intestine very similar to those observed in cholera in man. Guinea-pigs are susceptible to intraperitoneal injections of the spirillum, and speedily succumb. The symptoms are rapid fall of temperature, tenderness over the abdomen, and collapse. The autopsy shows an abundant fluid exudate containing the micro- organisms, and injection and redness of the peritoneum and viscera. Specificity—The cholera spirillum is present in the dejecta of cholera with great regularity, and as regularly absent from the dejecta of healthy individuals and those suffering from other dis- eases. No satisfactory proof of the specific nature of the organ- isms can be obtained by experimentation upon animals. Ani- mals are never affected by any disease similar to cholera during epidemics, nor do foods mixed with cholera discharges or with pure cultures of the cholera spirillum affect them. Subcutaneous in- oculations do not produce cholera. Detection of the Organism.—It often becomes a matter of im- portance to detect the cholera spirilla in drinking-water, and, as the number in which the bacteria exist in such a liquid may be very small, difficulty may be experienced in finding them by ordi- nary methods. One of the most expeditious methods is that recommended by Léffler, who adds 200 cc. of the water to be examined to 10 cc. of bouillon, allows the mixture to stand in an incubator for from twelve to twenty-four hours, and then makes plate cultures from the superficial layer of the liquid, where, if present, the development of the spirilla will be most rapid because of the free access of air. Gordon* employs a medium composed of lemco 1 gram, peptone I gram, sodium bicarbonate o.1 gram, starch 1 gram, and distilled water 100 cc. for the differentiation of the cholera and Finkler- Prior spirilla. If the medium be tinted with litmus and the cultures grown at 37°C., a strongly acid change is produced by the true cholera organism in twenty-four hours. The Finkler-Prior spirillum- ade but slight acidity, which first appears about the third ay. The identification of the cholera spirillum, and its differen- tiation from spiral organisms of similar morphology obtained from feces or water in which no cholera organisms are expected, is becoming less and less easy as our knowledge of the organisms increases. The following points may be taken into consideration: * “British Medical Journal,” July 28, 1906. 37 : 578 ' Asiatic Cholera (x) The typical morphology. The true cholera organism is short, has a single curve, is rounded at the ends, and possesses a single flagellum. (2) The infectivity. Freshly isolated cultures should be pathogenic for guinea-pigs and harmless to pigeons. (3) Vegeta- tive: The organism should liquefy 1o per cent. gelatin and should not coagulate milk. (4) Metabolic: the indol reaction should be marked. (5) Immunity reactions: the organism when injected into guinea-pigs in ascending doses should occasion immunity against the typical cholera organism, and the serum of the immunized guinea-pig, when introduced into a new guinea-pig, should protect it from infection and produce Pfeiffer’s phenomenon. The blood- serum of animals immunized against the cholera organism should agglutinate the doubtful organism in approximately the same dilution, and that of animals immunized to the doubtful organism should agglutinate the cholera organism reciprocally. Both organ- isms should have equal capacity for absorbing complements and amboceptors from blood-serum. (6) The true cholera organism should not be hemolytic. Too much reliance must not be placed upon the agglutination tests alone, as will be made clear by a perusal of the paper upon Bacteriological Diagnosis of Cholera by Ruffer.* Pfeiffer and Vogedest have applied the ‘immunity reaction’ to the identification of cholera spirilla in cultures. A hanging drop of a 1 :50 mixture of a powerful anticholera serumanda particle of cholera culture is made and examined under the microscope. The cholera spirilla at once become inactive, and are in a short time converted into little rolled-up masses. If the culture added be a spirillum other than the true cholera spirillum, instead of being destroyed the micro-organisms multiply and ‘thrive in the mixture of serum and bouillon. Immunity.—One attack of cholera usually leaves the victim immune from further attacks of the disease. Gruber and Wiener,t{ Haffkine,§ Pawlowsky,|| and Pfeiffer** have immunized animals against toxic substances from cholera cultures and against living cultures. Sobernheim{f{ found the Pfeiffer reaction specific against cholera alone, and thought the protection not due to the strongly bactericidal property of the serum, but to its stimulating effect upon the body- cells; for if theserum be heated to 60°-70°C., and its bactericidal power thus destroyed, it is still capable of producing immunity. This, of course, is in keeping with our present knowledge of the immune body, which is not destroyed by such temperatures. * “British Medical Journal,’ March 30, 1907, 1, p. 735. + “Centralbl. f. Bakt. u. Parasitenk.,” March 21, 1896, Bd. xrx, No. 11. t “Centralbl. f. Bakt.,” 1892, XIV, p. 76. § “Le Bull. méd.,” 1892, p. 1113, and “Brit. Med. Jour.,”’ 1893, p. 278. || “Deutsche med. Wochenschrift,”’ 1893, No. 22. : ** “Zeitschrift fiir Hygiene,” Bd. xvii and xx. Tt “Zeitschrift fiir Hygiene, xx, p. 438. Serum Therapy and Prophylaxis 579 The immunity produced by the injection of the spirilla into guinea-pigs continues in some cases as long as four and a half months, but the power of the serum to confer immunity is lost much sooner. Serum Therapy and Prophylaxis.—Of the numerous attempts to produce immunity against cholera in man, or to cure cholera when once established in the human organism, nothing very favorable can be said. Experiments in this field are not new. As early as 1885 Ferran, in Spain, administered hypodermic injections of pure virulent cultures of the cholera spirillum, in the hope of bringing about immunity. The work of Haffkine,* however, is the chief important contribution, and his method seems to be followed by a positive diminution of mortality in protected individuals. Haffkine uses two vaccines—one mild, the other so virulent that it would bring about extensive tissue-necrosis and perhaps death if used alone. His studies embrace more than 40,000 inoculations per- formed in India. The following extract will show results obtained in 1895: “, In all those instances where cholera has made a large number of victims— that is to say, where it has spread sufficiently to make it probable that the whole population, inoculated and uninoculated, were equally exposed to the infection— in all these places the results appeared favorable to inoculation. “9, The treatment applied after an epidemic actually breaks out tends to reduce the mortality even during the time which is claimed for producing the full effect of the operation. In the Goya Garl, where weak doses of a relatively weak vaccine had been applied, this reduction was to half the number of deaths; in the coolies of the Assam-Burmah survey party, where, as far as I can gather from my preliminary information; strong doses have been applied, the number of deaths was reduced to one-seventh. This fact would justify the application - of the method independently of the question as to the exact length of time during which the effect of this vaccination lasts. “3, In Lucknow, where the experiment was made on small doses of weak vaccines, a difference in cases and deaths was still noticeable in favor of the inoculated fourteen to fifteen months after vaccination in an epidemic of excep- tional virulence. This makes it probable that a protective effect could be eae even for long periods of time if larger doses of a stronger vaccine were used. “4. The best results seem to be obtained from application of middle doses of both anticholera vaccines, the second one being kept at the highest possible degree of virulence obtainable. _ “5. The most prolonged observations on the effect of middle doses were made in Calcutta, where the mortality from the eleventh up to the four hundred and fifty-ninth day after vaccination was, among the inoculated, 17.24 times smaller, and the number of cases 19.27 times smaller than among the not inoculated.” Pawlowsky and others have found the dog susceptible to cholera, and have utilized it in the preparation of an antitoxic serum. The dogs were first immunized against attenuated cultures, then against more and more virulent cultures, until a serum was ob- tained whose value was estimated at 1:130,000 upon experimental animals. Freymutht and others have endeavored to secure favorable *“Le Bull. méd.,” 1892, p. 1113; “Indian Med. Gazette,” 1893, p. 97; “Brit. Med. Jour.,” 1893, p. 278. T “Deutsche med. Wochenschrift,”’ 1893, No. 43. 580 The Finkler and Prior Spirillum results from the injection of blood-serum from convalescent patients into the diseased. One recovery out of three cases treated is recorded. In all these preliminaries the foreshadowing of a future thera- peusis must be evident, but as yet nothing satisfactory has been achieved. _ One of the chief errors made in the experimental preparation of anticholera serums is that efforts have been directed toward endow- ing the blood with the power of resisting and destroying the bacteria that rarely, if ever, reach it. The two essentials to be aimed at are an antitoxin to neutralize the depressing effects of the toxalbumin, and some means of destroying the bacteria in the intestine. Sanitation.—The first appearance of cholera may depend upon the introduction of the micro-organisms upon fomites, hence to avoid epidemics it is necessary to disinfect all such coming from cholera- infected localities. So soon as cholera asserts itself, the chief danger lies in the probable contamination of the water-supply. To prevent this the utmost effort must be made to locate all cases and see that the dejecta are thoroughly disinfected, and as the micro-organisms persist in the intestinal discharges for some weeks after convalescence, the patients should not too soon be discharged from the hospital, but should be retained until a bacteriologic examination shows no more comma bacilliin the feces. During an epidemic the water consumed should all be boiled, raw milk should be avoided, and no green or uncooked vegetables or fruitseaten. Foods should be carefully defended from flies, which may carry the organisms to them and infect them. The intestinal evacuations and all the clothing, bedding, and other articles used by the patients should be carefully disinfected. SPIRILLA RESEMBLING THE CHOLERA SPIRILLUM Tue FINKLER AND Prior SPIRILLUM (SprRILLUM PROTEUS) Similar in morphology to the spirillum of cholera, and in other respects closely related to it, is the spirillum obtained from the feces of a case of cholera nostras by Finkler and Prior.* Morphology.—It is shorter and stouter, with a more pronounced curve than the cholera spirillum, and rarely forms long spirals. The central portion is also somewhat thinner than the ends, which are a little pointed and give the organism aless uniform appearance. Involution forms are common in cultures, and appear as spheres, spindles, clubs, etc. Like the cholera spirillum, each organism is provided with a single flagellum situated at its end, and is actively motile. Staining.—The organism stains readily with the ordinary solutions, but not by Gram’s method. ; Cultivation.—Colonies.—The growth upon gelatin plates is rapid, and leads to such extensive liquefaction that four or five dilutions must frequently be made to secure few enough organisms to enable one to observe the growth of a single *“Centralbl. fiir allg. Gesundheitspflege,” Bonn, 1885, Bd. 1; “Deutsche med. Wochenschrift,” 1884, p. 632. Cultivation 581 colony. To the naked eye the deep colonies appear as small white points. They rapidly reach the surface, begin liquefaction of the gelatin, and by the second day appear about the size of lentils, and are situated in little depressions. Under the Fig. 240.—Spirillum of Finkler and Prior, from an agar-agar culture. XX 1000 (Itzerott and Niemann). microscope they are yellowish brown, finely granular, and are surrounded by a zone of sharply circumscribed liquefied gelatin. Careful examination with a high-power lens shows rapid movement of the granules in the colony. Fig. 241.—Spirillum of Finkler and Prior; colony twenty-four hours old, upon a gelatin plate. X 100 (Frankel and Pfeiffer). Gelatin Punctures.—In gelatin punctures the growth takes place rapidly along the whole length of the puncture, forming a stocking-shaped liquefaction filled with cloudy fluid which does not precipitate rapidly; a rather smeary, whitish 582 The Finkler and Prior Spirillum scum is usually formed upon the surface. The more extensive and more rapid liquefaction of the medium, the wider top to the funnel, the absence of the air- bubble, and the clouded nature of the liquefied material, all serve to differ- entiate the culture from the cholera spirillum. Agar-agar.—Upon agar-agar the growth is also rapid, and in a short time the whole surface of the culture medium is covered with a moist, thick, slimy coating, which may have a slightly yellowish tinge. Bouillon.—In bouillon the organism causes a diffuse turbidity with a more or less distinct pellicle on the surface. In sugar-containing culture-media it causes no fermentation and generates no gas. Potato.—The cultures upon potato are also different from those of the cholera organism, for the Finkler and Prior spirilla grow rapidly at the room tempera- ture, and produce a grayish-yellow, slimy shining layer, which may cover the whole of the culture-medium. : Blood-serum.—Blood-serum is rapidly liquefied by the organism. Milk.—The spirillum does not grow well in milk, and speedily dies in water. Fig. 242.—Spirillum of Finkler and Prior; gelatin puncture cultures aged forty- eight and sixty hours (Shakespeare). Metabolic Products——The organism does not produce indol. Buchner has shown that in media containing some glucose an acid reaction is produced. Pro- pele enzymes capable of dissolving gelatin, blood-serum, and casein are ormed. Pathogenesis.—It was at first supposed that if not the spirillum of cholera itself, this was a very closely allied organism. Later it was supposed to be the cause of cholera nostras. At present it is a question whether the organism has any pathologic significance. It was in one case secured by Knisl from the feces of a suicide, and has been found in carious teeth by Miiller. When injected into the stomach of guinea-pigs treated with tincture of opium according to the method of Koch, about 30 per cent. of the animals die, but the intestinal lesions produced are not identical with those produced by the cholera spirillum. The intestines in such cases are pale and filled with watery material having a strong putrefactive odor. This fluid teems with the spirilla. It seems unlikely, from the evidence thus far collected, that the Finkler and Prior spirillum is pathogenic for the human species. As Frankel points out, it is probably a frequent and harmless inhabitant of the human intestine. Morphology 583 Tue SPIRILLUM OF DENECKE (SPIRILLUM TYROGENUM) Another organism with a partial resemblance to the cholera spirillum was found by Denecke* in old cheese. Fig. 243.—Spirillum of Denecke, from an agar-agar culture. XX 1000 (Itzerott and Niemann). Morphology.—Its form is similar to that of the cholera spirillum, the shorter individuals being of equal diameter throughout. The spiral forms are longer Fig. 244.—Spirillum of Denecke; gelatin puncture cultures aged forty-eight and sixty hours (Shakespeare). than those of the Finkler and Prior spirillum, and are more tightly coiled than those of the cholera spirillum. * “Deutsche med. Wochenschrift,” 1885. 584 Spirillum of Gamaléia Like its related species, this micro-organism is actively motile and possesses a terminal flagellum. Cultivation.—It grows at the room temperature, as well as at 37°C., in this respect, as in its reaction to stains, much resembling the other two. Colonies.—Upon gelatin plates the growth of the colonies is much more rapid than that of the cholera spirillum, though slower than that of the Finkler and Prior spirillum. The colonies appear as small whitish, round points, which soon reach the surface of the gelatin and commence liquefaction. By the second _ day each is about the size of a pin’s head, has a yellow color, and occupies the bot- tom of a conical depression. The appearance is much like that of colonies of the cholera spirillum. The microscope shows the colonies to be of irregular shape and coarsely granu- lar, pale yellow at the edges, gradually becoming intense toward the center, and at first circumscribed, but later surrounded by clear zones, resulting from the liquefaction of the gelatin. These, according to the illumination, appear pale or dark. The colonies differ from those of cholera in the prompt liquefaction of the gelatin, the rapid growth, yellow color, irregular form, and distinct line of circumscription. . Gelatin Punctures.—In gelatin punctures the growth takes place all along the track of the wire, and forms a cloudy liquid which precipitates at the apex in the form of a coiled mass. Upon the surface a delicate, imperfect, yellowish scum forms. Liquefaction of the entire gelatin generally requires about two weeks. Agar-agar.—Upon agar-agar this spirillum forms a thin yellowish layer which. spreads quickly over most of the surface. Bouillon.—In bouillon the growth of the organism is characterized by a diffuse turbidity. No gas-formation occurs in sugar-containing media. Potatoes.—The culture upon potato is luxuriant if grown in the incubating - oven. It appears as a distinct yellowish, moist film, and when examined micro- scopically is seen to contain beautiful long spirals. Metabolic Products.—The organism produces no indol. : Pathogenesis.—The spirillum of Denecke is mentioned only because of its. morphologic resemblance to the cholera spirillum. It is not associated with any ~ human disease. Experiments, however, have shown that when the spirilla are introduced into guinea-pigs whose gastric contents are alkalinized and whose peristalsis is paralyzed with opium, about 20 per cent. of the animals die. THE SPIRILLUM OF GAMALEIA* (SPIRILLUM METCHNIKOVI) Resembling the cholera spirillum in morphology and vegetation, and possibly, as has been suggested, a descendant of the same original stock, is a spirillum which Gamaléia cultivated from the intestines of chickens affected with a disease: similar to chicken-cholera. Morphology.—This spirillum is a’ trifle shorter and thicker than the cholera spirillum. It is a little more curved, and has similar rounded ends. It forms long spirals in appropriate media, and is actively motile. Each spirillum is provided with a terminal flagellum. No spores have been demonstrated. Staining.—The organism stains easily, the ends more deeply than the center. It is not stained by Gram’s method. Cultivation —It grows well both at the temperature of the room and at that of incubation. Colonies.—The colonies upon gelatin plates have a marked resemblance to those of the cholera spirillum, yet there is a difference; and as Pfeiffer says, ‘‘it is comparatively easy to differentiate between a plate of pure cholera spirillum and a plate of pure Spirillum metchnikovi, yet it is almost impossible to pick out a few colonies of the latter if mixed upon a plate with the former.” Frankel regards this organism as a species intermediate between the cholera and the Finkler-Prior spirillum. The colonies upon gelatin plates appear in about twelve hours as small whitish points, and rapidly develop, so that by theend of the third day large saucer-shaped. liquefactions resembling colonies ofthe Finkler-Prior spirillum occur. Thelique- faction of the gelatin is quite rapid, the resulting fluid being turbid. Usually, upon a plate of Vibrio metchnikovi some colonies are present which closely * “Ann. de l’Inst. Pasteur,” 1888. Pathogenesis 585 resemble those of the cholera spirillum, being deeply situated in conical depres- sions in the gelatin. Under the microscope the contents of the colonies, which appear of a brownish color, are observed to be in rapid motion. The edges of the bacterial mass are fringed with radiating organisms. Gelatin Punctures.—In gelatin tubes the growth closely resembles that of the cholera organism, but develops more slowly. , Agar-agar.—Upon the surface of agar-agar a yellowish-brown growth develops along the whole line of inoculation. ; Potato.—On potato at the room temperature no growth occurs, but at the temperature of the incubator a luxuriant yellowish-brown growth takes place. Sometimes the color is quite dark, and chocolate-colored potato cultures are not uncommon. _Bouillon.—In bouillon the growth which occurs at the temperature of the incu- bator is quite characteristic, and very different from that of the cholera spirillum. The entire medium becomes clouded, of a grayish-white color, and opaque. A folded and wrinkled pellicle forms upon the surface. Milk.— When grown in litmus milk, the original blue color is changed to pink in a day, and at the end of another day the coloris all destroyed and the milk coagu- Fig. 245.—Spirillum metchnikovi, fromanagar-agar culture. XX 1000 (Itzerott and Niemann). lated. Ultimately the clots of casein sediment in irregular masses, from the elear, colorless whey. ; Vital Resistance.—The organism, like the cholera vibrio, is very susceptible to the influence of acids, high temperatures, and drying. The thermal death-point is 50°C., continued for five minutes. Metabolic Products.—The addition of sulphuric acid to a culture grown in a medium rich in peptone produces the same rose color observed in cholera cultures and shows the presence of indol. When glucose is added to the bouillon no fer- mentation or gas-production results. The organism produces acids and curdling enzymes. Pathogenesis.—The organism is pathogenic for animals, but not for man. Pfeiffer has shown that chickens and guinea-pigs are highly susceptible, and when inoculated under the skin usually die. The virulent organism is invariably fatal for pigeons. W. Rindfleisch has pointed out that this constant fatality for pigeons is a valuable criterion for the differentiation of this spirillum from that of cholera, as the subcutaneous injection of the most virulent cholera cultures is never fatal to pigeons, the birds only dying when the injections are made into the muscles in such a manner that the muscular tissue is injured and becomes a locus minoris resistentie. When guinea-pigs are treated by Koch’s method of narcotization and cholera infection, the temperature of the animal rises for a short time, then abruptly falls to 33°C. or less. Death follows in from twenty to 586 Spirillum Schuylkiliensis twenty-four hours. A distinct inflammation of the intestine, with exudate and numerous spirilla, may be found. The spirilla can also be found in the heart’s blood and in the organs of such guinea-pigs. When the bacilli are introduced by subcutaneous inoculation, the autopsy shows a bloody edema and a superficial necrosis of the tissues. ; The organisms can be found in the blood and all the organs of pigeons and young chickens, in such large numbers that Pfeiffer has called the disease Vibrio- nensepticemia. In the intestines very few alterations are noticeable, and very few spirilla can be found. : . ; Immunity.—Gamaléia has shown that pigeons and guinea-pigs can be made immune by inoculating them with cultures sterilized for a time at a temperature of 100°C, Mice and rabbits are immune, except to very large doses. Fig. 246.—Spirillum metchnikovi; puncture culture in gelatin forty-eight hours old (Frankel and Pfeiffer). SPIRILLUM SCHUYLKILIENSIS (ABBOTT) Morphology.—This micro-organism, closely resembling the cholera spirillum, was found by Abbott* in sewage-polluted water from the Schuylkill River at - Philadelphia. Cultivation.—Colonies.—The colonies developed upon gelatin plates very closely resemble those of the Spirillum metschnikovi. Gelatin punctures.—In gelatin puncture cultures the appearance is exactly like the true cholera spirillum. At times the growth is a little more rapid. : Agar-agar.—The growth on agar is luxuriant, and gives off a pronounced odor of indol. , Blood-serum.—Léffler’s blood-serum is apparently not a perfectly adapted medium, but upon it the organisms grow, with resulting liquefaction. Potato.—Upon potato, at the point of inoculation a thin, glazed, more or less dirty yellow growth, shading to brown and sometimes surrounded by a flat, dry, lusterless zone, is formed. . Milk.—In litmus milk a reddish tinge develops after the milk is kept twenty- four hours at body temperature. After forty-eight hours this color is increased and the milk coagulates. Metabolic Products.—In peptone solutions indol is easily detected. No gas is produced in glucose-containing culture-media. Acids and coagulating enzymes are formed. The organism is a facultative anaérobe. m “Journal of Experimental Medicine,” July, 1896, vol. 1, No. 3, p. 419. Spirillum Schuylkiliensis . 587 Vital Resistance.—The thermal death point is 50°C. maintained for five minutes. Pathogenesis.—The organism is pathogenic for pigeons, guinea-pigs, and mice, behaving much like Spirillum metchnikovi. No Pfeiffer’s phenomenon was observed. with the use of serum from immunized animals. Immunity.—Immunity could be produced in pigeons, and it was found that the serum was protective against both Spirillum schuylkiliensis and Spirillum metch- nikovi, the immunity thus produced being of about ten days’ duration. In a second paper by Abbott and Bergey* it was shown that the spirilla occurred in the water during all four seasons of the year, and in all parts of the river within the city, both at low and at high tide. They were also found in the sewage emptying into the river, and in the water of the Delaware River as fre- quently as in that of the Schuylkill. One hundred and ten pure cultures were isolated from the sources mentioned and subjected to routine tests. It was found that few or none of them were iden- tical in all points. There seems to be, therefore, a family of river spirilla, closely related to one another, like the different colon bacilli. The opinion expressed is that ‘“‘the only trustworthy difference between many of these varieties and the true cholera spirillum is the specific reaction with serum from animals immune against cholera, or by Pfeiffer’s method of intraperitoneal testing in such animals.” In discussing these spirilla of the Philadelphia water Bergeyt says: “The most important point with regard to the occurrence of these organisms in the river water around Philadelphia is the fact that similar organisms have been found in the surface waters of the European cities in which there had recently been an epidemic of Asiatic cholera, notably at Hamburg and Altona. . The foremost bacteriologists of Europe have been inclined to the opinion that the organisms which they found in the surface waters of the European cities were the remains of the true cholera organism, and that the deviations in the morphologic and biologic characters from those of the cholera organism were brought about by their prolonged existence in water. No such explanation of the occurrence of the organisms in Philadelphia waters can be given.” A number of interesting spirilla, more or less closely resembling that of Asiatic cholera, have been described from time to time. Their variation from the true cholera organism can best be determined by an examination of the following table, though for precise information the student will do well to look up the original descriptions, references to which are given in each case. * “Journal of Experimental Medicine,” vol. 11, No. 5, p. 535- Tt “Journal Amer. Med. Assoc.,” Oct. 23, 1897. Table of Spirilla 588 fro sberr -d ‘z6gr ,,{yr1yosuasy.oAA "pau aydsjnaq ,, te ‘12d -d ‘v6gr ‘Ar ,,‘neyospuny ayosiualsAzy ,, HL “ghz -d ‘f6gr ‘xix ,,oualsAP any AIgory ,, 23 “gfx -d ‘Sggr | SayLpsuayDO AA “Poul SYISINIG ,, xex “641 -d ‘pOgr'ixx ,,“aualsApy Any ATyoIy ,, It ‘br Joa ‘61h -d ‘o6gr ‘Aqnf ,,{aurstpayyt peyueurriedxq jo yeumnof,, ] [||| “f6gr ,,{neqospuny oyostuar3Aqy ,, tt “69b “d ‘/ggr 11 “pg ‘972 .,°IAVT “J “[qesjuas ,, | *zZ1 “d ‘p6gt “Ixx ,,{aueIsAH Any AIIY ,, “WHE *d ‘AIX “O79 TACT “F TQTBIWID ,, xx 664 ‘d ‘f6gr ,,“YysuayIOAA “peut aydsynaq_,, || segh d ‘11 ‘gggi ,,{Inays¥q "Jsu],[ 2p ‘uuy ,, “Sggr ,,{9slayosuay0MA ‘paur ayosynaqq ,, f *2fg -d ‘bggr ,,“WlryosuayooM “paw ayosnaq ,,f ‘zl pue rf “sony ‘Pggi ,,{YIIYIsuayIoM “UITH JoUrpIag ,, « , oo + LHIOT+/+] fo] + Jol+iti+jojofol+}ol+] o joj + | o | + J+]+lojof+l+4} o |4] o Aasiag pure yoqqy) aeuataens umy[iaids o|o ° ° +)o]o +/o] o Jo] + | o | o |+/+folo}+j4+}] o J+} o fr rrr tte (222 seyyuNyd) stenbe wnyiaids ojo + ° ° +AL+]+ +/o] o |+! 0 | o | + |4+]+}ojo}+}+] o {+} o BE OLE 27 6 (ttt dosstany) stsusutjoi1sq uinyyisidg ojo ° ol+ ojo|o +lo] o Jo] o | ¢ | & j+[tlojoj+]t+]o jo] o Jess sr ss + + Qibsayqquny) snuasii9} wmypisidg o]o}o} 0 jolo ° +/o}olojojo}/+jo}+} + Jo] o | o | + J4]/4lofol+]4+] o lo} o Js setter ees os mth ee eo ey wnypiids ° ° +P +lofo} |+jo} + Jo} o | o | + [t]+fojolt}4+] o J+} oft tte stots + (II TqreAA) Teqrem umypuids o}0 + ° ° o}+}+!ojo/+ O}o} o Jo] o | o | + J+]4+}ofoj+jt+] o f+} o yt tt ttt tee (22 yoyuog) suatovjanbrt wnypisids o;oj+] + J+ + IED she bP see ae ape eke) fed Re SO ee (ff exoruze A) TT umyptaids sa + + jo} o | o | + !+)+lolol+l+} 0 J+] o le ee sere costs (Lhaysrura aA) J amypiids oe. + Oj+}+) Jo +/O/o}ojofol+)+jo} o |4/ o | o | + [+i+jojt{ol+} o [+] 0 fests tet eee (x4 JOploH) snoiqnuep wmytatds + + o +)+)+}o]ofo}+ o| + Jo] o | o | + |+]+lolololj+}].o J+] o Jester tees (| tequnq) stsuaiequnp wnyfiids | *dnosip 41938 oJojo) + i+)o}+} +] 0/0 ++i t}oyojt] Jojt] o fof + | +] o J+ltjofolt}+]} o jo] +]yrrrrc: * + (@ergewmed) rAoyruyosjour wnya1ds ojo + ° ° +]Ojojojofoj+fo}+] o Jt] o | o | + J+][+fofof+j+] o Jo} frre erste (f{ 2yoeuaq) wnusg0143 winds ojo + ° o| + +)O}O;o]+/o}+}o}+]) + Jo} o | o | + J+j)+yofol+]+] o fof + ferret ee ete eee (fsolrg pue sat_xurg) (sneqzoid = urny[iidg) sexjsou Ziejoys wnyuids O} 0/0] + /O/O}o}+lo}o; + Joj+}+it+lol+lo} j+lo] o J+} o | o | + J4+i+fofol+]4] o J+} 4 ]erccc ree (x Yoox) eoyeIse e2rapoys umy[I1Ids ‘dnosp jeursezuy Wa wn n g/g 3 (8 |S RIE Qitlaslzej |Z S0|2|2 a “WATTIMIdS VYATOHD AHL ONITAWNASAY SWNSINVDONO DNILVUVdES UOA ATAVL IWILNAUAATIA CHAPTER XXVII TYPHOID FEVER Bacittus TypHosus (Esertu-GAFFKy) General Characteristics——A motile, flagellated, non-sporogenous, non- liquefying, non-chromogenic, non-aérogenic, atrobic and optionally anaérobic, pathogenic bacillus, staining by ordinary methods, but not by Gram’s method, not forming indol, acids from sugars, or coagulating milk. Typhoid fever, ‘“‘typhus abdominalis,”’ enteric fever, ‘‘la fievre typhique,’’ is a disease so well known and of such universal distribu- tion, that no introductory remarks concerning it are necessary. The bacillus of typhoid fever (Bacillus typhosus) was discovered , {a7 teh <7 Se" arr ty pees! Woy Se! 4 Mees 2 ean he a es gy) 4 Fig. 247.—Bacillus typhosus, from twenty-four-hour culture on agar. ‘(From Hiss and Zinsser, ‘‘Text-book of Bacteriology,” D. Appleton & Co., publishers.) in 1880 by Eberth* and Koch, and was first secured in pure culture from the spleen and lymphatic glands four years later by Gaffky.} Distribution.—The bacillus is both saprophytic and parasitic. It finds abundant opportunity in nature for growth and devel- opment, and, enjoying strong resisting powers, can accommodate itself to its environment much better than the majority of pathogenic bacteria, and can be found in water, soiled clothing, dust, sew- age, milk, etc., contaminated directly or indirectly with the intestinal discharges of diseased persons. * “Virchow’s Archiv,” 1881 and 1883. t “Mittheilungen aus dem kaiserl. Gesundheitsamte,” 1, 45. T Ibid., 2. 589 590 Typhoid Fever Morphology.—The typhoid bacillus measures about 1 to 3 yu (2 to 4 w—Chantemesse, Widal) in length and 0.5 to 0.8 w in breadth ' (Sternberg). The ends are rounded, and it is exceptional for the bacilli to be united in chains. The size and morphology vary with the nature of the culture-medium and the age of the culture. Thoi- not and Masselin,* in describing these morphologic variations, point out that when grown in bouillon the typhoid bacillus is very slender; in milk it is stouter; upon agar-agar and potato it is thick and short; and in old gelatin cultures it forms long filaments. It produces no spores. Flagella.—The organisms are actively motile and are provided with numerous flagella, which arise from all parts of the bacillus (peritricha), and are 10 to 20 in number. They stain well by Fig. 248.—Bacillus typhosus. Loffler’s method. The movements of the short bacilli are oscillating; those of the longer bacilli, serpentine and undulating. Staining.—The organism stains quite well by the ordinary methods, but not by Gram’s method. As it gives up its color in the presence of almost any solvent, it is difficult to stain in tissue. When sections of tissue are to be stained for the demonstration of the typhoid bacilli, the best method is to allow them to remain in Loffler’s alkaline methylene blue for from fifteen minutes to twenty- four hours, then wash in water, dehydrate rapidly in alcohol, clear up in xylol, and mount in Canada balsam. Ziehl’s method also gives good results: The sections are stained for fifteen minutes in a solution of distilled water, 100, fuchsin 1, and phenol 5. After staining they are washed in distilled water containing 1 per cent.of acetic acid, dehydrated in alcohol, cleared, and mounted. In such -* “Précis de Microbie,” Paris, 1893. Cultivation 501 preparations the bacilli are always found in scattered groups, which are easily discovered, under a low power of the microscope, as reddish specks, and readily resolved into bacilli with the oil-im- mersion lens. In bacilli stained with the alkaline methylene-blue solution, dark-colored dots (Babes-Ernst or metachromatic granules) may sometimes be observed near the ends of the rods. Isolation.—The bacillus can be secured in pure culture from an enlarged lymphatic gland or from thesplenic pulp of a case of typhoid. As the groups of bacilli are sometimes widely scattered through- out the spleen, E. Frankel recommends that as soon as the organ is removed from the body it be wrapped in cloths wet with a solution of bichlorid of mercury and kept for three days in a warm room, in order that a considerable and massive development of the bacilli Fig. 249.—Bacillus typhi abdominalis; superficial colony two days old, as seen upon the surface of a gelatin plate. X 20 (Heim). may take place. The surface is then seared with a hot iron and ma- terial for cultures obtained by introducing a platinum loop into the substance of the organ through the sterilized surface. Cultures may be more easily obtained from the blood of the living patients. _ (See “Blood culture,’ under the section “ Bacterio- logic Diagnosis.””) The bacilli can also be secured from the alvine discharges of typhoid patients during the second and third weeks of the disease. Cultivation.—The bacillus grows well upon all culture-media under both aérobic and anaérobic conditions. Colonies.—The deep colonies upon gelatin plates appear under the microscope of a brownish-yellow color and spindle-shape, and are sharply circumscribed. When superficial, however, they become larger and form a thin, bluish, iridescent layer with notched edges. The superficial colonies are often described as resembling grapevine leaves in shape. The center of the superficial colonies is the only 592 | Typhoid Fever portion which shows the yellowish-brown color. The gelatin is not liquefied. Gelatin Punctures.—When transferred to gelatin puncture cul- tures, the typhoid bacilli develop along the entire track of the wire, with the formation of minute, confluent, spheric colonies. A small, thin, whitish layer develops upon the surface near the center. The gelatin is not liquefied, but is sometimes slightly clouded in the neigh- borhood of the growth. Agar-agar.—The growth upon the surface of obliquely solidified gelatin, agar-agar, or blood-serum is not luxuriant. It forms a thin, moist, shining, translucent band with smooth edges and a grayish- yellow color. Potato.—When potato is inoculated and stood in the incubating oven, no growth can be seen even at the end of the second day, but if the surface of the medium be touched with a platinum wire, it is found entirely covered with a rather thick, invisible layer of sticky vegetation which the microscope shows to be made up of bacilli. This is described as the invisible growth. Unfortunately, “it is not a constant characteristic, for occasionally a typhoid bacillus will show a distinct yellowish or brownish color. The typical growth seems to take place only when the reaction of the potato is acid. Bouillon.—In bouillon the only change produced by the growth of the bacillus is a diffuse cloudiness. Rarely a pellicle is formed. When sugars are added to the bouillon the typhoid bacillus is found to form acid from dextrose, levulose, galactose, mannite, maltose, and dextrin, but not to form acid from lactose or saccharose. No gas is formed in the fermentation tube with any of the sugars. No indol is formed. Milk.—In milk containing litmus a very slight and slow acidity is produced, which later gives place to distinct alkalinity. The milk is not coagulated. Vital Resistance.—The organisms grow well at all ordinary tem- peratures. The thermal death-point is given by Sternberg at-56°C., destruction being effected in ten minutes. Upon ordinary culture- media, the organisms remain alive for several months if drying is prevented. In carefully sealed agar-agar tubes Hiss found the or- ganism still living after thirteen years. According to Klemperer and Levy,* the bacilli can remain vital for three months in distilled water, though in ordinary water the commoner and more vigorous sapro- phytes outgrow them and cause their disappearance in a few days. There seems to be some doubt, however, on this point, as Tavelt found that it livedfor six months in the blind terminal of a water- supply pipe, and Hofmann,{ after planting it in an aquarium con- * “Clinical Bacteriology.” Translated by A. A. Eshner, Phila., W. B. Saun- ders Co., 1900. / t “Centralbl. f. Bakt. u. Parasitenk.,” 1903, XXXIII, p. 166. T “Archiv. f. Hyg.,” 1905, LI, 2, 208. Toxic Products 593 taining fish, snails, water-plants, and protozoa, was able to recover it from the water after thirty-six days, and from the mud in the bot- tom after two months. In elaborate experimental studies of this question Jordan, Russel, and Zeit* found its longevity to be only three or four days under conditions resembling as nearly as possible those found in nature. When buried in the upper layers of the soil the bacilli retain their vitality for nearly six months. Robertsonf found that when planted in soil and occasionally fed by pouring bouillon upon the surface, the typhoid bacillus maintained its vitality for twelve months. He suggests that it may do the same in the soil about leaky drains. Cold has little effect upon typhoid bacilli, for some can withstand freezing and thawing several times. Observing that epidemics of typhoid fever had never been traced to polluted ice, Sedgwick and Winslowt made some investigations to determine what quantitative reduction might be brought about by freezing, and accordingly ex- perimentally froze a large number of samples of water intentionally infected with large numbers of typhoid bacilli from different sources. It was found that the bacilli disappeared in proportion to the length of time the water was frozen, and that the reduction averaged 99 per cent. in two weeks. The last two or three bacilli per thousand appeared very resistant and sometimes remained alive after twelve weeks. They have been found to remain alive upon linen from sixty to seventy-two days, and upon buckskin from eighty to eighty-five days. The typhoid bacillus resists the action of chemic agents rather better than most non-sporogenous organisms. The addition of from o.1 to 0.2 per cent. of carbolic acid to the culture-media is without effect uponits growth. At one time the tolerance to carbolic acid was thought to be characteristic, but it is now known to be shared by other bacteria (colon bacillus). Itis killed by 1 : 500 bichlorid of mercury solutions and 5 per cent. carbolic acid solutions in five minutes, Metabolic Products.—The typhoid bacillus does not produce indol. It produces a small amount of acid when grown in sugar-containing media, but its regular tendency is to form alkalies, as is shown by the .Teactions in litmus milk. It forms no coagulating or proteolytic enzymes. Toxic Products.—The disproportion of local to constitutional dis- turbance in typhoid fever and the irritative and necrotic charac- ter of its lesions suggest that we have to do with a toxic organism. Brieger and Frankel have, indeed, separated a toxalbumin, which they thought to be the specific poison, from bouillon cultures. When * “Journal of Infectious Diseases,” 1904, I, p. 641. { “Brit. Med. Jour.,” Jan. 8, 1893. as t “Jour. Boston Soc. of Med. Sci.,” March 20, 1900, vol. 1v, No. 7, p. 181. 38 594 Typhoid Fever injected into guinea-pigs the typhotoxin of Brieger causes salivation, accelerated respiration, diarrhea, mydriasis, and death in from twenty-four to forty-eight hours. Klemperer and Levy also point out, as affording clinical proof of the presence of toxin, the occasional fatal cases in which the typical picture of typhoid has been without the characteristic postmortem lesions, the diagnosis being made by the discovery of the bacilli in the spleen. Pfeiffer and Kolle* found toxic substance in the bodies of the bacilli only. It was not, like the toxins of diphtheria and tetanus, dissolved in the culture-medium. ‘This was an obstacle to the immu- nization experiments of both Pfeiffer and Kolle and Léffler and Abel, for the only method of immunizing animals was to make massive agar-agar cultures, scrape the bacilli from the surface, and distribute them through an indifferent fluid before injecting them into animals. If the bacilli grown upon ordinary culture-media are several times washed in distilled water, and then allowed to macerate in normal salt solution, autolysis takes place and a toxin is liberated, showing that the toxin is intracellular. Macfadyen and Rowland{ liberated an intracellular toxin from cultures of the typhoid bacilli by freezing them with liquid air and grinding them in anagate mortar. Animals immunized with this poison produced an antiserum active against it, but useless against infection with typhoid bacilli. Wright, of Net- ley§, observes that Macfadyen’s method of securing this intracel- lular toxin was unnecessarily cumbersome, as the body juices of animals injected with dead cultures of the bacilli dissolve them at once and thus liberate the same toxic product. Besredka|| and Macfadyen** think that exotoxin is also formed. Vaughanff has obtained poisonous and non-poisonous fractions by extracting massive cultures of typhoid bacilli with 2 per cent. solu- tions of sodium hydrate in absolute alcohol at 78°C. Mode of Infection—The typhoid bacillus enters the body by way of the alimentary tract with infected foods and water. Rosenau, Lumsden, and Kastlet{ were able to connect ro per cent. of the cases of typhoid fever occurring in the District of Columbia with infection through milk. Interesting additional facts upon the subject can be found in Bulletin No. 41 of the Hygienic Laboratory upon “Milk in its Relation to the Public Health.” The bacillus occasionally enters milk in water used to dilute it or to wash the cans. The occurrence of typhoid fever among the soldiers of the United States Army during the Spanish-American War in 1898 was shown by * “Deutsche med. Wochenschrift,” Nov. 12, 1896. { “Centralbl. f. Bakt. u. Parasitenk.,” Jan. 23, 1896, Bd. xx, No. 23, p. 51. t “Brit. Med. Jour.,” 1903. § Ibid., April, 4, 1903, 1, p. 786. || ‘Ann. de I’Inst. Pasteur,” 1895, x, 1896, Xi. ** “Centralbl. f. Bakt.,” etc., 1906, I. tt “Amer. Jour. Med. Sci.,” 1908, CXXXVI. 4 “Hygienic Laboratory Bulletin No. 33,” Washington, D. C., 1907. Pathogenesis 595 Reed, Vaughan, and Shakespeare* to be largely the result of the pollution of the food of the soldiers by flies that shortly before had visited infected latrines. The bacillus is also occasionally present upon green vegetables grown in soil fertilized with infected human excrement or sprinkled with polluted water, and epidemics are reported in which the occur- rence of the disease was traced to oysters infected through sewage. Newsholmef found that in 56 cases of typhoid fever about one-third were attributable to eating raw shell-fish from sewage-polluted beds. Pathogenesis.—The primary activities of the typhoid bacillus are unknown. It is supposed that it passes uninjured through the acid secretions of the stomach to enter the intestine, where local dis- turbances are set up. Whether during an early residence in the intestine its metabolism is accompanied by the formation of a toxic product, irritating to the mucosa, and affording the bacilli means of entrance to the lymph-vessels, through diminutive breaches of con- tinuity, is not known. We usually find it well established in the intestinal and mesenteric lymphatics at the time we are able to recognize the disease. It is quite. certain that the chief operations of the typhoid bacillus are in the tissues and not in the intestine, as seems to bea widely prevalent error. It is contrary to most of our knowledge of the organism that it should easily adapt itself to saprophytic exist- ence among the more vigorous intestinal organisms. Those who look for it in the feces are usually surprised at the difficulty of finding it, or at the small numbers present. It is far more easy to isolate the organism from the blood than from the feces, and much greater numbers occur in the urine than in the feces. It probably es- capes from the blood into the bile, where it grows luxuriantly, and entering the gall-bladder may take up permanent residence there, escaping into the intestine each time the gall-bladder is emptied. Many bacilli thus discharged probably meet with destruc- tion in the intestine, though some convalescents from typhoid fever for years have a periodic appearance of bacilli in the feces. Such individuals have become known as “typhoid carriers” and are a men- ace to the public. In a case studied by Millert bacilli were found in the gall-bladder seven years after recovery from typhoid fever; in a case studied by Droba§ they were found in both the gall-bladder and a gall-stone seventeen years after recovery from the disease; Humer,|| found them in the gall-bladder of a patient suffering from cholecystitis, eighteen years after recovery from an attack of typhoid fever, and ina i “Report on Typhoid Fever in the U. S. Military Campsin the Spanish War,” vol. 1. + “Brit. Med. Jour.,” Jan., 1895. {t ‘Bull. of the Johns Hopkins Hospital,” May, 1808. § “Wiener klin. Wochenschrift,” 1899, XU, p. 1141. il “Bull. of the Johns Hopkins Hospital,” Aug. and Sept., 1899. 596 Typhoid Fever case studied by Dean,* they were present in the stools of a man twenty-nine years after he had had an attack of typhoid fever. Cushing} invariably found the bacilli in the bile in clumps resembling the agglutinations of the Widal reaction. He thinks it probable that these clumps form nuclei upon which bile salts can be precipitated and calculous formation begun. The presence of gall-stones, together with the long-lived infective agents, may at any subsequent time provoke cholecystitis. Cushing collected 6 cases of operation for cholecystitis with calculi in which typhoid bacilli were present, and 5 in which Bacillus coli was present in the gall-bladder. _ Fig. 250.—Intestinal perforation in typhoid fever. Observe the threads of tissue obstructing the opening. (Museum of the Pennsylvania Hospital.) (Keen, ‘Surgical Complications and Sequels of Typhoid Fever.”’) With the most approved methods yet devised, Peabody and Pratt{ were unable to recover the micro-organism from the intestinal contents in more than 21 per cent. of febrile cases, and only in small numbers as a rule. The greatest number was obtained when there was much blood in the stool. There is always well-marked blood-infection during the first weeks of the disease, and upon this depends the occurrence of the rose-colored spots. . * “British Medical Journal,” March 7, 1908, 1, p. 562. tT “Bull. of the Johns Hopkins Hospital,” 1x, No. 86. } “Journal of the American Medical Association,” Sept. 7, 1907, XLIX, p. 846+ Pathogenesis 507 The bacilli enter the solitary glands and Peyer’s patches, and multiply slowly during the incubation period of the disease—one to three weeks. The immediate result of their activity in the lymphatic structures is an increase in the number of cells, the ultimate effect is necrosis and sloughing of the Peyer’s patches and solitary glands. From the intestinal lymphatics the bacilli pass, in all probability, to the mesenteric nodes, which become enlarged, softened, and sometimes rupture. They also invade the spleen, liver and some- times the kidneys, and other organs where they may be found in small clusters in properly stained specimens. Mallory* found the histologic lesions of typhoid fever to be wide- spread throughout the body and not limited to the Peyer’s patches of the intestine, where they are most evident. His conclusions regard- ing the pathology of the disease are briefly: ‘The typhoid bacillus produces a mild diffusible toxin, partly within the intestinal tract, partly within the blood and organs of the body. This toxin pro- duces proliferation of the endothelial cells, which acquire for a certain length of time malignant properties. The new-formed cells are epithelioid in character, have irregular, lightly staining, ec- centrically situated nuclei, abundant, sharply defined, acidophilic protoplasm, and are characterized by marked phagocytic properties. These phagocytic cells are produced most abundantly along the line of absorption from the intestinal tract, both in the lymphatic ap- paratus and in the blood-vessels. They are also produced by dis- tribution of the toxin through the general circulation, in greatest numbers where the circulation is slowest. Finally, they are pro- duced all over the body in the lymphatic spaces and vessels by absorption of the toxin eliminated from the blood-vessels. The swelling of the intestinal lymphoid tissue of the mesenteric lymph nodes and of the spleen is due almost entirely to the forma- tion of phagocytic cells. The necrosis of the intestinal lymphoid tissue is accidental in nature and is caused through occlusion of the veins and capillaries by fibrinous thrombi, which owe their origin to degeneration of phagocytic cells beneath the lining endothelium of the vessels. ‘Two varieties of focal lesions occur in the liver: one consists of the formation of phagocytic cells in the lymph-spaces and vessels around the portal vessels under the action of the toxin absorbed by the lymphatics; the other is due to obstruction of liver capillaries by phagocytic cells derived in small part from the lining endothelium of the liver capillaries, but chiefly by embolism through the portal circulation of cells originating from the endothelium of the blood-vessels of the in- testine and spleen. The liver-cells lying between the occluded capillaries undergo necrosis and disappear. Later the foci of cells / degenerate and fibrin forms between them. Invasion by poly- morphonuclear leukocytes is rare.” ; * “Journal of Experimental Medicine,” 1898, vol. U1, p. 611. 598 Typhoid Fever “|. Histologically the typhoid process is proliferative and stands in close relationship to tuberculosis, but the lesions are diffuse and bear no intimate relation to the typhoid bacillus, while the tubercular process is focal and stands in the closest relation to the tubercle bacillus.” The growth of the bacilli in the kidneys causes albuminuria, and the bacilli can be found in the urine in about 25 per cent. of the cases. Smith* found them in the urine in 3 out of 7 cases which he investi- gated; Richardson, f in 9 out of 38 cases. They did not occur before the third week, and remained in one case twenty-two days after cessation of the fever. Sometimes they were present in immense numbers, the urine being actually clouded by their presence. Petruschky{t found that albuminuria sometimes occurs without the presence of the bacilli; that their presence in the urine is infre- quent; that the bacilli never appear in the urine in the early part of the disease, and hence are of little importance for diagnostic pur- poses. Gwyn§ has found as many as 50,000,000 typhoid bacilli per cubic centimeter of urine, and mentions a case of Cushing’s in which the bacilli persisted in the urine for six years after the primary attack of typhoid fever. Their occurrence, no doubt, depends pri- marily upon a typhoid bacteremia, by which they are brought to the kidney. Their persistence in the urine after recovery from typhoid fever, depends upon continued growth in the bladder and not upon continuous escape from the blood. It is of importance from a sanitary point of view to remember that the urine as well as the feces is infectious. The bacilli pass from the lymphatics to the general circulation, so that all cases of typhoid fever are true bacteremias during part or all of their course. Bacilli can be found in the circulating blood. The eruption may be regarded as one of the local irritative manifestations of the bacillus, as the blood from the roseole always contains them, and Richardson|| found it necessary to examine a number of spots in each case. He carefully disinfected the skin, freezing it with chlorid of ethyl, making a crucial incision, and cultivating from the blood thus obtained. He was able to secure the typhoid bacillus in 13 out of 14 cases examined. As a means of diagnosis the matter is of some importance, as the rose spots may precede the occurrence of the Widal reaction by a number of days. In rare instances the bacillus may be found in the expectoration, especially when pulmonary complications arise in the course of the * «Brit. Med. Jour.,” Feb. 13, 1897. { ‘‘Journal of Experimental Medicine,” May, 1808. t “Centralbl. f. Bakt. u. Parasitenk.,” May 13, 1898, No. 13, p. 577- § “Phila. Med. Jour.,” March 3, 1900. | “Phila. Med. Jour.,” March 3, 1900. Prophylaxis 599 disease. Cases of this kind have been reported by Chantemesse and Widal* and Frinkel.+ The pyogenic power of the typhoid bacillus was first pointed out by A. Frankel, who observed it in a suppuration that occurred four months after convalescence. Low{ found virulent typhoid bacilli in the pus of abscesses occurring from one to six years after convalescence. Weichselbaum has seen general peritonitis from rupture of the spleen in typhoid fever, with escape of the bacilli. Otitis media, ostitis, periostitis, and osteomyelitis are common results of the lodgment of the bacilli in bony tissue. Ohlmacher§ has found the bacilli in suppurations of the membranes of the brain. The bacilli are also encountered in other local suppurations occurring in or following typhoid fever. Flexner and Harris|| have seen a case in which the distribution of the bacilli was sufficiently widespread to constitute a real septicemia. Lower Animals.—Typhoid fever is communicable to animals with difficulty. They are not infected by bacilli contained in fecal matter or by the pure cultures mixed with the food, and are not injured by the injection of blood from typhoid patients. Gaffky failed completely to produce any symptoms suggestive of typhoid fever in rabbits, guinea-pigs, white rats, mice, pigeons, chickens, and calves, and found that Java apes could feed daily upon food pol- luted with typhoid bacilli for a considerable time, yet without symptoms. Griinbaum** produced typhoid fever in chimpanzees by inoculating them with the bacillus. The introduction of viru- lent cultures into the abdominal cavity of animals is followed by peritonitis. Germano and Maurea}{ found that mice succumbed in from one to three days after intraperitoneal injection of 1 or 2 cc. of a twenty- four-hour-old bouillon culture. Subcutaneous injections in rabbits and dogs caused abscesses. Lésener found the introduction of 3 mg. of an agar-agar culture into the abdominal cavity of guinea-pigs to be fatal. Petruschkytt found that mice convalescent from subcutaneous injections of typhoid cultures frequently suffered from a more or less widespread necrosis of the skin at the point of injection. Prophylaxis.—One of the most important and practical points for the physician to grasp in relation to the subject of typhoid fever is the highly infective character of the discharges, both feces and urine. *“ Archiv. de physiol. norm. et. path.,” 1887. t “Deutsche med. Wochenschrift,” 1899, XV, XVI. }“Sitz. der k. k. Gesellschaft d. Aerzt. in Wien,” ‘“Aerztl. Central-Anz.,” 1898, No. 3. § “Jour. Amer. Med. Assoc.,” Aug. 28, 1897. al “Bull. Johns Hopkins Hospital,” Dec., 1897. Brit. Med. Jour.,” April 9, 1904. it “‘Ziegler’s Beitrage,” Bd. x11, Heft 3, p. 494. ti‘Zeitschrift fiir Hygiene,” 1892, Bd. XI, p. 261. 600 Typhoid Fever In every case the greatest care should be taken for their proper ' disinfection, a rigid attention paid to all the details of cleanliness in the sick-room, and the careful sterilization of all articles which are soiled by the patient. If country practitioners wereas carefulin this particular as they should be, the disease would be much less frequent in regions remote from the filth and squalor of large cities with their unmanageable slums, and the distribution of the bacilli to villages and towns, by milk, and by watercourses polluted in their infancy, might be checked. In large cities where typhoid fever has been endemic the incidence of the disease has been enormously reduced by purification of the water-supply. Where this measure is not possible, the safety of the individual citizens can be promoted by using bottled pure waters for drinking purposes or by boiling the water for domestic con- sumption. In military camps, etc., the fly as a carrier of the infection must first be excluded from the latrines and then as well from the kitchens and mess tents. When epidemics are in progress, green vegetables and oysters that may be polluted by infected water must be guarded against. : Prophylactic Vaccination.—Following the principle of Haffkine’s anticholera inoculations, Pfeiffer and Kolle,* Wright,f and Wright and Semplet have used subcutaneous injections of sterilized cultures asaprophylacticmeasure. Onecubiccentimeter of a bouillon culture sterilized by heat was used. . The “Indian Medical Gazette” gives the following important figures showing what was accomplished in 1899: Among the British troops in India there were 1312 cases of typhoid fever, with 348 deaths (25 per cent.). The ratio of admissions to the total strength was 20.6 per 1000. There were 4502 inoculations, and among them there were only 9 deaths from typhoid fever—o.2 per cent. of the strength. There were 44 admissions, giving 0.98 per cent. of the strength. Among the non-inoculated men of the same corps and at. the same stations, of 25,851 men there were 675 cases and 146 deaths, giving the relative percentages of admissions and deaths as 2.54 and 0.56.§ In a later contribution, Wright|| showed that the prophylactic vaccination against typhoid fever reduced the number of cases and diminished the death-rate among the inoculated, and also called attention to the slight risk the inoculated run of being injured in case their vital resistance is below normal, or they are already in the early stages of the disease, or where the dose administered is too Sarge, or the second vaccination given too soon after the first. * “Deutsche med. Wochenschrift,” 1896, XXII; 1898, XXIV. t “Lancet,” Sept., 1896. t “Brit. Med. Jour.,” 1897, I, p. 256: “Phila. Med. Jour.,” Oct. 13, 1900, p. 688. } “The Lancet,” Sept. 6, 1902. : Specific Therapy 601 In 1903 Wright* published new statistics on the subject, and between 1903 and 1908 numerous references to the subject appear in the “British Medical Journal,” in the “Lancet,” and in the “Journal of the Royal Army Medical Corps,” all favorable in their general attitude. During the Mexican Revolution of 1911, the United States Govern- ment began, on March 10, 1911, the mobilization of regiments of the United States Army on the Mexican frontier near San Antonio, Texas. In order to prevent repetition of the sad experiences of the Spanish-American War, in which the troops suffered terribly from typhoid fever, the Secretary of War determined that the entire command should be immunized against the disease. Many of the soldiers arriving on.the ground had already been immunized, the re- mainder were at once given the necessary injection upon arrival. The mean strength of the command at San Antonio was 12,000 up to June 30, 1911, a period approximating four months. During all that time there were only 2 cases of typhoid fever in the encamp- ment, 1 in an uninoculated civilian teamster and 1 in an inoculated soldier. Both cases recovered. The soldier suffered from so mild an attack that it would not have been diagnosed had not a blood- culture been made. During the four months from March 1oth to June 30th the typhoid fever was prevalent among the civilians of San Antonio, there being 4o cases with 19 deaths.t The prophylactic used was prepared from a specially selected strain of Bacillus typhosus grown on agar-agar in Kolle flasks for twenty-four hours. The growth was washed off with normal salt solution, killed by heating at 55° to 56°C. in a water-bath, standard- ized by counting the bacteria according to the method of Wright, and after being diluted with salt solution, 0.25 per cent. of trikresol was added. One cubic centimeter of the finished prophylactic con- tained 1,000,000,000 bacilli. The first dose injected contained 500,000,000 bacilli, the second and third, given after ten and twenty days, contained 1,000,000,c00 each. The injections caused little inconvenience either locally or constitutionally. Only 1 case had ~ fever, chills, and sweats, and this was the only case requiring treatment in the hospital. It subsequently developed that this soldier was suffering from early tuberculosis, which may explain the untoward symptoms from which he suffered. Specific Therapy.— Animals can be immunized to this bacillus, and then, according to Chantemesse and Widal, develop antitoxic blood capable of protecting other animals. Sternt found in the blood of human convalescents a substance thought to have a protective effect upon infected guinea-pigs. His observation is in accordance with a * “Brit. Med. Jour.,” Oct. 10, 1903. t “Report of the Surgeon-General of the United States Army to the Secretary of War,” 1911, Washington, D. C. } “Zeitschrift far Hygiene,” 1894, XVI, p. 458. 602 Typhoid Fever previous one by Chantemesse and Widal, and has recently been abundantly confirmed. ; The immunization of dogs and goats by the introduction of increasing doses of virulent cultures has been achieved by Pfeiffer and Kolle* and by Léffler and Abel.t From these animals immune serums were secured. Walgert reported 4 cases treated successfully with a serum ob- tained from convalescent patients. Ten cubic centimeters were given at a dose, and the injection was repeated in 1 case with relapse. Rumpf§ and Kraus and Buswell|| report a number of cases of typhoid favorably influenced by hypodermic injections of small doses of sterilized cultures of Bacillus pyocyaneus. Jez** believes that the antitoxic principle in typhoid fever is con- tained in some of the internal organs instead of the blood, and claims Fig. 251.—Typhoid bacilli, unaggluti- Fig. 252.—Typhoid bacilli, showing nated (Jordan). typical clumping by typhoid serum (Jordan). to have obtained remarkable results in 18 cases treated with extracts of the bone-marrow, spleen, and thymus of rabbits previously in- jected with the typhoid bacillus. Chantemesse,{tt Pope,{t and Steele§§ have all used serums from animals immunized against typhoid cultures for the treatment of typhoid fever, with more or less success but an analysis of the results shows them to be very inconclusive. The serum prepared by Macfadyen,]|||| by crushing cultures . *“Centralbl. f. Bakt. u. Parasitenk.,” Jan. 23, 1896, Bd. xix, No. 23, p. 51. T Ibid, 1896. t “Miinchener med. Wochenschrift,” Sept. 27, 1898. ; “Deutsche med. Wochenschrift,” 1893, No. 41. || ‘Wiener klin. Wochenschrift,” July 12, 1894. ** “Méd. moderne,” March 25, 1899. TT “Gaz. des Hépitaux,” 1898, LXxI, p. 307. tt “Brit. Med. Jour.,” 1897, 1, 259. §§ Ibid., April 17, 1897. lll “Brit. Med. Jour.,” April 3, 1903. Bacteriologic Methods 603 frozen with liquid air and injecting animals with the thus liberated intracellular toxin, seems to be no improvement upon others. Meyer and Bergell* prepared a serum by injecting horses with a new typhoid toxin. After two years’ treatment they were able to demonstrate its value in curing infection in laboratory animals. von Leyden} speaks in favorable terms of this serum. The typhoid immune (bacteriolytic) serum is specific, but its action requires the presence of additional complementary substance, and by itself itis useless. Indeed, it may do harm by causing the formation of anti-immune bodies. So far no serum has been produced that is of any certain value in therapeutics. Bacteriologic Diagnosis.—There are four bacteriologic methods that may assist the clinician in completing the diagnosis of typhoid fever. In the order of their general usefulness and practicability these are: 1. The Widal reaction of agglutination. 2. The blood-culture. 3. The isolation of the bacillus from the feces. 4. The conjunctival and dermal reactions. Widal Reaction of A gglutination—This very valuable adjunct to our means of making the diagnosis of atypical and obscure cases of typhoidal infection was discovered in 1896 when Widal and Griin- baum,t working independently, observed that when blood-serum from typhoid fever patients is added to cultures of the typhoid bacillus a definite reactive phenomenon occurs. The phenomenon, now familiarly known as the “‘ Widal reaction,” consists of complete loss of the motion so characteristic of the typhoid bacillus, and the collection of the micro-organisms into clusters or groups—agglutina- tion. The bacteria frequently appear shrunken and partly dissolved. The technic of the test is outlined in the section upon Agglutination (q.v.). For the use of the practising physician, commercial houses now furnish various outfits known as ‘“‘agglutometers,” in which are found such simple apparatus and directions as will enable those inexpert in laboratory manipulations to arrive at fairly accurate results. The Blood-culture-——The technic of this operation is simple. The skin of the fold of the elbow is thoroughly cleansed, a fillet put about the arm, and as the veins become prominent, a sterile hypo- dermic needle is introduced into one and about 10 cc. of blood drawn into a Keidel tube or into a syringe. Before clotting can take place, this is discharged into a small flask containing 100 cc. of bouillon, mixed, and stood away to incubate. After twenty-four hours the bacilli can usually be found in pure culture. * “Med. Klinik,” m1, No. 31, p. 917, Aug. 4, 1907. t “Berl. klin. Wochenschrift,”’ 1907, No. 18. Tt “La Semaine Médicale,” 1896, p. 295. 604 Typhoid Fever Tn case the culture is not pure, the typhoid bacillus can be sepa- rated from contaminating organisms by plating. The Isolation of the Bacillus from the Feces.—This method of making the diagnosis has practically been abandoned because of its uncertainty, its cumbersomeness, its tediousness, and because the preceding methods suffice in all cases. An excellent résumé of the many methods employed for isolating the bacillus from the stools has been published by Peabody and Pratt,* and is appropriate reading for those interested in this subject. The Conjunctival Reaction —An additional aid to the diagnosis of typhoid in doubtful cases based upon the Wolff-Eisner-Calmette reaction in tuberculosis is the ‘‘ocular typhoid reaction” of Chan- temesse.{| This test consists in the instillation into the eye ofa solution-made by extracting the typhoid bacillus as follows: ‘“‘Gela- tin plates covered with an eighteen- to twenty-hour-old culture of virulent typhoid bacilli were washed with 4 to 5 cc. of sterile water. The suspension thus obtained was heated to 60°C., centrifugated, and the supernatant fluid withdrawn. The centrifugated organisms were then dried and triturated. A second suspension of these broken up bacillary bodies was then made, and allowed to stand for from two to three days at 60°C. The extract thus obtained, after removing the disintegrated and digested remnants, was precipitated with alcohol, forming a fine coagulum. This was subsequently dried, powdered and dissolved in sterile water in the proportion of 0.02 mg. to a drop.’”’t When one drop of this is placed upon the conjunctiva of a patient in the early days of typhoid fever, diffuse redness increases and becomes marked in two or three hours. There is also some feeling of heat in the eye. Tears flow freely, and there is a slight mucopuru- lent exudate in some cases. The reaction persists about ten hours and then declines, usually disappearing in twenty-four hours. Ham- burger§ confirmed the results of Chantemesse. It is too early to say how useful the reaction is, but it seems to promise aid in diagnosing difficult cases. Differential Diagnosis of the Typhoid and Colon Bacilli—This constitutes the chief perplexity of bacteriologic work with the typhoid bacillus, and is the great bugbear of beginners. A great deal of energy has been expended upon it, a considerable literature has been written about it, and much still remains to be learned by which it may be simplified. Two chief methods are in vogue at present: 1. The serum differentiation. 2. The culture differentiation. * “Boston Medical and Surgical Journal,” 1907. t “Deutsche med. Wochenschrift,” 1907, No. 31, p. 1264. tT See Hamburger, “Jour. Amer. Med. Assoc.,” L, 17, p. 1344, April 25, 1908. § Loc. cit. Differentiation of Typhoid and Colon Bacilli 605 Serum Differentiation—The specific agglutinating action of experimentally prepared serums can be used to differentiate cultures of the colon, paracolon, typhoid, and paratyphoid bacilli, the typhoid bacilli alone exhibiting the specific effect of the typhoid serum. This is a very reliable means of differentiation when the cultures have already been isolated. The method is described under the heading “Agglutination,” in the section devoted to the “Special Phenomenon of Infection and Immunity.”’ Richardson* has found it very convenient to saturate filter-paper with typhoid serum, dry it, cut into o.5 cm. squares, and keep it on hand in the laboratory for the purpose of making this differentiation. To make a test, one of these little squares is dropped in 0.5 cc. of a twenty-four-hour-old bouillon culture of the suspected bacillus and allowed to stand for five minutes. A drop of the fluid placed upon a slide and covered will then show typical agglutinations if the culture be one of the typhoid fever bacillus. In a second mention of this method} he has found its use satisfactory in practice and the paper serviceable after four- teen months’ keeping. The Cultural Differentiation—When the typhoid bacilli are to be isolated from the blood of living patients, they are so likely to be obtained in pure culture that little trouble is experienced. If they are to be isolated from the pus of a posttyphoidal abscess, or from viscera at autopsy, from water suspected of pollution, and especially when they are to be isolated from the intestinal contents, with its tich bacterial flora, the matter becomes progressively complicated. As the colonies of the typhoid bacilli closely resemble those of Bacillus coli, etc., special media have, from time to time, been . devised for the purpose of emphasizing such differences as rapidity of growth, acid production, etc. Thus, Elsnert has suggested the employment of a special medium made as follows: One kilogram of grated potatoes (the small red German potatoes are best) is permitted to macerate over night in 1 liter of water. The juice is carefully pressed out and filtered cold, to get rid of as much starch as possible. The filtrate is boiled and again filtered. The next step is a neutralization, for which Elsner used litmus as an indicator, and added 2.5 to 3 cc. of a {9 normal sodium hydrate solution to each 10 cc. of the juice. Abbott prefers to use phenol- -phthalein as an indicator. The final reaction should be slightly acid. Ten per cent. of gelatin (no peptone or sodium chlorid) is dissolved in the solution, which is boiled, and must then be again neutralized to the same point as before. After filtration the medium receives the addition of 1 per cent. of potassium iodid; then it 1s filled into tubes and sterilized like the ordinary culture-media. When water or feces suspected to contain the typhoid bacillus are mixed in this medium and poured upon plates, no bacteria develop well except the typhoid and colon bacilli. These, however, differ markedly in appearance, for the colon colonies appear of the usual size in twenty-four hours, at which time the typhoid bacillus, if present, will have produced no colonies discoverable by the microscope. It is only after forty-eight hours—long after the colon colonies have become conspicuous—that little colonies of the typhoid bacillus appear as finely granular, small, round, shining, dew-like points, in marked contrast to their large, coarsely granular predecessors. : *“Centralbl. f. Bakt. u. Parasitenk.,” 1897, p. 445- t “Journal of Experimental Medicine,” May, 1898, p. 353, note. } “Zeitschrift fiir Hygiene,” 1895, xxt1, Heft 1; Dec. 6, 1896. 606 Typhoid Fever Unfortunately, many of the small colonies that develop in Elsner’s medium subsequently prove to be those of the colon bacillus, and the method is thus rendered unreliable. Rémy* prefers to make an artificial medium approximating a potato in composition, but without dextrin or glucose. The com- position is as follows: Distilled water.; scccr04 neue vfawnagses eee rs 1000.0 grams ASPalagin.wdseutuars che pees Rie Ee OEE OWES 6.0 ae Oxalic: AGIG ssi 52 iyi eine b SEasiaad beaten 0.5 oe (aCe AGIGs. 5.55 ctewswhe cinerea eno OTe 8? Citric ald iia cee cougars cnneastaskenn neem 4 Org 2? Disodic phosphate...............- 000 eee eee 5.0 ee Magnesium sulphate................ 000000 2.5 uN Potassium sulphate.................02-.00 riage f [e SOdiuny GHGOTIGs «so icc bcied quce ston igre saws wre os 2.0 mA All the salts excepting the magnesium sulphate are powdered in a mortar and introduced into a flask with the distilled water. Thirty grams of Witte’s or Grubler’s peptone are then added and the mixture heated in the autoclave under pressureforone-quarterhour. Assoon as removed, the contents are poured into another flask into which 120 to 150 grams of gelatin had previously been placed. The flask is shaken to dissolve the gelatin, and the contents then made slightly alkaline with soda solution. The mixture is again heated in the autoclave at r10°C., for one-quarter hour, then acidified with a one-half normal solution of sulphuric acid, so that 10 cc. have an acidity neutralized by 0.2 cc. of one-half normal soda solution. This acidity is equal to 0.5 cc. sulphuric acid per liter. After shaking, place the flask in a steam sterilizer for ten minutes, then filter. When filtered, verify the acidity of the medium, correcting if necessary. Finally, add the magnesium sulphate, dissolve, dispense in tubes, and sterilize by the intermittent method. At the moment of using, put into each tube 1 cc. of a 35 per cent. solution of lactose and 0.1 cc. of a 2.5 per cent. solution of carbolic acid. Upon this medium the colonies of the typhoid and colon bacilli show marked differences. The colon colonies are yellowish brown, the typhoid colonies bluish white and small. Fine bubbles of gas from the fermentation of the lactose often occur about the colon colonies. By this method Rémy was able to isolate the typhoid bacillus from the stools in 23 cases which he studied. He believes that the con- stant presence of the typhoid bacillus in the stools of typhoid fever, . and its absence from them under all other conditions, is a far more important and valuable method of diagnosis than even the Widal reaction. Wiirtz{ and Kashida{ make the differential diagnosis by observ- ing the acid production of Bacillus coli in a medium consisting of bouillon containing 1.5 per cent. of agar, 2 per cent. of milk-sugar, I per cent. of urea, and 30 per cent. of tincture of litmus. This is the so-called létmus-lactose-agar-agar. The culture-medium should be blue. When liquefied, inoculated with the colon bacillus, poured into Petri dishes, and stood for from sixteen to eighteen hours in the incubator, the blue color passes off and the culture-medium becomes * Ann, de l’Inst. Pasteur,” Aug., 1900. t “Archiv. de med. Experimentale,” 1892, IV, p. 85. I“Centralbl. f. Bkt. u. Parasitenk, June 24, ae) Bd. xx, Nos. 20 and ar. Differentiation of Typhoid and Colon Bacilli 607 red. Ifa glass rod dipped in hydrochloric acid be held over the dish, vapor of ammonium chlorid is given off. The typhoid bacillus pro-. duces no acid in this medium, and there is consequently no change in its color. Upon plates with colonies of both bacilli, the typhoid colonies produce no change of color, while the colon colonies at once redden the surrounding medium. Rothberger* first employed neutral red for the differentiation of the typhoid and colon bacilli. When grown in fluid media containing it, the colon bacillus produces a yellowish fluorescence, while the typhoid bacillus does not destroy the port-wine color. Savaget and Tronst have made use of the color reaction for the routine detection of the colon bacillus in water. The best adaptation of the method is by Stokes,§ who adds it to the various sugar bouillons in the propor- tion of o.1 gram per liter, and uses the medium in the fermentation tube. The colon bacillus always ferments the sugars and produces a typical color reaction. Hiss|| recommends the use of two special media. The first consists of 5 grams of agar-agar, 80 grams of gelatin, 5 grams of Liebig’s beef-extract, 5 grams of sodium chlorid, and 10 grams of glucose to the liter. The agar is dissolved in the 1000 cc. of water, to which have been added the beef- extract and sodium chlorid. When the agar is completely melted, the gelatin is added and thoroughly dissolved by a few minutes’ boiling. The medium is then titrated to determine its reaction, phenolphthalein being used as the indicator, and enough HCl or NaOH added to bring it to the desired reaction—i.e., a reac- tion indicating 1.5 per cent. of normal acid. To the clear medium add one or two eggs, well beaten in 25 cc. of water; boil for forty-five minutes, and filter through a thin layer of absorbent cotton. Add the glucose after clearing. This medium is used in tubes, in which the cultureis planted by the ordinary puncture. The typhoid bacillus alone has the power of uniformly clouding this medium without showing streaks or gas-bubbles. The second medium is used for plating. It contains 10 grams of agar, 25 grams of gelatin, 5 grams of beef-extract, 5 grams of sodium chlorid, and 10 grams of glucose. The method of preparation is the same as for the tube-me- dium, care always being taken to add the gelatin after the agar is thoroughly melted, so as not to alter this ingredient by prolonged exposure to high tempera- ture. The preparation should never contain less than 2 per cent. of normal acid. Of all the organisms upon which Hiss experimented with this medium, Bacillus typhosus alone displayed the power of producing thread-forming colonies. The colonies of the typhoid bacillus when deep in Hiss’ medium appear small, generally spheric, with a rough, irregular outline, and, by transmitted light, of a vitreous greenish or yellowish-green color. The most characteristic feature con- sists of well-defined filamentous outgrowths, ranging from a single thread to a complete fringe about the colony. The young colonies are, at times, composed solely of threads. The fringing threads generally grow out nearly at right angles to the periphery of the colony. : The colonies of the colon bacillus appear, on the average, larger than those of the typhoid bacillus; they are spheric or of a whetstone form, and by transmitted light are darker, more opaque, and less refractive than the typhoid colonies. By reflected light they are pale yellow to the unaided eye. Surface colonies are large, round, irregularly spreading, and are brown or yel- lowish-brown in color. Hiss claims that by the use of these media the typhoid bacillus can readily be detected in typhoid stools. *“Centralbl. f. Bakt.,” 1893, p. 187. t+ “Journal of Hygiene,” 1901, 1, p. 437. TIbid., 1902, 1, p. 437. § “Jour. of Infectious Diseases,” 1904, I, p. 341- || “Jour. of Experimental Medicine,” Nov., 1897, vol. 11, No. 6. 608 Typhoid Fever Piorkowski* recommends a culture-medium composed of urine two days old, to which 0.5 per cent. of peptone and 3.3 per cent. of gelatin have been added. Colonies of the typhoid bacillus appear radiated and filamentous; those of the colon bacillus, round, yellow- ish, and sharply defined at the edges. The cultures should be kept at 22°C., and the colonies should appear in twenty-four hours. Adami and Chapin* have suggested a method for the isolation of typhoid bacilli from water, in which use is made of the agglutination of the bacilli by immune serum. Two quart bottles (Winchester quarts) are carefully sterilized and filled with the suspected water with an addition of 25 cc. of nutrient broth and incubated for eighteen to twenty-four hours at 37°C. By this time the typhoid bacillus grows abundantly in spite of the small amount of nourishment the water contains. At the end of the incubation, ro cc. of the fluid is filled into each of a number of long narrow (7 mm.) test-tubes made by sealing a glass tube one-half meter long at one end. About 1 inch from the bottom the tube is filed completely round so as to break easily at that point. The different tubes next receive additions of typhoid immune serum sufficient to make the dilutions 1:60, 1:100, 1:150, and 1:200. If typhoid bacilli are present, within a quarter of an hour beginning agglutination can be seen, and by the end of two to five hours flocculent masses collect at the bottom of the tube, forming a flocculent precipitate. The next procedure should be with the tube showing agglutination with the greatest dilu- tion, as the more concentrated preparations carry down not only the typhoid bacilli, but also closely related organisms. After the sedimentation of the agglu- tinated bacilli is complete, the tube is broken at the file mark, and the sediment contained in the short tube washed with two or three changes of distilled water, being allowed to settle each time. This removes many of the organisms not agglutinated. A loopful of the washed sediment is transferred to a tube of nutrient broth, and finally from this tube plate cultures are made upon Elsner’s or Hiss’ media. A culture-medium for isolating the typhoid bacillus from feces is recommended by Drigalski-Conradit and by Petkowitsch.{ It is made as follows: Horse-meat infusion (3 pounds of horse meat to 2 liters of Water) <.c ces. can cce ccd Snes one ae aes 2 liters Witte’s peptone........ eee eee eee 20 grams INUEFOSES «0 2 aitnitee (uss selalid des eal ache aohene ee eatavans 20 grams Sodium chlorid..... 0.0... cece eee Io grams A Galea Par cs .02's'es ei ches a adegraees Sawn ye epee 60 grams Litmus solution (Kubel and Tiemann)........... 260 cc. . TACCOSE sins cho ts te irershi deere’ s eoeteiale-cmpanege aan abe 30 grams Crystal-violet solution (o.o1 percent.)........... 20 CC. Before adding the crystal-violet solution render feebly alkaline to litmus (about 0.04 per cent. of pure soda). Colon colonies upon this medium appear in fourteen to sixteen hours to be red and opaque. Typhoid colonies blue or violet, transparent and drop-like. Beckman§ modifies the preparation, making it as follows: * “ Berliner klin. Wochenschrift,” Feb. 13, 1899. t ‘Zeitschrift f. Hygiene,” Bd. xxrx. Tt “Centralbl. f. Bakt.,” etc., May 28, 1904, Bd. xxxv1, No. 2, p. 304. § See F. F. Wesbrook, “Jour. Infectious Diseases,” May, 1905, Supplement, No. 1, p. 319. Differentiation of Typhoid and Colon Bacilli 609 (a) Add x liter of water to 680 grams of finely chopped lean beef and place in thecoldfortwenty-fourhours. Expressthejuiceand make up to 1 liter. Coagu- late the albumin, either by boiling for ten minutes or by heating to 120°C, in the autoclave. Filter. Add 10 grams of Witte’s peptone, 10 grams of nutrose, and 5 grams of sodium chlorid. Heat in the autoclave at a temperature of 320°C. for thirty minutes, or’boil vigorously for fifteen minutes. Render slightly alkaline to litmus paper. Filter. Add 30 grams of agar. Heat in the autoclave at a temperature of 120°C. for one-half hour, or heat over the gas-flame until the agar is dissolved. Render slightly alkaline to litmus paper while hot, if necessary. Filter through glass wool into a sterile vessel. : (b) To 130 cc. of litmus solution (Kubel and Tiemann’s) add 15 grams of chemically pure lactose. Boil for ten minutes. (c) Mix (a) and (b) while hot. Render slightly alkaline to litmus, if necessary. To the mixture add 2 cc. of hot sterile solution of 10 per cent. sodium hydrate in distilled water and to cc. of a fresh solution of Héchst’s crystal violet (0.1 gram of crystal violet to roo cc. of sterile water). The medium is now poured into Petri dishes and is of a deep purple color. So ;--: much water of condensation forms on the © | solidified surface thatitisan advantagetouse | porous clay covers (Hill) for the Petri dishes instead of the ordinary glass covers. The medium keeps well but dries up rapidly. A very ingenious method of isolat- | ing the typhoid.and colon bacilli from — drinking water has been suggested by — Starkey,* who uses a tubular laby- | rinth of glass filled with ordinary bouil- * lon containing 0.05 per cent. of car- bolic acid, or, as recommended by Somers,{ Pariette’s bouillon. The original formula for the latter medium is as follows: 1. Measure out pure hydrochloric acid, 4.cc., and add it to carbolic acid __ : solution (5 per cent.), roo cc. Fig. 253.—Starkey’s labyrinth as Allow the solution to stand at least modified by Somers. a few days before use. 2. This solution is added in quantities of 0.1, 0.2, and 0.3 cc. (delivered by means of a sterile graduated pipette to tubes, each containing 10 cc. of previously sterilized nutrient bouillon). 3. Incubate at 37°C. for forty-eight hours to eliminate contaminated tubes. The restraining medium prevents the ready growth of most organisms except colon and typhoid bacilli. The anaérobic conditions prevent the development of aérobic organisms which form the majority of bacteria with which one comes in contact in ordinary bacteriological examinations. The typhoid bacillus, being more motile than the colon, travels more quickly through the coils of the labyrinth and first arrives at its end, where it can be found in pure or nearly pure cul- ture after about forty-eight hours. Somers has improved the labyrinth by bending it in a circular *“ Amer. Jour. Med. Sci.,” July, 1906, cxxxtt, No. 1, No. 412, p. 109. + “Trans. Phila. Path. Soc.,”’ 1906. 39 610 Typhoid Fever form, so that it can stand alone, and by adapting its size to the Novy jar, so that satisfactory anaérobic conditions can easily be attained. Hesse* has recommended the following medium: Agar agar necnils aulonwenalenelas 5 grams (4.5 grams absolutely dry). Witte’s peptone.............05 Io fs Liebig’s beef-extract........... 5 ef Sodium chlorid............... 8.5 : Distilled water............2.05 1000 Dissolve the agar-agar in 500 cc. of the water over a free flame, making up the loss by evaporation. Dissolve the other ingredient, in the remaining 500 cc. of water, heat until dissolved, replacing the loss by evaporation. Pour the two solutions together, heat for thirty minutes and add distilled water to replace loss by evaporation. Filter through cotton until clear. Adjust reaction to 1 per cent. acidity. Tube—1occ.toatube. Sterilize in the autoclave. The medium is used for plating. The material containing the micro-organisms must be so dilute that only a few colonies will develop upon the plates. The typhoid colonies greatly outgrow the colon colonies and may attain to a diameter of several centimeters. They show a small opaque center and an opalescent body and appear circular. Capaldi recommends the following medium for plating typhoid and colon colonies: Witte’s peptone... 62.25) cin denase teen saa eaeaes 20 grams Geel acs Pat syne ach eeeaey oetcaesamear cake, atte eae PANS Io ‘f AAT AP AT eo sacs scatters x geal mind Sn ai Seeg ne ehtonls 20“ Dextrose or mannite..................00000005 to (“ Sodium chlorid................000000000 00s ig NS Potassium chlorid.................000 cece eee Be oe Distilled Waterie.e sje cccucie cage geyaces a ecaio Nad wna oe tooo Sf Dissolve the agar in 500 cc. of water, the other ingredients in the other 500 cc. of water. Pour together, add 10 cc. of NaOH, filter, and tube. Upon this medium the typhoid colonies are small, glistening, bluish, and translucent. Colon colonies are larger, opaque, and brownish. Endot recommends the employment of the following medium upon which colonies of the typhoid bacillus grow large and remain colorless while those of the colon bacillus remain small and red: Iooo cc. of meat infusion. 30 grams of agar-agar. ro grams of peptone (Witte’s). 5 grams of sodium chlorid. Neutralize and clear by filtration, then add 10 cc. of a 10 per cent. solution of NaOH to alkalinize, 10 grams of chemically pure lactose and 5 cc. of a filtered, saturated, alcoholic solution of fuchsin. Next add 25 cc. of a ro per cent. sodium sulphite solution, by which the intense red given by thefuchsinis entirely bleached by the time the agar-agar is cold. After adding the necessary reagents and while ono and perhaps red, tube the medium. . The tubes should be kept in the ark, * “Zeitschrift ftir Hygiene,” 1908, Lvi, 441. { ‘Zeitschrift fiir Hygiene,” 1896, xx1m, 475. t“Centralbl. f. Bakt.,” etc., 1904, xxv. Differentiation of Typhoid and Colon Bacilli 611 - Léffler* has found malachite green a very useful adjunct to our means of differentiating the typhoid from other similar bacilli. For the purpose, 2}4 to 3 per cent. of a 2 per cent. solution of malachite green are added to the culture-medium. The preparation given the preference con- sists of 1 pound of meat macerated in 1 liter of water, neutralized with potassium, with the addition of 2 per cent. of peptone, 5 per cent. of lactose, r per cent. of glucose, 0.5 per cent. of sodium sulphate, 2 per cent. of nitrate of potassium, and 3 per cent. of a 2 per cent. solution of malachite green. In the medium the ordinary cocci and bacilli do not grow, Girt- ner’s bacillus and the paratyphoid bacillus 6 leave the medium clear, but grow as a deposit at the bottom of the tube; the typhoid bacillus destroys the green. If agar-agar be added, the colonies are sur- rounded by a clear yellow zone. The colon and other organisms grow slowly if at all. Not many workers were satisfied with the results obtained by malachite green, nor were the results obtained uniform. A careful study of the subject was made by Peabody and Pratt,t who found great differences in the quality and reactions of different malachite greens in the market. That with which Léffler worked was com- mercially known as “120.” They obtained three samples of this dye, which varied in acidity between wide margins (0.2-1.0). Experimenting with the different preparations, they found that the least acid was the most useful preparation. The success of the method, therefore, depends upon the adjustment of the concentra- tion of the dye to the reaction of the medium. When this is done, malachite green becomes a valuable adjunct to specific differentia- tion. Their studies of the media led Peabody and Pratt to the inven- tion of a new method of isolating typhoid bacilli from the feces. Instead of employing malachite green agar-agar directly for this purpose, they first employ malachite green bouillon as an “enrich- ing” culture, and after eighteen to twenty-four hours’ growth in the incubator inoculate one or two large (20 cm. diameter) Drigalski- Conradi plates, from which the colonies can subsequently be picked out. . Bile salts were first employed in culture-media by Limbourg{ and have been more or less popular ever since, though for differentiation of typhoid and colon bacilli they cause occasional disappointment. Buxton and Coleman§ prepare a medium composed of: Ox=bil@ sss ci cided ca sae d Gold Baw SASS ORE E OTE TR goo cc GIy. Cer itis 03 jc cones nee eelgieFatee homes kd Suda HES 100 cc Peptone€ yc: cccn yond eden dae Geet AF Ok anes 20 grams This was placed in a number of 100 cc. flasks, sterilized in the Arnold sterilizer, and employed chiefly for blood-culture. The typhoid bacillus grows well in it. *“Boston Med. and Surg. Journal,” Feb. 13, 1908, CLVII, p. 213. 1 ‘Zeitschrift f. physiol. Chemie,” 1889, II, p. 196. T “Inst. hyg. Univers. Griefswald,” see “Bull. Inst. Past.,” 1v, No. 9, May 15, 1906, p. 393. § “Journal of Infectious Diseases,”’ 1909, v1, No. 2, p. 194. 612 Typhoid Fever Jackson* prepares a medium for water examination when typhoid and colon bacilli are suspected. It consists of undiluted ox-bile to which 1 per cent. of peptone and x per cent. of lactose are added. It is filled into fermentation-tubes of 40 cc. capacity and sterilized in the Arnold apparatus. If fresh ox-bile cannot be secured, an 11 per cent. solution of dry ox-bile can be made; ro cc. of suspected water or milk are planted in the tubes of this medium. The contained micro-organisms grow rapidly, typhoid bacilli outgrowing all others, and not fermenting the sugar; rapid fermentation and copious gas-formation take place if colon bacilli are present. An excellent medium suggested by MacConkeyT has the following composition: Aare sd vacua bad aave dns dee ay Ree RRS Eee I.5 grams Sodium taurocholate...............0.00000 eee o.5 gram PCPLONG i 3554 sea ek eed eye ed Mea taetaw aud es 2.0 grams Water a ciaee doeay a le aes Raee, i meaudl subareas aublaned 100.0 CC. It is boiled, clarified, and filtered as usual, then receives an addition of 1.0 gram of lactose, is tubed, and then sterilized three times on successive days. For determining fermentation by colon bacilli the same investiga- tor advises a broth composed of: Sodium taurocholate (pure)................04. 0.5 gram PEDtON Gh 5.5 cpnscrned av aun ie aaaiione Game wa Oe 2.0 grams G)UGOSEt cepeeioe sau Gee ace obs eo Gee ees o.5 gram Waters s.4)) os Sainaikiaagacisee seme Gutaecoraeanae 100.0 cc Boil, filter, add sufficient neutral litmus, fill into fermentation-tubes, and steril- ize at 100°C. Colon colonies appear red; typhoid, blue. In a careful study of the bile-salt media MacConkeyf points out an error, first discovered by Theobald Smith, that depends upon the alkali production of the colon bacillus in the absence of sugar. If too little sugar be added to the medium, the alkali production masks the acid production unless the oxygen be removed, and red colonies of the colon bacillus grown upon the medium may in time turn dis- tinctly blue. It becomes obvious, therefore, that the medium should be as neutral as possible to the indicator used. After trial he found neutral red preferable to ‘litmus, and makes the medium as follows: x. A stock solution is made: Sodium taurocholate (commercial from ox-bile and neutral to neutral red)... 0... ccc eee o.5 per cent. Peptone (Witte’s) io: cscs sce siecedpaueaeeeeee evs 2.0 per cent. Water (distilled or tap).......... ccc cece cee 100.0 CC. (As calcium 0.03 per cent. is favorable to the growth of the organisms, it should be added if distilled water is used.) The ingredients should be mixed, steamed in a steam sterilizer for one to two hours, filtered while hot, allowed to stand twenty-four to forty-eight hours, then filtered cold through paper. A clear solution should then result, which will keep indefinitely under proper conditions. The various bile-salt media are prepared * “Biological Studies of the Pupils of W. T. Sedgwick,” 1906, University of Chicago Press. t “The Thompson-Yates Laboratory Reports,” II, p. 151. } ‘Journal of Hygiene,” 1908, vill, p. 322. Bacilli Resembling the Typhoid Bacillus 613 from this stock solution by adding glucose, 0.5 per cent.; lactose, 1 per cent.; cane-sugar, 1 per cent.; dulcit, o.5 per cent.; adonit, 0.5 per cent., or inulin, 1 per cent.; and neutral red (i per cent. solution), 0.25 per cent., distributing into fermentation-tubes and sterilizing in the steamer for fifteen minutes on each of three successive days. Bile-salt agar-agar is made by dissolving 2 per cent. of agar-agar in the stock fluid, either in the steamer or in the autoclave. The mixture is cleared with an egg, filtered, neutral red added in the same proportion as for the broth, and dis- tributed into flasks in quantities of 80 cc. When required for use, the fer- mentable substance is added to the agar in the flask, and the whole placed in a water-bath or steamer (care must be taken not to heat either the fluid or solid medium beyond 100°C.). When melted, the agar preparation is poured into Petri dishes, allowed to solidify, and then dried in an incubator or warm room, the plate being placed upside down with the bottom detached and propped up on the edge of the cover. It is necessary that the surface of the agar-agar should not be too wet, lest the colonies become confluent, nor too dry, lest the growth be stunted. Inoculations are made by placing a loopful of the material to be examined on the center of one plate, and rubbed over the surface with a bent glass rod; the same rod, without recharging, being used to inoculate the surface of two other plates. The plates are then incubated upside down. The colonies of the colon bacillus appear yellow. : BAcILLI RESEMBLING THE TyPHOID BACILLUS Bacillus typhosus is one of a group of organisms possessing a con- siderable number of common characteristics, each member of which, however, can be differentiated by some one fairly well-marked pecu- liarity. At one end of the series is the typhoid bacillus, which we conceive to be devoid of the power to liquefy gelatin, ferment sugars, form indol, coagulate milk, or progressively form acids. At the other: extreme stands Bacillus coli, an organism whose typical representa- tives coagulate milk, form indol, ferment dextrose, lactose, sacchar- ose, and maltose with the formation of hydrogen and carbon dioxid in the proportion of sn . CO, I Between these extremes are numerous organisms known as ‘“‘inter- mediates.” It is usually a simple matter to differentiate these forms from the typical species at the two ends of the series, but it is quite difficult to differentiate them from one another. Whether they are of sufficient importance to make it worth while to pay much atten- tion to them is, as yet, uncertain; and, indeed, we do not know whether they are to be regarded as variations from the type species or separate and distinct organisms. The fact that some of them are associated with serious and fatal disorders—paracolon bacillus and bacillus of psittacosis—proves them, at least, to be important. Buxton* summarizes the main points of difference as follows: B. coli com- munis. Intermediates. B.typhosus Coagulation of milk........... + =] i Production of indol........... + = = Fermentation of lactose with PAS i hun aint oourand ebawes oe = Se Fermentation of glucose with BAS iiyscoh aonne con dedes nw ener + se = - + * “Journal of Medical Research,” vol. vit, No. 1, June, 1902, p. 201. Agglutination by typhoid serum. 614 Bacilli Resembling the Typhoid Bacillus The characteristics of the three groups as shown by the fermenta- tion-test stand thus:* Gas upon Gas upon Gas upon dextrose. lactose. saccharose. Bacillus typhosus ............. = = = Intermediates................ + = = BaciJlus coli communis........ + + as Bacillus coli communior....... + + + Buxton finds those pathogenic for man clinically divisible into three groups, as follows: (a) The Meat-poisoning Group —This includes Bacillus enteritidis of Gartner and others. The symptoms begin soon after eating the poisonous meat, and are toxic. Bacilli quickly invade the body. The illness continues four or five days, after which recovery is quick. In a few cases death has occurred on the second or third day. (b) The Pneumonic or Psittacosis Group.—Psittacosis is an epi- demic infectious disease with pneumonic symptoms and a high mortality. Its origin has been traced to diseased parrots, and from them Nocard isolated Bacillus psittacosis, supposed to be the cause of the disease in man. Later epidemics were studied by Achard and Bensaude. (c) The Typhoidal Group.—The organisms to be included in this group occasion symptoms closely resembling typhoid fever, though they differ biologically from the typhoid bacillus, and do not agglu- tinate with typhoid serums. It is thus evident that some of the intermediates occasion symp- toms resembling typhoid fever, while others occasion symptoms widely differing from it. It is suggested that to the former the term paratyphoid bacilli be applied, while the latter are known as paracolon bacilli. Although Achard and Bensaude,t and Johnson, Hewlett, and Longcopet have studied the paratyphoid infections, Gwyn,§ Lib- man, || and others the paracolon bacilli, and Cushing** and Durhamf{ have made comparative studies of the members of the group, it is still too soon to regard the knowledge attained sufficient to warrant particular mention of the various intermediate and related organ- isms in a work of this kind. In the following pages, therefore, attention will be devoted only to the more important organisms of the group. * Hiss and Zinsser, “‘Text-book of Bacteriology,” 1910, p. 429. t ‘Soc. Med.,” Nov., 1896. eT eee ace t “Amer. Jour. Med. Sci.,” Aug., 1902. § “Johns Hopkins Bulletin,” 1898, vol. rx. || ‘Journal of Medical Research,” 1902, p. 168. **<< 1000 ' (Itzerott and Niemann.) resemble diplococci. They stain by ordinary methods, but not by Gram’s method. They are motile and have flagella like the typhoid and colon bacilli. They form no spores. Upon gelatin and agar-agar, circular colonies with a dark nucleus surrounded by a transparent zone are formed. In gelatin punctures the bacilli grow all along the line of puncture and form a surface growth with concen- tric markings. The gelatin is not liquefied. The bacilli grow readily upon agar and on potato, but without characteristic appearances. In bouillon a diffuse turbidity occurs, with floating and suspended flakes. Milk is not altered. Pathogenesis.—The bacillus is fatal to mice, guinea-pigs, rabbits, hares, and other rodents in about twenty days after inoculation. At theseatof inoculation an abscess develops, the neighboring lymphatic glands enlarge and caseate, and nodules resembling tubercles form in the internal organs. Similar bacilli studied by Pfeiffer were isolated from a horse supposed to have glanders. * “Bacillére tuberculose, u. s. w.,” Leipzig, 1889. { “Archiv de Physiol. norm. et. Path.,” 1883 and 1884. f “Virchow’s Archiv,” Bd. cr. ee de l’Inst. Pasteur,” 1887. || ‘“Compte-rendu de l’Acad. des Sci.,” Paris, t. cv. CHAPTER XXX LEPROSY Bacittus Lepr& (HANSEN)* General Characteristics.—A non-motile, non-flagellate, non-sporogenous, chromogenic, non-liquefying, non-aérogenic, distinctly aérobic, parasitic and highly pathogenic, acid-resisting bacillus, staining by Gram’s method, and culti- vable upon specially prepared artificial media. It does not form indol, or acidu- late or coagulate milk. Leprosy very early received attention and study. Moses in- cluded in the laws to the people of Israel rules for its diagnosis, for the isolation of the sufferers, for the determination of recovery, and for the sacrificial observances to be fulfilled before the convalescent could once more mingle with his people. The Bible is replete with miracles wrought upon lepers, and during the times of biblical tradition it seems to have been an exceedingly common and malig- nant disease. Many of the diseases called leprosy in the Bible were, however, in all probability, less important parasitic skin affections. Distribution.—At the present time, although we hear very little about it in the northern United States, leprosy is a widespread dis- ease and exists much the same as it did several thousand years ago in Palestine, Syria, Egypt, and the adjacent countries, and is common in China, Japan, and India. South Africa has many cases, and Europe, especially Norway, Sweden, and parts of the Mediterranean coast, a considerable number. In certain islands, especially the Sandwich and Philippine Islands, it is endemic. In the United States the disease is uncommon, the Southern States and Gulf coast being chiefly affected. A commission of the Marine-Hospital Service, formed for the purpose of investigating the prevalence of leprosy, in 1902 re- ported 278 existing cases in the United States. Of these, 155 occurred in the State of Louisiana. The other States with numerous cases were California, 24; Florida, 24; Minnesota, 20; and North Dakota, 16. No other State had more than 7 (New York). Of the cases, 145 were American born, 120 foreign born, the remainder uncertain. Etiology.—The cause of leprosy is, without doubt, the lepra bacillus, discovered by Hansen in 1879. Morphology.—The bacillus is about the same size as the tubercle bacillus. Its protoplasm commonly presents open spaces of frac- * “Virchow’s Archives,” 1879. 695 696 Leprosy tures, giving it a beaded appearance, like the tubercle bacillus. It occurs singly or in irregular groups. There is no characteristic grouping and filaments are unknown. It is not motile and has no flagella and no spores. Duval found that the cultivated bacilli are longer, more curved, and show a greater irregularity in the distribution of the chromatin than those in the tissues where they are short, slender, and slightly curved. In artificial cultures there is a delicate filamentous ar- rangement of the bacilli, especially where they have become ac- customed to a saprophytic existence. They often contain distinct metachromatic granules analogous to those met with in certain forms of the diphtheria bacillus. They are quite pleomorphous, and in the same culture all forms occur, from solidly staining coccoid Fig. 282.—Lepra bacilli. Smear from a lepra node stained with carbol-fuchsin (Kolle and Wassermann). shapes to slender slightly curved filaments, with numerous chromatic segments and occasional metachromatic granules. Sometimes the organisms are pointed at the ends. Czaplewski found that the lepra bacilli in his cultures colored uniformly when young, but were invariably granular when old. The more rapidly the organism grew, the more slender it appeared. ‘Staining.—It stains in very much the same way as the tubercle bacillus, but permits of a more ready penetration of the stain, so that the ordinary aqueous solutions of the anilin dyes color it quite readily. The property of retaining the color in the presence of the mineral acids also characterizes the lepra bacillus, and the methods of Ehrlich, Gabbet, and Unna for staining the tubercle bacillus can be used for its detection. It stains well by Gram’s method and by Weigert’s modification of it, by which beautiful tissue specimens can be prepared. Cultivation—Many endeavors have been made to cultivate Cultivation 697 this bacillus upon artificially prepared media, but in 1903 Hansen,* who discovered the organism, declared that no one had yet culti- vated it. ; Bordoni-Uffreduzzit was able to cultivate a bacillus which par- took of the staining peculiarities of the lepra bacillus as it appears in the tissues, but differed in morphology. Czaplewskit confirmed the work of Bordoni-Uffredozzi, and Fig. 283.—Section of one of the nodules from the patient shown in Fig. 28s, stained by the Weigert-Gram method to show the lepra bacilli scattered through oe tissue and inclosed in the large vacuolated “‘lepra-cells.”” Magnified 1000 lameters. described a bacillus supposed to be the lepra bacillus, which he succeeded in cultivating from the nasal secretions of a leper. The bacillus was isolated upon a culture-medium consisting of glycerinized serum without the addition of salt, peptone, or sugar. The mixture was poured into Petri dishes, coagulated by heat, and sterilized by the intermittent method. * Kolle and Wassermann’s “Handbuch der pathogenen Mikrodrganismen,”’ I, p. 184, 1903. { “Zeitschrift f. Hygiene,” etc., 1884, 111. t“Centralbl. f. Bakt. und Parasitenk.,” Jan. 31, 1898, vol. xxm1, Nos. 3 and 4, P. 97. 698 Leprosy The secretion, being rich in lepra bacilli, was taken up with a platinum wire and inoculated upon the culture-medium by a series of linear strokes. The dishes were then sealed with paraffin and kept in the incubating oven at 37°C. Numerous colonies, chiefly of Staphylococcus aureus and the bacillus of Friedlander, developed, and in addition a number of colonies, composed of slender bacilli about the size and form of the lepra bacillus. These colonies were grayish yellow, humped i in the middle, 1 to 2 mm. in diameter, irregularly rounded, and uneven at the edges. They were firm and could be entirely inverted with the platinum wire, although the consistence was crumbly. They were excavated on the under side. The colonies that formed upon agar-agar were much like those described by Bordoni-Uffreduzzi, and appeared as isolated, grayish, rounded flakes, thicker in the center than at the edges, and -char- acterized by an irregular serrated border from which a fine irregular network extended upon the medium. These projections consisted of bundles of the bacilli. When a transfer was made from one of these colonies to fresh media, the growth became apparent in a few days and assumed a band-like form, with a plateau-like elevation in the center. The bacillus thus isolated grew with moderate rapidity upon all the ordinary culture-media except potato. Upon blood-serum the growth was more luxuriant and fluid than upon the solid media. Upon coagulated serum the growth was somewhat dry and elevated, and was frequently so loosely attached to the surface of the medium as to be readily lifted up by the platinum wire. The growth was especially luxuriant upon sheep’s blood-serum to which 5 per cent. of glycerin was added. The growth upon the Léffler mixture was also luxuriant. Upon agar-agar the growth was more meager; it was more luxuriant upon glycerin agar-agar than upon plain agar-agar, the bacterial mass appearing grayish and flatter than upon blood- serum. The growth never extended to the water of condensation to form a floating layer. The bacillus developed well upon gelatin after it had grown arti- ficially for a number of generations and become accustomed to a saprophytic existence. Upon the surface of gelatin the growth was in general, similar to that upon agar-agar. In puncture cultures most of the growth occurred upon the surface to form a whitish, grayish, or yellowish wrinkled layer. Below the surface of the gelatin the growth occurred as a thick, granular column. The medium was not liquefied. In bouillon, growth occurred only at the bottom of the tube inthe form of a powdery sediment. Cultivation 699 Spronck* believed that he had successfully cultivated the organ- ism upon glycerinized, neutralized potatoes, first seeing the growth after the lapse of ten days. Cultures thus prepared were found to be agglutinated by the blood-serum of lepra cases, and he recom- mended the agglutination test for the diagnosis of obscure cases of the disease. Ducrey claimed to have cultivated the lepra bacillus in grape- sugar, agar, and in bouillon zz vacuo. His results need confirmation. Rostt claimed to have isolated and cultivated the lepra bacillus upon media free from sodium chlorid. The technic of his method is thus described by Rudolph:t “Small lumps of pumice stone are washed and then dried in the sun, and then allowed to absorb a mixture of 1 ounce of meat extract and 2 ounces of water. This pumice stone is then placed in wide-mouthed bottles and placed in the auto- clave. Each bottle is provided with a stopper through which pass two tubes, the one tube opening into the autoclave and reaching nearly to the bottom of the bottle,.and the other leading from the top of the bottle into a condenser adjoining. When the cover of the autoclave is adjusted and the steam admitted, then in the case of each bottle, the steam passes by the one tube to the bottom of the bottle, and rising through the pieces of pumice stone, the steam, carrying with it the volatile constituents of the meat-extract, reaches the condenser by the second tube. The vapor in the condenser yields the salt-free nutrient medium in the proportion of 2 liters to each ounce of meat-extract originally used. The medium is collected from the condenser in sterilized Pasteur flasks which are kept plunged during the process in a freezing mixture in order to condense some of the volatile alkaloids from the beef that would otherwise escape. The nutrient fluid is now inoculated with the bacillus of leprosy and the flasks kept at 37°C. for from four to six weeks;. at the end of this period when examined the flasks should present a turbid appearance with a stringy white deposit.” Clegg§ announced the cultivation of lepra bacilli from human leprous tissue in symbiosis with ameba and other bacteria. The organisms thus cultured he kept alive in subcultures. The method devised by Clegg was the starting-point of a more extended re- search by Duval,|| who, after confirming the work of Clegg, found that the bacillus could be cultivated directly from human lesions upon culture-media containing tryptophan, without the symbiotic ameba or other bacteria. The initial culture was somewhat difficult to secure, but once the bacilli grew, transplantation was easily and successfully carried on for indefinite generations. He further found that the lepra bacillus could be successfully started to grow upon the ordinary laboratory media if bits of leprous tissue were placed upon them, and at the same time some symbiotic organism, such as the colon, typhoid, proteus, or other bacilli, added. Or if the tissue were already contaminated the lepra bacilli proceeded to multiply. Duval interprets this to mean that the lepra bacillus is unable to effect the destruction of the albumin molecule alone, and *“Weekblad van het Nederlandsch Tijdschrift voor geneeskunde,” Deel n, 1898, No. 14; abstract ‘‘Centralbl. f. Bakt.,’”’ etc., 1899, XXV, DP. 257. + “Brit. Med. Jour.,” Feb. 22, 1905, and “Indian Med. Gazette,” 1905. Tt “Medicine,” March, 1905, P- 175- § “Philippine Journal ‘of Science,” 1909, IV, 403. || “Journal of Experimental Medicine,” 1910, x11, 649; 1911, xin, 365. 700 Leprosy hence explains the advantage of adding tryptophan. The medium most successfully employed by Duval was as follows: ; _ “Egg-albumen or human blood-serum is poured into sterile Petri dishes and inspissated for three hours at 70°C. The excised leprous nodule is then cut into’ thin slices, 2 to 4 mm. in breadth and 0.5 to 1 mm. in thickness, which are dis-: tributed over the surface of the coagulated albumin. By means ofa pipette the medium thus seeded with bits of tissue is bathed in a 1 per cent. sterile solution of trypsin, care being taken not to submerge the pieces of leprous tissue. Sufficient fluid is added to moisten thoroughly the surface of the medium. The Petri dishes are now placed in a moist chamber at 37°C., and allowed to incubate for a week or ten days. They are removed from the plates from time to time, as evaporation necessitates, for the addition of more trypsin. It will be noted that after a week or ten days the tissue bits are partially sunken below the surface of the medium and are softened to a thick, creamy consistence, fragments of which are readily removed with a platinum needle. On microscopic examination of this material it is noted that the leprosy bacilli have increased to enormous numbers and scarcely a trace of the tissue remains. Separate lepra bacillus colonies are also discernible on and around the softened tissue masses. . . . The colonies are at first gray- ish white, but after several days they assume a distinct orange-yellow tint. . Subcultures may be obtained by transferring portions of the growth to a second series of plates or to slanted culture-tubes that contain the special albumin-trypsin medium. After the third or fourth generation the bacilli may be grown without. difficulty upon glycerinated serum agar prepared in the following manner: “Twenty grams of agar, 3 gm. of sodium chlorid, 30 cc. of glycerin, and 500 cc. of distilled water are thoroughly mixed, clarified, and sterilized in the usual way. To tubes containing 10 cc. of this material is added in proper proportion a solution of unheated turtle muscle infusion. Five hundred grams of turtle muscle are cut into fine pieces and placed ina flask with soo cc. of distilled water. This is kept in the ice-chest for forty-eight hours and then filtered through gauze to remove the tissue. The filtrate is then passed through a Berkefeld filter for. purposes of sterilization. By means of a sterile pipet, 5 cc. of the muscle filtrate is added to the agar mixture which has been melted and cooled to 42°C. The tubes are now thoroughly agitated and allowed to solidify in the slanted position. “This medium is perfectly clear or of a light amber color, and admirably suited to the cultivation of the Bacillus lepra, once the initial culture has been started. Growth is luxuriant and reaches its maximum in forty-eight to sixty hours. On the surface of this medium the growth is moist and orange-yellow in color, while in the water of coridensation, though growth apparently has not occurred, the detached bacilli collect in the dependent parts in the form of feathery masses without clouding the fluid. “Ordinary nutrient agar may be used with trypsin as a plating medium instead of the inspissated serum where bits of tissue are employed. With the addition of x per cent. of tryptophan it answers every purpose, whether the bacilli are planted with tissue or alone. It also serves to start multiplication of lepra bacilli that are contaminated at the time of plating. In the latter case the medium is “surface seeded’ with an emulsion of the tissue juices in the same manner as in preparing ‘streak’ plates. The leprosy colonies in the thinner parts of the loop track are well separated and easily distinguished from those of other species by their color and by their appearance only after two to five days. “Tn using an agar medium it is well to leave out the peptone and to titrate the reaction to 1.5 per cent. alkaline in order to prevent too profuse growth of the associated bacteria; besides, an alkaline medium seems best adapted for the multiplication of the lepra bacillus. “Bacillus lepre will also grow on the various blood-agar media once they are accustomed to artificial conditions. The Novy-McNeal agar for the cultivation of trypanosomes gives a luxuriant growth of the organism if 2 per cent. glycerin has been added; without the glycerin, growth is very scant. Fluid media are not suited for the artificial cultivation of leprosy bacilli unless they are kept upon the surface. Like the tubercle bacilli they require abundant oxygen... . “Ordinarily the growth of Bacillus lepre is very moist, and in this respect unlike that of Bacillus tuberculosis, except possibly the avian stain. Sometimes when the medium is devoid of water of condensation, the growth is dry and occa- sionally wrinkled, though it is easily removed from the surface of the medium Pathogenesis 7OI “The chromogenic property of lepra cultures is a constant and characteristic feature of the rapidly growing strains. The color varies in the degree of intensity depending upon the medium employed. If glycerinated agar (without peptone) is used, the colonies are faint lemon, while on inspissated blood-serum they are deep orange. It is noteworthy that the growth in the tissues and in the first dozen or so generations on artificial media is entirely without pigment.” Although each of the workers upon leprosy has begun by asserting that he had certainly cultivated the specific organism, a time comes when a more extended acquaintance with the bacteriology of the disease seems to cause him to doubt the results of his own work. This is particularly true of this work of Duval, which was prosecuted with enthusiasm, carried conviction with it, and then was partially repudiated by its author, for in the discussion before the 17th Inter- national Medical Congress in London in 1913, Duval* is reported as saying that “he knew less of the bacteriology of leprosy now than he _ did some four years ago. He had made several mistakes, had ' stated openly that he had cultivated the leprosy bacillus, but now admitted frankly that he was mistaken.” The interesting question that awaits settlement now seems to be, if these bacilli, and specially the bacillus of Duval, are not Bacillus lepre, what are they? What relation do they bear to leprosy? Pathogenesis——Melcher and Ortmann* introduced fragments of lepra nodules into the anterior chambers of the eyes of rabbits, and observed the death of the animals after some months, with what they considered to be typical leprous lesions of all the viscera, especially the cecum; but the later careful experiments of Tashiro show that most of the lower animals are entirely insusceptible to infection with the lepra bacillus, and that when they are inoculated the bacilli persistently diminish in numbers and finally disappear. Nicollet found it possible to infect monkeys with material rich in lepra bacilli taken from human beings. The lesions appeared only after an incubation period that was in some cases prolonged from twenty-two to ninety-four days. The lesions persisted but a short time and the monkeys recovered in from thirty to one hundred and fifty days. Clegg§ and Sugai|| found Japanese dancing mice susceptible to infection with leprous material, the micro-organisms not remain- ing localized at the seat of inoculation, but disseminating through- out the animal’s body. Their observation has been confirmed by | Duval,** who later{{ was also able to infect monkeys—Macacus rhesus—with pure cultures of the organism and produce the typical disease. * “Berliner klin. Wochenschrift,”’ 1885-1886. + “Centralbl. f. Bakt. u. Parasitenk,”’ (Originale), March 12, 1902,xxx1, No. 7, p. 276. 3 t “Semaine medicale,” 1905, No. 10, p. 110. § “ Philippine Journal of Science,” 1909, IV, 403. | “Lepra,” 1909, VIII, 203. le ** “Journal of Experimental Medicine,’ tt Ibid., rorz, x11, 374. ” ” 1910, XII, 649. 702 Leprosy Very few instances are recorded in which actual inoculation has produced leprosy in man. Arning* was able to experiment upon a condemned criminal, of a family entirely free from the disease, in the Sandwich Islands. Fragments of tissue freshly excised from a lepra nodule were introduced beneath his skin and the man was kept under observation. In the course of some months typical lesions began to develop at the points of inoculation and spread gradually, ending in general leprosy in about five years. Sticker} is of the opinion that the primary infection in lepra takes place through the nose, supporting his opinion by observa- tions upon 153 accurately studied cases, in which— 1. The nasal lesion is the only one constant in both the nodular and anesthetic forms of the disease. 2. The nasal lesion is peculiar—i.e., naw entirely different from all other lepra lesions. 3. The clinical symptoms of lepra begin in the nose. 4. The relapses in the disease always begin with nasal symptoms, such as epistaxis, congestion of the nasal mucous membrane, a sensation of heat, etc. 5. In incipient cases the lepra bacilli are first found in the nose. Lesions.—The lepra nodes in general resemble tuberculous lesions, but are superficial, affecting the skin and subcutaneous tissues. Rarely they may also occur in the organs. Virchowt has seen a case in which lepra bacilli could be found only in the spleen. Once established in the body, the bacillus may grow in the con- nective tissues and produce chronic inflammatory nodes—the analogues of tubercles;—or in the nerves, causing aresthesia and trophic disturbances. On this account two forms of the disease, lepra nodosa (elephantiasis grecorum) and lepra anesthetica, are described. These forms may occur independently of one another, or may be associated in the same case. The nodes consist of lymphoid and epithelioid cells and fibers, and are vascular, so that much of the embryonal tissue completes its transformation to fibers without necrotic changes. This makes the disease productive rather than destructive, the lesions re- sembling new growths. The bacilli, which occur in enormous _nhumbers, are often found in groups inclosed within the protoplasm of certain large vacuolated cells—the ‘‘lepra cells”—which seem to be partly degenerated endothelial cells. Sometimes they are anuclear; rarely they contain several nuclei (giant cells). Bacilli also occur in the lymph-spaces and in the nerve-sheath. Lepra nodules do not degenerate like tubercles, and the ulcera- tion, which constitutes a large part of the pathology of the disease, *“Centralbl. f. Bakt.,” etc., 1889, VI, p. 201. Tt “ Mittheilungen und Verhandlungen der internationalen wissenschaftlichen Lepra-Konferenz zu Berlin,” Oct., 1897, 2, Theil. } Ibid. Lesions 703 seems to be largely due to the injurious action of external agencies upon the feebly vital pathologic tissue. According to the studies of Johnston and Jamieson,* the bacterio- logic diagnosis of nodular leprosy can be made by spreading serum obtained by scraping a leprous nodule upon a cover-glass, drying, fixing, and staining with carbol-fuchsin and Gabbet’s solution as for the tubercle bacillus. In such preparations the bacilli are pres- ent in enormous numbers, forming a marked contrast to tuber- culous skin diseases, in which they are very few. Fig. 284.—Lepra anesthetica (McConnell). In anesthetic leprosy nodules form upon the peripheral nerves, and by connective-tissue formation, as well as by the entrance of the bacilli into the nerve-sheaths, cause irritation, followed by degeneration of the nerves. The anesthesia following the peripheral nervous lesions predisposes to the formation of ulcers, etc., by allow- ing injuries to occur without detection and to progress without observation. The ulcerations of the hands and feet, with frequent loss of fingers and toes, follow these lesions, probably in the same manner as in syringomyelia. The disease usually first manifests itself upon the face, extensor surfaces, elbows, and knees, and for a long time confines itself to * “Montreal Med. Journal,” Jan., 1897. 704 Leprosy the skin. Ultimately it sometimes invades the lymphatics and ex- tends to the internal viscera. Death ultimately occurs from ex- haustion, if not from the frequent intercurrent affections, especially pneumonia and tuberculosis, to which the patients seem predisposed. Specific Therapy.—Carrasquilla’s* “leprosy serum’ was prepared by injecting the serum separated from blood withdrawn from lepers, into horses, mules, and asses, and, after a number of in- jections, bleeding the animals and separating the serum. There is no reason for thinking that such a product could have therapeutic value. In practice it proved worthless. Rost} prepared massive cultures of the lepra bacillus, filtered Fig. 285.—A case of lepra nodosa treated in the Medico-Chirurgical Hospital of Philadelphia. them through porcelain, concentrated the filtrate to one-tenth of its volume, and mixed the filtrate with an equal volume of glycerin. The resulting preparation was called leprolin and was supposed to be analogous to tuberculin. With it he treated a number of lepers at the Leper Hospital at Rangoon, Burmah, many of whom greatly improved and some of whom seemed to be cured. Confirmation of the work by others is greatly desired. Sanitation.—While not so contagious as tuberculosis, it has * “Wiener med. Wochenschrift,” No. 41, 1897. { “Brit. Med. Jour.,” Feb. 11, 1905. Sanitation 705 been proved that leprosy is transmissible, and it may be regarded as an essential sanitary precaution that lepers should be segregated and mingle as little as possible with healthy persons. The disease is not hereditary, so that there is no reason why lepers should not marry among themselves. The children should, however, be taken from the parents lest they be subsequently infected. 45 CHAPTER XXXI GLANDERS Bacittus Maier (LOFFLER AND ScHitrTz)* General Characteristics.—A non-motile, non-flagellate, non-sporogenous, non- liquefying, non-chromogenic, non-aérogenic, agrobic and optionally anaérobic, acid-forming and milk coagulating bacillus, pathogenic for man and the lower animals, staining by ordinary methods, but not by Gram’s method. Glanders, “Rotz’”’ (German) or ‘“‘morve’’ (French), is an infectious mycotic disease which, fortunately, is almost entirely confined to the lower animals. Only occasionally does it secure a victim among hostlers, drovers, soldiers, and others whose vocations bring them in contact with diseased horses. Several bacteriologists have succumbed to accidental laboratory infection. Glanders was first known to us as a.disease of the horse and ass, characterized by the formation of discrete, cleanly cut ulcers upon the mucous membrane of the nose. The ulcers in the nose are formed by the breaking down of inflammatory nodules which can be detected in all stages upon the diseased membranes. Hav- ing once formed, they show no tendency to recover, but slowly spread and persistently discharge a virulent pus. The edges of the ulcers are indurated and elevated, their surfaces often smooth. The disease does not progress to any great extent before the sub- maxillary lymphatic glands begin to enlarge, soften, and ulcerate. The lungs may also become infected by inspiration of the infectious material from the nose and throat, and contain small foci of broncho- pneumonia not unlike tubercles in their early appearance. The animals ultimately die of exhaustion. Specific Organism.—In 1882, shortly after the discovery of the tubercle bacillus, Léffler and Schiitz discovered in the discharges and tissues of the disease the specific micro-organism, the glanders bacillus (Bacillus mallet). Distribution.—The glanders bacillus does not seem to find con- ditions outside the animal body suitable for its growth, and prob- ably lives a purely parasitic existence. Morphology.—The glanders bacillus is somewhat shorter and distinctly thicker than the tubercle bacillus, and has rounded ends. It measures about 0.25 to0.4 X 1.5 to 3 yw, and is slightly bent. Coccoid and branched forms sometimes occur. It usually occurs singly, though upon blood-serum, and especially upon potato, * “Deutsche med. Wochenschrift,” 1882, 52. 706 Staining 707 conjoined individuals may occasionally be found. Long threads are never formed. When stained with ordinary aqueous solutions of the aniline dyes, or with Léffler’s alkaline methylene-blue, the bacillary sub- stance does not usually appear homogeneous, but, like that of the diphtheria bacillus, shows marked inequalities, some areas being deeply, some faintly, stained. The bacillus is non-motile, has no flagella, and does not form spores. Staining.—The organism can be stained with the watery anilin- dye solutions, but not by Gram’s method. The bacillus readily gives up the stain in the presence of decolorizing agents, so is dif- Fig. 286.—Bacillus mallei, from a culture upon glycerin agar-agar. X 1000 (Frankel and Pfeiffer). ficult to stain in tissues. Ldéffler accomplished the staining by allowing the sections to lie for some time (five minutes) in the alka- line methylene-blue solution, then transferring them to a solution of | sulphuric and oxalic acids: Concentrated sulphuric acid................0505- 2 drops Five per cent. oxalic acid solution........... hacia 1 drop Distilled: waters: cavity de tani, Sitoeyen waantena souls tek Io cc. for five seconds, then to absolute alcohol, xylol, etc. The bacilli appear dark blue upona paler ground. This method gives very good results, but has been largely superseded by the use of Kiihne’s car- ~ bolmethylene-blue. Methylene-blueé, «0.0.0. cccc een ase suse terse seaaas r.5 PAT CO Wa Oc cca sh cee eas Ree te Ducane arte 10.0 Five per cent. aqueous phenol solution............... 100.0 Kiihne stains the section for about half an hour, washes it in water, 708 Glanders decolorizes it carefully in hydrochloric acid (10 drops to §00 cc. of water), immerses it at once in a solution of lithium carbonate (8 drops of a saturated solution of lithium carbonate in 10 cc. of water), places it in a bath of distilled water for a few minutes, dips it into absolute alcohol colored with a little methylene-blue, dehydrates it in anilin oil containing a little methylene-blue in solution, washes it in pure anilin oil, not colored, then in a light ethereal oil, clears it in xylol, and finally mounts it in balsam. Vital Resistance.—The organism grows only between 25° and 42°C. It is killed by exposure to 60°C. for two hours, or to 75°C. for one hour. Sunlight kills it after twenty-four hours’ exposure. Thor- ough drying destroys it in a short time. When planted upon cul- ture-media, sealed, and kept cool and in the dark, it may be kept alive for months and even years. Exposure to 1 per cent. carbolic acid destroys it in about half an hour; 1: 1000 bichlorid of mercury solution, in about fifteen minutes. According to Hiss and Zinsser, it may remain alive in the water of horse-troughs for seventy days. Isolation.—Attempts to isolate the glanders bacillus from infectious discharges, by the usual plate method, are apt to fail, on account of the presence of other more rapidly growing organisms. A better method seems to be by infecting an animal and recover- ing the bacillus from its tissues. For this purpose the guinea-pig, being a highly susceptible as well as a readily procurable animal, is appropriate. When a subcutaneous inoculation of some of the infectious pus is made, a tumefaction can be observed in guinea- pigs in from four to five days. Somewhat later this tumefac- tion changes to a caseous nodule, which ruptures and leaves a chronic superficial ulcer with irregular margins. The lymph- glands speedily become invaded, and in four or five weeks signs of general infection appear. The lymph-glands, especially of the inguinal region, suppurate, and the testicles frequently undergo the same process. Later the joints are affected with a suppura- tive arthritis, the pus from which contains the bacilli. The animal eventually dies of exhaustion. No nasal ulcers form in guinea-pigs. In field-mice the disease is much more rapid, no local lesions being visible. For two or three days the animal seems unwell, its breathing is hurried, it sits with closed eyes in a corner of the cage, and finally, without any other preliminaries, tumbles over dead. From the tissues of the inoculated animals pure cultures are easily made. Perhaps the best places from which to secure a culture are the softened nodes which have not ruptured, or the joints. Diagnosis of Glanders.—Straus* has given us a method which is of great use, both for isolating pure cultures of the glanders bacillus and for making a diagnosis of the disease. * “Compt. rendu Acad. d. Sciences,” Paris, CVIII, 530. Cultivation 709 But a short time is required. The material suspected to contain the glanders bacillus is injected into the peritoneal cavity of a male guinea-pig. In three or four days the disease becomes established and the testicles enlarge; the skin over them becomes red and shining; the testicles themselves begin to suppurate, and often evacuate through the skin. The animal dies in about two weeks. If, however, it be killed and its testicles examined, the tunica vaginalis testis will be found to contain pus, and sometimes to be partially obliterated by inflammatory exudation. The bacilli are present in this pus, and can be secured from it in pure cultures. The value of Straus’ method has been somewhat lessened by the dis- covery by Kutcher,* that a new bacillus, which he has classed among the pseudo-tubercle bacilli, producesa similar testicular swelling when injected into the abdominal cavity; also by Levy and Steinmetz, t who found that Staphylococcus pyogenes aureus was also capable of pro- voking suppurative orchitis. However, the diagnosis is certain ifa culture of the glanders bacillus be secured from the pus in the scrotum. For the diagnosis of the disease in living animals, subcutaneous injections of mallein (qg.v.) are also employed. McFadyent was the first to récomniend agglutination of the glanders bacillus by the serum of supposedly infected animals as a test of the existence of glanders. The subject has been somewhat extensively tried and officially adopted by the Prussian govern- ment. Moore and Taylor,§ in a recent review and examination of the test, conclude that it is easier and quite as accurate as the mallein method and is applicable in cases where fever exists. The mdximum dilution of normal horse-serum that will macroscopically agglutinate glanders bacilli is 1 : 500, but occursin very fewcases. The maxi- mum agglutinative power of the serum of diseased horses not suffer- ing from glanders is not higher than that of normal serum., The diagnosis is usually not difficult to make, but requires much care. Cultures of the glanders bacillus sometimes unexpectedly lose their ability to agglutinate. , The diagnosis of glanders by means of the complement-fixation method has been tried with glittering results by Mohler and Eichhorn.|| Cultivation.—The bacillus is an aérobic and optionally anaérobic organism, and can be grown in bouillon, upon agar-agar, better upon glycerin agar-agar, very well upon blood-serum, and quite character- istically upon potato. The optimum temperature is 37.5°C. Colonies.—Upon 4 per cent. glycerin agar-agar plates the colonies appear upon the second day as whitish or pale yellow, shining, round dots. Under the microscope they are brownish yellow, thick and granular, with sharp borders. Bouillon.—In broth cultures the glanders bacillus causes turbidity, the surface of the culture being covered by a slimy scum. The medium becomes brown in color. * “Zeitschrift fiir Hygiene,” Bd. xx1, Heft 1, Dec. 6, 1895. ¢ “Berliner klin. Wochenschrift,” March 18, 1895, No. 11. t “Jour. Comp. Path. and Therap.,” 1896, p. 322. § “Jour. Infectious Diseases,” 1907, IV, p. 85, supplement. || “Report of the Bureau of Animal Industry,” 1910. 710 Glanders Gelatin is not liquefied. The growth upon the surface is grayish white and slimy, never abundant. Agar-agar.—Upon agar-agar and glycerin agar-agar the growth occurs as a moist shining viscid layer. Blood-serum.—Upon blood-serum the growth is rather character- istic, the colonies along the line of inoculation appearing as cir- cumscribed, clear, transparent drops, which later become confluent and form a transparent layer unaccompanied by liquefaction. Potato.—The most characteristic growth is upon potato. It first appears in about forty-eight hours as a transparent, honey-like, yellowish layer, developing only at incubation temperatures, and soon becoming reddish-brown in color. As this brown color of the colony develops, the potato for a considerable distance around it becomes greenish brown. Bacillus pyocyaneus sometimes produces somewhat the same appearance. Fig. 287.—Culture of glanders upon cooked potato (Léffler). Milk.—In litmus milk the glanders bacillus produces acid. A firm coagulum forms and subsequently separates from the clear reddish whey. Metabolic Products.—The organism produces acids and curdling ferments. It forms no indol, no liquefying or proteolytic ferments. There is no exotoxin. All the poisonous substances seem tobe endotoxins. Mallein.—Babes,* Bonome,} Pearson,{ and others have prepared a substance, mallein, from cultures of the glanders bacillus, and have employed it for diagnostic purposes. It seems to be useful in veteri- * “ Archiv de Med. exp. et d’Anat. patholog.,” 1892, No. 4. t “Deutsche med. Woch.,” 1894, Nos. 36 and 38, pp. 703, 725, and 744. t “Jour. of Comp. Med. and Vet. Archiv,” Phila., 1891, XII, pp. 41 I-415. Lesions 7IT nary medicine, the reaction following its injection into glandered animals being similar to that caused by the injection of tuberculin into tuberculous animals. The preparation of mallein is simple. Cultures of the glanders bacillus are grown in glycerin bouillon for several weeks and killed by heat. The culture is then filtered through porcelain, to remove the dead bacteria, and evaporated to one-tenth of its volume. Before use the mallein is diluted with nine times its volume of 0.5 per cent. aqueous carbolic acid solution. The dose for diagnostic purposes is 0.25 cc. for the horse. It has also been prepared from potato cultures, which are said to yield a stronger product. The agent is employed exactly like tuberculin, the temperature being taken before and after its hypodermic in- jection. A febrile reaction of more than 1.5°C. is said to beindicative of the disease. Pathogenesis.—That the bacillus is the cause of glanders there is no room to doubt, as Léffler and Schiitz have succeeded, by the inoculation of horses and asses, in producing the well-known disease. The goat, cat, hog, field-mouse, wood-mouse, marmot, rabbit, guinea-pig, and hedgehog all appear to be susceptible. Cattle, house-mice, white mice, rats, and birds are immune. Infection may take place through the mucous membranes of the nose, mouth, or alimentary tract, and apparently without preéxisting demonstrable lesions. The disease assumes either an acute form, characterized by de- structive necrosis and ulceration of the mucous membranes with fever and prostration, terminating in pneumonia, or, as is more frequent, a chronic form (‘‘farcy”), in which the lesions of the mucous membranes are less destructive and in which there is a generalized distribution of the micro-organisms throughout the body, with resulting more or less widespread nodular formations (farcy- buds) in the skin. The acute form is quickly fatal, death some- times coming on in from four to six weeks; the chronic form may last for several years and end in complete recovery. Lesions.— When stained in sections of tissue the bacilli are found in small inflammatory areas. These nodules can be seen with the naked eye scattered through the liver, kidney, and spleen of animals dead of experimental glanders. They consist principally of leuko- cytes, but also contain numerous epithelioid cells. As is the case with tubercles, the centers of the nodules are prone to necrotic changes, but the cells show marked karyorrhexis, and the tendency is more toward colliquation than caseation. The typical ulcerations depend upon retrogressive changes occurring upon mucous surfaces, the breaking down of the nodules permitting the softened material to escape. At times the lesions heal with the formation of stellate scars. Baumgarten* regarded the histologic lesions of glanders as much * “Pathologische Mykologie,” Braunschweig, 1890. qi2 Glanders Fig. 288.—Pustular eruption of acute glanders as exhibited on the day of the patient’s death, twenty-eight days after initial chill (Zeit). Fig. 289.—Lesions of glanders in the skin of a horsé. (Kitt). Glanders in Human Beings 713 _like those of the tubercle. He first saw epithelioid cells accumulate, followed by the invasion of leukocytes. Tedeschi* was not able to confirm Baumgarten’s work, but found the primary change to be necrosis of the affected tissue followed by invasion of leukocytes. The observations of Wright} are in accord with those of Tede- schi. He first saw a marked degeneration of the tissue, and then an inflammatory exudation, amounting in some cases to actual suppuration. , Glanders in Human Beings.—Human beings are but rarely in- fected. The disease has, however, occurred among those in frequent Fig. 290.—Farcy affecting the skin of the shoulder (Mohler and Eichhorn, in Twenty-seventh Annual Report of the Bureau of Animal Industry, U. S. De- partment of Agriculture, 1910). contact with horses and among bacteriologists. It occurs either in an acute form in which, from whatever primary focus may have been its starting-point, the distribution of micro-organisms may be so rapid as to induce an affection with skin lesions resembling smallpox and terminating fatally in eight or ten days. The chronic form in man is chiefly confined to the nasal and laryn- geal mucosa. It is commonly mistaken for more simple infections, and though it sometimes shows its character by generalizing, it not infrequently recovers. Virulence.—The organism is said to lose virulence if cultivated for many generations upon artificial media. While this is true, attempts to attenuate fresh cultures by heat, etc., have usually failed. * “Zeigler’s Beitrage z. path. Anat.,” Bd. x1t1, 1893. Tt “Journal of Experimental Medicine,” vol. 1, No. 4, p. 577. 414 : Glanders Immunity.—Leo has pointed out that white rats, which are im- mune to the disease, may be made susceptible by feeding with phloridzin and causing glycosuria. Babes has asserted that the injection of mallein into susceptible animals will immunize them against glanders. Some observers claim to have seen good therapeutic results follow the repeated in- Fig. 291.—Lesions of glanders in the nasal septum of a horse (Mohler and Eichhorn, in Twenty-seventh Annual Report of the Bureau of Animal Industry, U.S. Department of Agriculture, 1910). jection of mallein in small doses. Others, as Chenot and Picq,* find blood-serum from immune animals like the ox to be curative when injected into guinea-pigs infected with glanders. Pseudo-glanders Bacillus.—Bacilli similar to the glanders pacilhas in tinctorial and cultural peculiarities, but not pathogenic for mice, guinea-pigs, or rabbits, have been isolated by Babes, t and by Selter,} and called the pseudo-glanders bacillus. * “Compte-rendu de la Soc. de Biol.,”” March 26, 1892. { “Archiv de med. exp. et d’anat. path.,” 1891. t“Centralbl. f. Bakt.,” etc., Feb. 18, 1902, XXXV, 5, D. 520. CHAPTER XXXII RHINOSCLEROMA BacILtus RHINOSCLEROMATIS (VON FRIScH*) General Characteristics.—A non-motile, non-flagellate, non-sporogenous, non- chromogenic, non-aérogenic, aérobic and optionally anaérobic, capsulated ba- cillus, pathogenic for man and identical with Bacillus pneumoniz of Friedlander, except that it stains by Gram’s method. A peculiar disease of the nares, characterized by the formation of circumscribed nodular tumors, and known as rhinoscleroma, is occasionally seen in Austria-Hungary, Italy, and some parts of Fig. 292.—Rhinoscleroma (Courtesy of Mr. Owen Richards, Cairo, Egypt). Germany.’ A few cases have been observed in Egypt and a few among the foreign-born residents of the United States. The nodular masses are flattened, may be discrete, isolated, or coalescent, grow with great slowness, and recur ifexcised. The disease commences in the mucous membrane and the adjoining skin of the nose, and spreads to the skin in the immediate neighborhood by a slow invasion, involving the upper lip, jaw, hard palate, and sometimes even the * “Wiener med. Wochenschrift,” 1882, 32. 715 716 Rhinoscleroma pharynx. The growths are without evidences of acute inflammation, do not usually ulcerate, and upon microscopic examination consist of an infiltration of the papillary layer and corium of the skin, with round cells which in part change to fibrillar tissue. The tumors possess a well-developed lymph-vascular system. Sometimes the cells undergo hyaline degeneration. In the nodes, von Frisch discovered bacilli closely resembling the pneumobacillus of Friedlinder, both in morphology and vegetation, and, like it, surrounded by a capsule. The only differences between te Fig. 293.—Rhinoscleroma (Courtesy of Mr. Owen Richards, Cairo, Egypt). the bacillus of rhinoscleroma and Bacillus pneumoniz of Friedlander are that the former stains well by Gram’s method, while the latter does not; that the former is rather more distinctly rod-shaped than the latter, and more often shows its capsule in culture-media. The bacillus can be cultivated, and cultures in all media resemble those of the bacillus of Friedlander (q.v.) so closely as to be almost indistinguishable from it. The chief difference lies in its inability to endure acid media and to ferment carbohydrates. Even when inoculated into animals the bacillus behaves much like Friedlinder’s bacillus. Pathogenesis q17 Tnoculation has, so far, failed to reproduce the disease either in man or in the lower animals. Pathogenesis.—The bacillus is said to be pathogenic for man only, producing granulomatous formations of the skin and mucous membranes of the anterior and posterior nares. These vary in Fig. 294.—Bacillus rhinoscleromatis. Pure culture on glycerinagar-agar. Mag- nified 1000 diameters (Migula). structure according to age. The young nodes consist of a loose fibrillar tissue composed of lymphocytes, fibroblasts, and fibers. Some of the cells are large and have a clear cytoplasm and are known as the cells of Mikulicz. In and between them the bacilli are found in considerable numbers. The older lesions consist of a firm sclerotic cicatricial tissue. , CHAPTER XXXIII SYPHILIS TREPONEMA (SPIROCHETA) PALLIDUM (SCHAUDINN AND HOFFMANN) General Characteristics—A non-chromogenic, non-aérogenic, anaérobic, minute, slender, closely coiled, flexible, motile, flagellated, non-sporogenous, non-liquefying, spiral organism, cultivable upon specially prepared media, patho- genic for man and certain of the lower animals, staining by certain methods only and not by Grarm’s method. ALTHOUGH syphilis has been well known for centuries, its specific cause has but recently been discovered. The supposition that the disease could not be successfully communicated to any of the lower animals was supposed to explain the delay, but has not proved to be the case, for in spite of the discovery of Metschnikoff and Roux* that chimpanzees could be successfully inoculated with virus from a human lesion, the confirmation of their work by Lassarf and others, and the additional discovery of Metschnikoff and Roux,t{ that it is also possible to infect macaques with syphilis, the specific organism was, after all, discovered for the first time in matter secured from human lesions. It has long been known that preputial smegma and various ulcerative lesions of the generative organs contain certain spiral or- ganisms. Bordet studied them with care, expecting to prove that. they were concerned with the etiology of syphilis, but it remained for Schaudinn and Hoffmann§ to discover the specific micro- organism. They point out that there are two separate species of spiral organisms commonly found in ulcerative lesions of the genitalia. One called by them Spirocheta refringens is of common occurrence, the other, called Spirocheta pallida, later, and more correctly, Treponema. pallidum, is found only in syphilitic lesions— and is, therefore, their probable cause. The discovery of Tre- ponema pallidum by Schaudinn and Hoffmann was quickly con- firmed by Metschnikoff.|| It is now universally accepted as the cause of syphilis. a Morphology.—The organism is a slender, flexible, closely coiled spiral, usually showing from eight to ten uniform undulations, but occasionally being so short as to show only two or three, or so long as to show as many as twenty. * “Ann, de l’Inst. Pasteur,” Dec., 1903, p. 809. { “Berliner klin. Wochenschrift,” 1903, Pp. 1189. t ‘Annales de l’Inst. Pasteur,” Jan., 1904. § “Deutsche med. Wochenschrift,” May 4, 1905. [ “Bull. Acad. de med. de Paris,” May 16, 1905. 718 Staining 719 It is very slender, measuring from 0.33 to 0.5 w in breadth to 3.5 to 15.5 » in length (Levaditi and McIntosh). It forms no spores, Multiplication seems to take place by longitudinal division. It is motile, and when observed alive with a dark field illuminator, can be seen to rotate slowly about its longitudinal axis at the same time that it slowly sways from side to side with a serpentine move- ment. The organisms are provided with flagella at one end, some- times one at each end. Noguchi* observed two types of treponema, one slender, one stouter. When carried through culture and used to inoculate rabbits their differences were found to be fairly constant. The lesions pro- duced in rabbit’s testicles varied with the variety of organism in- oculated, one causing a diffuse, the other a nodular, orchitis. He conjectured that the distinction may be of value in explaining certain obscure points in human syphilis. Staining.—I. Films.—The original discovery of the organism was achieved through the employment of Giemsa’s stain—a modifi- cation of the Romanowsky method. But by this method the organ- isms appeared very pale and not very numerous. Goldhornj improved it as follows: In 200 cc. of water, 2 grams of lithium carbonate are dissolved and 2 grams of Merck’s medicinal, Griibler’s BX, or Koch’s rectified methylene blue added. This mixture is heated moderately in a rice boiler until a rich polychrome has formed. To determine this a sample is examined in a test-tube every few minutes by holding it against an artificial light. As soon as a distinctly red color is obtained, the desired degree of heating has been reached. After cooling it is filtered through cotton ina funnel. To one-half of this polychrome solution 5 per cent. of acetic acid is gradually added until a strip of litmus-paper shows above the line of demarcation a distinct acid reaction, when the remaining half of the solution is added, so as to carry the reaction back to a low degree of alkalinity. A weak eosin solution is now prepared, approximately o.5 per cent. French eosin, and this is added gradually while the mixture is being stirred until a filtered sam- ple shows the filtrate to be of a pale bluish color with a slight fluorescence. The mixture is allowed to stand for one day and then filtered. The precipitate which has separated is collected on a double piece of filter-paper and dried at room tem- perature (heating spoils it). When completely dried it can easily be removed from the paper and may then be dissolved without further washingin commercial (not pure) wood alcohol. The solution should be allowed to stand a day, then filtered. The strength of this alcoholic solution is approximately 1 per cent. To use the stain, one drops upon an unfixed spread enough dye to cover it, permits it to act for three or four seconds, and then pours it off and introduces the glass slowly, spread side down, into clean water, where it is held for another four or five seconds, after which it is shaken to and fro in the water to wash it. It is next dried and examined at once or after mounting in balsam. The spirochetes appear violet in color. Ghoreyeb{ recommends the following rapid method of staining the organism in smears. A thin spread is to be preferred. No heat fixation is necessary: * “Journal of Experimental Medicine,” 1912, xv, No. 2, p. 201. { Ibid., 1906, vit, p. 451. ce 2, . t “Jour. Amer. Med. Assoc.,” May 7, 1910, Liv, No. 19, p. 1498. 720 Syphilis 1. Cover the smear with a 1 per cent. aqueous solution of osmic acid, and per- mit it to act for thirty seconds. This solution acts as a fixative and mordant. 2. Wash thoroughly in running water. : : 3. Cover the smear with a 1: 100 dilution of Liquor plumbi subacetatis (freshly prepared). Permit it to act for ten seconds. The lead unites with the albumin . to form lead albuminate which is insoluble in water. 4. Wash thoroughly in running water. : . : s. Cover the smear with a ro per cent. aqueous solution of sodium sulphid. This is to act ten seconds, during which the salt transforms the lead albuminate into lead sulphid and causes the preparation to turn brown. The osmic acid when reapplied causes it to become black. : 6. Wash thoroughly in running water. The whole process is to be repeated in exactly the same manner three times, the washings all being very thorough. The preparation is then dried and mounted in Canada balsam. The micro-organisms and cellular detritus are stained black. Fig. 295.—Treponema pallidum in the periosteum near an epiphysis (Bertarelli). When serum from a primary sore or other syphilitic lesion is treated by these methods, a number of the spirocheta appear well stained and a number very palely stained, so that one is in doubt whether there may be many others unstained, and this seems to be the case, for when similar smears are treated by other methods many more can be found. Stern* has applied the method of silver incrustation to the ex- amination of films by the following simple procedure: _ Spreads are made in the usual manner, dried in the air, and then for a few hours in an incubating ovenat 37°C. They are next placed in a ro per cent. solution of nitrate of silver in a colorless glass receptacle and allowed to rest in the diffused daylight of a comfortably lighted room for a few hours, until they become brown- ish metallic in appearance, when they are thoroughly washed in water. The spi-, tocheta appear black, the background brownish. * “Berliner klin. Wochenschrift,” 1907, No. 14. Staining 721 Burri* has recommended a simple and rapid method of demon- strating the treponema and other similar organisms by the use of India ink. A drop of juice is squeezed from a chancre or mucous patch and mixed with a drop of India ink and then spread upon a glass slide as in making a spread of a drop of blood. As the ink dries it leaves a black or dark brown field upon which the spiral organisms stand out as shining, colorless, and hence conspicuous objects. Williams uses Higgins’ water-proof ink, and Hiss recommends ‘‘chin- chin,” Giinther-Wagner liquid pear] ink, for the purpose. The method is fairly satisfactory for diagnosis and can be applied in a few moments. Fig. 296.—Treponema pallidum impregnated with silver. Film prepared from the skin of a macerated, congenitally syphilitic fetus. > 750 diameters (Flex- ner). The dense aggregation of organisms may indicate agglutination. II. Section.—Staining the organism in the tissues is a more difficult matter, for the Giemsa stain scarcely shows it at all. Bert- arelli and Volpinof tried a modification of the van Ermengen method for flagella with some success, but there was no real success until Levaditit devised his methods of silver impregnation. This consists in hardening pieces of tissue about 1 mm. in thickness in 10 per cent. formol for twenty-four hours, rinsing in water, and immersing in 95 per cent. alcohol for twenty-four hours. The block is then placed in diluted water until it sinks to the bottom of the container, and then transferred to a 1.5 to 3 per cent. aqueous solution of nitrate of silver in a blue or amber bottle and kept in a dark * “Wiener klin. Wochenschrift,” July 1, 1909. + “Centralbl. f. Bakt. u. Parasitenk.,” Orig., 1905, XI, p. 56. t “Compt.-rendu de la Soc. de Biol. de Paris,” 1905, LIX, p. 326. 46 722 Syphilis incubating oven at 37°C. for from three to five days. Finally, it is washed in water and placed in a solution of pyrogallic acid, 2 to 4 grams; formol, 5 cc.; distilled water, 100 cc., and kept in the dark, at room temperature, from twenty- four to seventy-two hours, then washed in distilled water, embedded in paraffin, and cut. The treponemata are intensely black, the tissue yellow brown. The sections are finally stained with—(a) Giemsa’s stain for a few minutes, then washed in water, differentiated with absolute alcohol containing a few drops of ~ oil of cloves, cleared with oil of bergamot or xylol, or (6) concentrated solution of toluidin blue, differentiated in alcohol containing a few drops of Unna’s glycerin- ether mixture, cleared in oil of bergamot, then in xylol, and mounted in Canada balsam. This method was later improved by egadia and Manouelian’* by the addition of 10 per cent. of pyridin to the silver bath just before the block of tissue is put in, and by using for the reducing bath a mixture of pyrogallic acid, acetone, and pyridin. The details are as follows: Fragments of organs or tissues 1.to 2 mm. in thick- ness are fixed for twenty-four to forty-eight hours in a solution of formalin 10: 100, then washed in 96 per cent. alcohol for twelve to sixteen hours, then in distilled water until the blocks fall to the bottom of the container. They are then impreg- nated by immersion in a bath composed of a 1 percent. solution of nitrate of silver, to which, at the moment of employment, ro per cent. of pyridin is added. Keep the blocks immersed in this solution at room temperature for two or three hours, and at 50°C. for four or six hours, then wash rapidly in a ro per cent. solution of pyridin, and reduce in a bath composed of 4 per cent. pyrogallic acid, to which, at” the moment of using, 10 per cent. of pure acetone and 15 per cent. (total volume) of pyridin are added. The reduction bath must be continued for several hours, after which the tissue goes through 70 per cent. alcohol, xylol, paraffin, and sec- tions are cut. The sections, fastened to the slide, are stained with Unna’s blue ‘2 elnds blue, differentiated with glycerin-ether, and finally mounted in Canada alsam. Distribution.—The Treponema pallidum is not known in nature apart from the lesions of syphilis. It has now been found in all the lesions of this disease and in the blood of syphilitics in larger or smaller numbers. The discovery has greatly modified our ideas of the tertiary stage, for the demonstration of the organisms in its lesions shows them to be undoubtedly contagious.. The greatest number of the organisms are found in the tissues—especially the © liver—of still-born infants with congenital syphilis. Cultivation—The cultivation of the treponema was first at- tempted by Levaditi and McIntosh,t who, deriving the organism from an experimental primary lesion in a monkey (Macacus rhesus), carried it through several generations in collodion sacs inclosed in the peritoneal cavity of other monkeys (Macacus cynomolgus) and in the peritoneal cavity of rabbits. They were unable, how- ever, to secure the treponema in pure culture, having it continually mixed with other organisms from the primary lesion. In the mixture, however, they were able to maintain it for generations and study its morphology and behavior. During cultivation its virulence was lost. Schereschewsky{ endeavored to cultivate the treponema by * “Compt.-rendu de la Soc. de Biol. de Paris,” 1906, Lvim, p. 134. t “Ann. de l’Inst. Pasteur,” 1907, p. 784. ft “Deutsche med. Wochenschrift,”’ t909, xxxv, 835, 1260, 1652. Cultivation 723 placing a fragment of human tissue, containing it, deep down into gelatinized horse-serum. The treponema grew together with the contaminating organism and nopureculture wassecured. Muhlens* and Hoffmann, using the same method, succeeded in securing pure cultures of the treponema, but found them avirulent. Noguchi,t taking advantage of the observations of Bruckner and Galasesco§ and Sowade,|| that an enormous multiplication of treponema occurred when material containing it was inoculated into the rabbit’s testis, performed a lengthy series of cultivation experiments with the enriched material thus obtained. The culture-medium used in these experiments was a ‘“‘serum water,” composed of 1 part of the serum of the sheep, horse, or rabbit and 3 parts of distilled water; 16 cc. of this mixture was placed in test-tubes 20 cm. long and 1.5 cm. in diameter and sterilized for fifteen minutes at 100°C. each day for three days. To each of a series of such tubes a carefully removed fragment of sterile rabbit’s testis was added, after which the tubes were incubated at 37°C. for two days to determine their sterility. To each tube the material from the inoculated rabbit’s testis, rich in the treponema, is added, after which the surface of the medium in each receives a thick layer of sterile paraffin oil. As the most strict anaérobiosis is necessary, the tubes are placed in a Novy jar, the bottom of which contains pyrogallic acid. Noguchi first passes H gas through the jar, permitting it to bubble through the pyrogallic acid solution for ten minutes. He then uses a vacuum pump to exhaust the atmosphere in the jar, and lastly permits the alka- line solution (KOH) to flow down one of the tubes and mix with the pyrogallic acid. In these cultures the pallidum grows together with such bacteria as may have been simultaneously introduced. To secure the cultures free from these bacteria Noguchi permitted the treponema to grow through a Berkefeld filter, which for a long time held back the other organisms. Later it was found that both bacteria and treponema grow side by side in a deep stab in a serum-agar-tissue medium, but that the bacteria grow only in the stab or puncture, whereas the treponemata grow out into the medium as a hazy cloud. By cautiously breaking the tube and securing material for transplantation from the scarcely visible cloud, the organisms may be transplanted to new media and pure cultures obtained. In a later paper, Noguchi** details the cultivation of the tre- ponema from fragments of human chancres, mucous patches, and other cutaneous lesions. The medium employed is a mixture of 2 per cent. slightly alkaline agar and 1 part of ascitic or hydrocele fluid, at the bottom of which a fragment of rabbit kidney or testis is placed. The medium is prepared in the tubes, after the addi- tion of the tissue, by mixing 2 parts of the melted agar at 50°C. with * Ibid., 1909, Xxxv, 1261. + “Zeitschrift fiir Hygiene und Infektionsk.,” 1911, LXVIII, 27. t “Journal of Experimental Medicine,” 1911, XIV, 99. § “Compt.-rendu de la Soc. de Biol. de Paris,” 1910, Lxvitt, 648. || “Deutsche med. Wochenschrift,” 1911, XxXvII, 682. ** “Journal of Experimental Medicine,’’ 1912, XV, I, p. go. 724 Syphilis 1 part of the ascitic or hydrocele fluid. After solidification a layer of paraffin oil 3 cm. deep is added. A considerable number of tubes should be prepared at the same time and incubated for a few days prior to use to determine sterility. The bits of human tissue are snipped up with sterile scissors in salt solution containing 1 per cent. of sodium citrate and should be kept immersed in this fluid from the time of securing to the time of planting, so as not to become dried. A bit of the tissue should be emulsified in a mortar with citrate solution and examined with a dark field illuminator to make sure that the organ- isms to be cultivated are present. If they are found, and the material shown to be adapted to culti- vation, each of the remaining bits of tissue is taken up by a thin blunt glass rod and pushed to the bottom of a culture-tube and into each tube several drops of the emulsion examined are intro- duced by means of a capillary pipet, also inserted deeply into the medium. The tubes are next incubated at 37°C. for two or three weeks. In successful tubes, in which the medium has not been broken up by gas-producing bacteria, there is a dense opaque growth of bacteria along the line of puncture, and a diffuse opales- cence of the agar-agar caused by the extension into it of the grow- ing treponemata. A capillary tube cautiously inserted into the opal- escent medium withdraws a particle that can be examined with the dark field illuminator. When such observation shows the cause of the opalescence to be, in fact, the treponema, the tube can be cautiously broken at some appropriate part and the transplanta- tion made from the opalescent part of the medium to fresh appro- priate culture-media. By these means, after a few trials, pure cultures of treponema were secured. The colonies were said never to be sharp, but always faintly visible. There is no color and no odor. By inoculating the organisms recently secured from human lesions (by the method given) into monkeys (Macacus rhesus and Cereopithicus callitrichus) Noguchi was able to produce typical syphilis of the monkey, thus showing that the virulence of the organisms was not lost in the cultivation. Zinsser, Hopkins and Gilbert* found it possible to grow Tre- ponema pallidum in massive cultures in fluid media. They em- -ployed a flask with a long slender neck like a “specific gravity flask.” The flask was filled with slightly acid (0.2 to 0.8 per cent. acidity) broth containing sheep-serum, ascitic fluid, horse-serum or rabbit- | serum, with an addition of autoclaved and hence thoroughly sterilized tissue (kidney, liver, brain, lung or heart muscle) and covered with sterile neutral paraffine oil. The culture contains the greatest number of organisms after three weeks. To collect them for mak- ing Juetin, etc., the fluid in the flasks was poured into tubes and *“ Journal of Experimental Medicine,” 1915, xxt, No. 3, p. 213. Pathogenesis and Specificity 725 centrifugated for a short time to throw down scraps of the nutrient tissue, the fluid then decanted and recentrifugated rapidly and for alonger time to throw down the micro-organisms. Pathogenesis and Specificity —There can be no doubt about the causal relation of Treponema pallidum to syphilis. It is unknown in every other relation; it has appeared in every required relation, and thus has completely fulfilled the laws of specificity laid down by Koch. Treponema pallidum is not only pathogenic for man, but, as has already been shown, can also be successfully implanted into chimpanzees, macaques, rabbits, guinea-pigs, and other experi- ment animals. As syphilis is, however, unknown under natural conditions, except in man, it may be looked upon as a human disease. The organism enters the body through a local breach of con- tinuity of the superficial tissues, except in experimental and con- genital infections, where it may immediately reach the blood. In ordinary acquired syphilis the point of entrance shows the first manifestations of the disease after a peried of primary incuba- tion about three weeks long, in what is known as the primary lesion or chancre. This appears as a papule, grows larger, undergoes super- ficial indolent ulceration, and eventually heals with the formation of an indurated cicatrix. It is in this lesion that the treponema first makes its appearance. From this lesion, where it multiplies slowly, it enters the lymphatics and soon reaches the lymph-nodes, which swell one by one as its invasion progresses. During this stage of glandular enlargement the organisms can be found in small numbers in juice secured from a puncture made in the gland with a hollow needle. This period of primary symptoms (chancre and adenitis) includes part of what is known as the period of secondary incubation, which intervenes between the appearance of the chancre and that of the secondary symptoms. It usually lasts about six weeks, During this time the organisms are multiplying in the lymph-nodes and occasionally entering the blood. What fate the organisms meet when they reach the blood in small numbers is not yet known, but the slow invasion suggests that those first enter- ing are destroyed, and that it is only when their numbers are great and their virulence increased that they suddenly become able to overcome the defenses and permit the development of the secondary symptoms. The period of secondary symptoms corresponds to the invasion of the blood by the parasite. It may continue from one to three years, during which time the patient suffers from general symptoms, fever, etc., probably due to intoxication and local symptoms, such as alopecia, exanthemata, etc., due to local colonization of the organisms. At the end of this period a partial immunity, such as is seen in other infectious diseases (malaria), develops, the organisms disappear from the blood, the general local and constitutional disturbances recover, and the ‘patient may 720 Syphilis be well. Should he continue to harbor some of the micro-parasites, however, there may be an insidious sclerosis of the blood-vessels and parenchymatous organs consequent upon the growth and mul- tiplication of the parasites, or there may be after many years a period of tertiary symptoms characterized by the sudden appear- ance of severe lesions in which the parasites are very few in number. The specific organisms are present in juice expressed from the primary lesion, in juice from the buboes and enlarged lymph-nodes; in the blood, in the roseola, and all of the secondary lesions, and sparingly in the tertiary lesions. In congenital syphilis they reach the fetus from the ovum, the spermatozoén, or the blood of the mother. Prenatal death from syphilis is accompanied by lesions in which enormous numbers of the organisms can be found, and furnishes the best tissues for their experimental demonstration and study. Lesions.—The lesions of syphilis are so numerous that the reader is referred to works on pathology and dermatology for satisfactory descriptions. Here it may suffice to say that though diverse in appearance and location, they have certain features in common. The first of these, and that which naturally places syphilis among _the infectious granulomata, is the lymphocytic infiltration of the tissues, with which all of the lesions begin. The second is a peculiar form of necrosis—slimy when superficial, gummy when deep—with which they terminate. The third is a tendency toward excessive cicatrization. Diagnosis.—It is now possible to make a certain and early diag- nosis of syphilis by the recognition of the specific organisms, and as the difficulty of treatment is in proportion to the stage at which the disease arrives before treatment, it should never be neglected. I. Staining —The expressed lymph from a carefully cleaned freshly abraded primary lesion can be stained by Giemsa’s method, or, as is much better and more certain, by Stern’s method, with nitrate of silver, or by the use of India ink. II. Dark-field Examination—For those who possess the “dark- field illuminator” or some similar apparatus with the proper lamp, direct examination of the fluid expressed from the lesions can be made, and the living, moving organisms recognized. This should be the quickest method of diagnosis, though it takes practice. III. Serum Diagnosis—Wassermann and Bruck have devised a laboratory method of making the diagnosis of syphilis by test- ing the complement fixing power of the patient’s serum. This method, now known as the “‘Wassermann reaction,” (q.v.) is given elsewhere in complete detail. The success of the von Pirquet cutaneous tuberculin reaction in assisting the diagnosis of tuberculosis led to experiments on the part of a number of investigators—Meirowsky, Wolff-Eisner, Tedeschi, Nobe, Ciuffo, Nicholas, Favre, and Gauthier and Jodas- Diagnosis 727 shon—to obtain analogous reaction in syphilis by applying extracts of syphilitic tissues to the scarified epiderm of syphilitics. Some reactions were observed, but Neisser and Bruck found that similar reactions occurred when a concentrated extract of normal liver was applied, and to such reactions which could not be looked upon as specific, Neisser applied the term “‘ Umstimmung.” After having successfully achieved the cultivation of Treponema pallidum, Noguchi* resolved to try the effect of an application of an extract of the organisms applied to the skin, in the hope that it might provoke a reaction useful for diagnosis. To this end he pre- pared two cultures, one in ascitic fluid containing a piece of sterile placenta, the other in ascitic fluid agar also containing a piece of placenta. After permitting them to grow under strictly anaérobic conditions at 37°C. until luxuriant development occurred, the lower part of the solid culture was carefully cut off, the tissue fragment removed, and the rich culture carefully ground in a sterile mortar, the thick paste being diluted from time to time by adding a little of the fluid culture. The grinding was continued until the emulsion became perfectly clear, when it was heated to 60°C. for one hour upon a water-bath and 0.5 per cent. of carbolic acid added. When examined with the dark-field illuminator, 4o to 100 dead trepone- mata could be seen in every field. Cultures made from the sus- pension remained sterile and inoculation into rabbits’ testicles was without result. This extract of the treponema culture he calls Juetin. When it was applied to the ear of a normal rabbit, by means of an endermic injection with a fine needle, an erythema appeared, but faded within forty-eight hours, the skin resuming its normal appearance, but when it was applied to the ear of a syphilized rabbit, at the end of the forty-eight hours the redness developed into an induration the size of a pea and persisted from four to six days, disappearing in ten days. In one case a sterile pustule developed. Luetin was tested by Noguchi and his colleagues upon 400 cases: 146 of these were controls, 177 syphilitics, and 77 parasyphilitics. In the controls there was erythema without pain or itching, which disappeared without induration within forty-eight hours. In the syphilitics at the end of forty-eight hours there was an induration in the form of a papule 5 to 10 mm. in diameter, surrounded by a zone of redness and telangiectasis. This slowly increased for three or four days and became dark bluish red. It usually disappeared in about a week. Sometimes the papule underwent vesiculation and sometimes pustulation. It always healed kindly without in- duration. In certain cases described as torpid, the erythema cleared away and a negative result was supposed to have resulted, when suddenly the spots lighted up again and progressed to vesiculation or pustulation. In 3 cases there were constitutional symptoms— * “Journal of Experimental Medicine,” 1911, XIII, p. 557- 728 Syphilis malaise, loss of appetite, and diarrhea. Noguchi found that the reaction is specific, that it is most striking and most constantly present in tertiary, latent tertiary, and congenital syphilis. It, therefore, forms a valuable adjunct to diagnosis, seeing that it is most evident in precisely those cases in which the Wassermann reaction is most apt to fail. A few early cases energetically treated with mercury and salvarsan give marked reactions. A few old cases fail to give it. SPIROCHAZTA REFRINGENS (SCHAUDINN AND HOFFMANN) This spiral organism, though given the name by which it is now known by Schaudinn and Hoffmann, was probably first described by Donné under the name Vibrio lineola. It is probably a frequent organism of the skin and mucous mem- branes, and occurs in greatest numbers in lesions of the genitalia because of the smegma upon which it customarily lives. It is present in most primary lesions of syphilis, but is no less frequently found in non-syphilitic lesions, such as bal- anitis, venereal warts, and genital carcinoma. It is also found in the mouth and on the tonsils. According to Hoffmann and Prowazek’* it is not entirely harmless, but has a pathogenic action, and some of the complicating lesions of syphilis as well as some of the destructive diseases of the genitals may be intensified by it. They found it pathogenic for apes. Morphologically, it is much broader than Treponema pallidum, its spiral waves are much coarser and less regular. It is easy tostain by all methods and is hence easily found. It has been cultivated by Noguchi. t ***Centralbl. f. Bakt.,” etc., 1906, XLI. t ‘Journal of Experimental Medicine,” May 1, 1912, xv. CHAPTER XXXIV FRAMBESIA TROPICA (YAWS) TREPONEMA PERTENUE (PALLIDULUM) (CASTELLANI) Tuts peculiar, specific, infectious, contagious, chronic febrile disease of the tropics is characterized by the appearance upon the skin of one or more primary papular lesions—the yaws—bearing some semblance to raspberries, and by subsequent malaise, fever, and other constitutional disturbances. These are later followed by the appearance of a second crop of small papules which grow tothe size of a pea or a small nut or may grow to be as large as apples, which become covered with firm scabs and gradually cicatrize. The patient either recovers or suffers from relapses and the appearance of further crops of the lesions. The duration of the disease varies from a few weeks to several years. In most cases the constitutional dis- turbances occur only at the period preceding the development of the eruptions and for a short time afterward. Little children frequently die; older children and adults may die of exhaustion in case extensive lesions with marked ulcerations develop. The patients usually recover and pigmented areas remain for some time where the lesions have occurred. The disease appears to have been known since 1525, when Oviedo became acquainted with it in St. Domingo. It has always been very puzzling because it bears so many resemblances to syphilis; but the peculiar raspberry-like character of the primary lesion, its dispo- sition to occur upon the face, mouth, nose, eyes, neck, limbs, fingers, and toes, as well as upon the genitals, seem to point in another di- rection, and all authorities now admit that it is not syphilis, but an independent disease. It occurs only in tropical countries, and is most frequent in equatorial Africa on the west coast, from Senegambia to Angola. It also occurs in West Soudan, Algeria, the Nile Valley, and in the islands about the east coast of Africa. It has been seen rarely in South Africa. In Asia it occurs in Malabar, Assam, Ceylon, Bur- mah, Siam, Malay Peninsula, the Indian Archipelago, Moluccas, and China. It is also endemic in many of the islands and archipelagos of the southern Pacific. The disease rarely makes its appearance in the United States, and it is of interest to know that Wood* has been able to collect nine such cases from the literature. *“A merican Journal of Tropical Medicine,” 1915, 11, No. 7, p. 431. 729 730 Frambesia Tropica Specific Organism.—The cause of the disease was unknown until the discovery of Treponema pallidum, which opened a way for its investigation. Castellani* was quick to seize the opportunity, and in the same year in which Schaudinn and Hoffmann discovered the cause of syphilis, announced a similar organism as the cause of yaws. At the time of discovery he called it Spirocheta pertenuis and Spirocheta pallidula, but it is now recognized as a treponema and is called Treponema pertenue. Morphology.—The organism so closely resembles Treponema pallidum that it is rather by knowing the source from which the organism was derived than by any morphologic distinctions that the two are separated. It is said to be a little shorter than T. Fig. 297.—Yaws (photograph by P. B. Cousland, M. B., Swatow, China). pallidum, measures 7 to 20 w in length, is closely and regularly coiled, and is said to have rounded ends. Staining.—It stains like its close relative, palely with most of the dyes. The silver nitrate, the India ink methods, and the other methods of staining Treponema are all appropriate, both for demonstrating it in smears from the lesions or in sections of tissue. Cultivation.—The organism seems not yet to have been cultivated. Pathogenesis.—Castellanit has succeeded in infecting monkeys with the scrapings from yaws papules. The infection usually re- sulted in a local lesion, though there was also a generalized infection, for he found treponemata everywhere in the lymph-nodes. When the inoculation material was filtered and all of the organisms re- moved, the infectivity was destroyed. Blood and splenic substance from the infected monkey, containing no organisms other than the * “Brit. Med. Jour.,” 1905, 11, 282, 1280, 1330. Tt “Jour. of Hygiene,” 1907, vil, p. 558. Diagnosis 731 treponemata, was infective for other monkeys. When monkeys successfully inoculated with yaws are afterward infected with syph- ilitic virus they are notimmune. On the other hand, monkeys that have successfully been inoculated with syphilis are not immune against yaws. Levaditi and Nattan-Larrier* differ from Castellani in this particular, and found that monkeys infected with syphilis are refractory to yaws. Castellani was able, by means of com- plement-fixation tests, to detect different specific antibodies for syphilis and yaws. Halberstadtert has successfully infected orang-outangs. There is no doubt but that in their clinical manifestations and in their etiology frambesia and syphilis are closely related. Diagnosis.—In addition to the clinical manifestations which are usually quite sufficient for diagnosis, the discovery of the Treponema pertenue is of assistance. It can usually be found without difficulty by expressing the serum from a lesion and staining it by any of the methods recommended for Treponema pallidum, the India-ink method being the most simple. The Wassermann reaction is always positive in yaws, hence is of no use for purposes of differential diagnosis. * “Ann. de l’Inst. Pasteur,” 1908, XXII, 260. t ‘“‘Arbeiten a. d. Kaiserl. Gesund.,”’ 1907, XxVI, 48. CHAPTER XXXV ACTINOMYCOSIS ACTINOMYCES Bovis (BOLLINGER) General Characteristics.—A parasitic, pathogenic, aérobic and optionally anaé- robic, non-motile, non-flagellate, non-sporogenous (?), liquefying, pathogenic, branched micro-organism, belonging to the higher bacteria, staining by ordinary methods and by Gram’s method. In 1845 Langenbeck discovered that an infectious disease of cattle known as “wooden tongue” and “lumpy jaw,” and later as actinomycosis, could be communicated to man. The observation, however, was not published until 1878, one year after Bollinger* had discovered the actinomyces, the specific cause of the disease. Israel} wrote the first important paper upon actinomycosis as a disease of man, though the best paper on the subject is probably Fic. 298.—Bovine actinomycosis. that by Bostrom,{ who made a careful study of the microscopic lesions of the disease. Its first manifestations are usually found either about the jaw or in the tongue, and consist of considerable sized enlargements which are sometimes dense and fibrous (wooden tongue), some- times suppurative in character. In sections of tissue containing these nodular formations, small yellowish granules surrounded by some pus can usually be found. These granules, when examined be- neath the microscope, consist of peculiar rosette-like bodies—the “ray-fungi” or actinomyces. Distribution—The actinomyces is best known as a parasitic organism associated with actinomycosis. That it occurs rather * “Deutsche Zeitschrift fiir Thiermedizin,” 1877. } “Virchow’s Archives,” 1874-78. { “Berl. klin. Wochenschrift,” 1885. ‘‘Beitrige zur Path. Anat. und zur Allg. Path.,” 1890, mx. 732 Morphology 733 widely in nature seems to be indicated by the fact that cases of infection have been known to occur from the spines of barley and other cereals. Berestnew* succeeded in isolating the organisms from hay and straw. Morphology.— A complete ray-fungus consists of several distinct zones composed of different elements. The center is composed of a granular mass containing numerous bodies resembling micro- cocci or spores. Extending from this center into the neighboring tissue is a radiating, branched, tangled mass of mycelial threads. Fig. 299.—Colony or granule of actinomyces in a section through a lesion showing the Gram-stained filaments and hyaline material and also the pus- cells surrounding the colony (Wright and Brown). In an outer zone these threads are seen to terminate in conspicuous, club-shaped, radiating forms which give the colonies their rosette- like appearance. The clubs are inconspicuous in the human lesions of the disease. The pleomorphism of the organism and the branched network it forms class it among the higher bacteria in the genus Actinomyces. When the clumps formed in artificial cultivations of the parasite are properly crushed, spread out, and stained, the long mycelial threads, o.3-0.5 uw in thickness, occasionally show flask- or bottle- like expansions—the clubs—at the ends. These probably depend * “Centralbl. f. Bact.,” etc., Ref., 1898, No. 24. 734 ~ s Actinomycosis upon gelatinization of the cell-membrane of the degenerating para- site. The club is one of the chief characteristics of the organism. In sections of tissue the radiating filaments are very distinct, and the terminal clubs are all directed outward, closely packed together, and making the whole mass form a rounded little body often spoken of as an “‘actinomyces grain.”” When tissues are stained first with carmin and then by Gram’s method, the fungous threads appear blue-black, the clubs red. The cells of the tissues affected and a larger or smaller collection of leukocytes form the surrounding re- sisting tissue-zone. The fungus is of sufficient size to be detected in pus, etc., by the naked eye. As it usually has a bright yellow color it is not in- frequently spoken of as a ‘“‘sulphur grain.” Fig. 300.—Actinomyces granule crushed beneath a cover-glass, showing radial striations in the hyaline masses. Preparation not stained; low magnifying power (Wright and Brown). Cultivation.— The actinomyces fungus may be grown upon arti- ficial culture media, as has been shown by Israel,* Wolff, and others. “The granules, preferably obtained from closed lesions, are first thoroughly washed in sterile water or bouillon and then crushed and disintegrated between two sterile slides. If one is working with a bovine case it is well to examine microscopically the disintegrated material, after mixing it with a drop or two of bouillon under a cover- glass, to see if filamentous masses are present. If they are not, or if they are very few, proceed no further, but begin again with another granule, because the granules in bovine lesions sometimes contain no living filaments at all, but may be composed entirely of de- generated structures from which no growth of micro-organisms can be * “Virchow’s Archives,” cxv. Cultivation 735 generated. If filaments and filamentous masses are found to be present in the granule, then the disintegrated products of the granule are to be transferred by means of the platinum loop to melted 1 per cent. dextrose agar-agar contained in test-tubes filled to a depth of 7 or 8 centimeters which have been cooled to about 40°C. The material is to be thoroughly distributed throughout the melted agar-agar by means of the loop, and the tube then placed in the in- cubator. Several tubes should be prepared. At the same time a number of granules, after washing in sterile water or bouillon, should beplaced on thesides of sterile test-tubes plugged with cottonand kept at room temperature in thedark. The sugar-agar tubes inoculated as above described should be examined from day to day for the presence of the characteristic colonies in the depths of the agar-agar. If very many colonies of contaminating bacteria have developed in .the tubes, it will probably be very difficult or impossible to isolate the specific micro-organism. If there are few or no contaminating colonies, then the colonies of the specific organism should be ex- pected to develop in the course of two or three days to a week. If a good number of living filaments of the micro-organism have been distributed throughout the agar, the specific colonies that develop will be very numerous in the depths of the agar, especially throughout a shallow zone situated about 5 to 12 mm. below the surface of the agar-agar. When the presence of the char- acteristic colonies has been determined, slices or pieces of the agar containing colonies are to be cut out of the tube by means of a stiff platinum wire with a flattened and bent extremity. A piece of the agar-agar is to be placed upon a clean slide and covered with a clean cover-glass. It is to be examined under a low power of the micro- scope, and an isolated colony selected for transplantation. By obvious manipulations, under continuous control of microscopic observation, the selected colony, together with a small amount of the surrounding agar-agar is to be cut out, care being taken to be sure that no other colony is present in the small piece of agar- agar containing the colony. Thesmallpiece of agar-agar thus cut out should not havea greatest dimension of more than2mm. The piece of agar-agar is then transferred from the slide by means of a platinum loop to a tube of sterile bouillon where it is thoroughly shaken up to free it from any adherent bacteria. If there be any reason to believe that the small piece of agar has been very much contaminated with bacteria, it should be washed in a second tube of bouillon, then the piece of agar-agar is to be transferred by means of the platinum loop to a tube of melted sugar-agar cooled to 40°C. It should be immersed deeply in the agar and the tube placed in the incubator. If the colony thus transferred to the agar-agar is capable of growth, in the course of some days it will have formed a good- sized colony from which transplants in various culture-media may be made.” 730 Actinomycosis ae a. a Fig. 301.—Colony of actinomyces with well-developed “clubs” at the periph- ery in a nodule in the peritoneal cavity of a guinea-pig inoculated with a cul- ture from another guinea-pig. Paraffin section. Low magnification (Wright). (Photograph by Mr. L. S. Brown.) Fig. 302.—A colony of actinomyces in a nodule twenty-eight days old in the peritoneal cavity of a guinea-pig inoculated with a culture from another guinea- pig (Bovine case). The “‘clubs” are well developed and show some indications of stratification. Paraffin section. XX 750 approx. (Wright). (Photograph by Mr. L. S. Brown.) ; Cultivation 737 From such anaérobic cultures the micro-organism can, after a few generations, be made to grow upon the surface of solid media, where it invariably forms rounded nodular, elevated masses. | | RO eee roa ote ae ee Pri * Fig. 303.—Actinomycosis; glycerin-agar cultures: A, Discrete rounded colonies after about ten days’ incubation at 37°C.; B, limpet-shaped colonies three and a half months old; C, lichen-like appearance frequently seen; the growth is three and a half months old (Curtis). Blood-serum.—Upon blood-serum the nodular growths present a yellowish or rust-red color, and are surrounded with a whitish down 47 738 Actinomycosis of fine threads. The colonies adhere closely to the culture-media and are so firm that they crush with difficulty. If the surface be scraped, spores and fine threads may be secured. If the mass be crushed, branched filaments may be secured. The colonies become confluent in the course of time, and a thick wrinkled membrane is produced. The growth liquefies blood-serum. Gelatin.—In gelatin puncture cultures an arborescent growth occurs and the gelatin is liquefied. Agar-agar.—Upon agar-agar.and glycerin agar-agar the growth is similar to that upon blood-serum. The agar-agar turns brown as the culture ages. Bouillon.—In bouillon the growth occurs in the form of large granules if allowed to stand quietly; of numerous small granules if frequently shaken up. The granules are similar in structure to those formed upon the dense media. The bouillon does not become clouded. Potato. —Upon potato the wwe resembles that upon blood- serum, but is slower in developing. The color is reddish-yellow and the white down early makes its appearance. Eggs.—The organism can also be grown in raw eggs, into which it is carefully introduced through a small opening made under aseptic precautions. In the eggs long, branched mycelial threads are formed. . The chovattenbtie rosettes so constantly found in the tissues are never seen in, artificial cultures. . Metabolism:—There seems to be some jae of opinion as to the oxygen requirement of actinomyces. Israel, Bostrém and others state that it grows best when provided with a free oxygen supply. Wright found it to grow best under anaérobic conditions. It does not ferment sugar, and does not evolve gas. It liquefies gelatin and blood-serum but does not coagulate milk. Some strains seem to produce a small quantity of orange-red pigment. A small amount of soluble toxin appears in culture-filtrates. Temperature.—In well established strains accustomed to sap- rophytic life, growth progresses slowly but continuously at 20°C. (room temperature). Freshly isolated cultures just being started will only grow at 37°C. Growth ceases at a point between 45°C. and 50°C. Wright found the organism killed after an hour at 60°C. Virulence.— When the actinomyces is grown upon artificial media the virulence is retained for a considerable time. Different strains show varying degrees of pathogenesis, some being almost or quite non-pathogenic, others virulent. The difficulty of making successful injections of the laboratory animals limits our power to accurately gauge the virulence. Pathogenesis.—Actinomycosis is almost peculiar to bovine animals, but sometimes occurs in hogs, horses, and other animals, and rarely in human beings. The disease can with difficulty be Pathogenesis 739 inoculated into experiment animals, the introduced fungi either be- coming absorbed or encapsulated by connective tissue and not grow- ing. In the abdominal cavities of rabbits the peritoneum, mesentery and omentum show typical nodules containing the actinomyces rays in cases of successful inoculation. Mode of Infection.—The manner by which the organism enters the body is not positively known. In some cases it may be by direct Le x a: Se 2 | Fig. 304.—Section of liver from a case of actinomycosis in man (Crookshank). inoculation with infectious pus, but there is some reason to believe that the organism occurs in nature as a saprophyte, or as an epiphyte upon the hulls of certain grains, especially barley. Woodhead has recorded a case where a primary mediastinal actinomycosis in the human subject was apparently traced to perforation of the posterior pharyngeal wall by a barley spikelet accidentally swallowed by the patient. 740 Actinomycosis Cases of actinomycosis are fortunately somewhat rare in human medicine, and do not always occur in those brought in contact with the lower animals. The fungi may enter the organism through the mouth and pharynx, through the respiratory tract, through the digestive tract, or through wounds. The invasion has been known to take place at the roots of carious teeth, and is more liable to occur in the lower than in the upper jaw. Israel reported a case in which the primary lesion seemed to occur external to the bone of the lower jaw, as a tumor about the size of a cherry, with an external opening. Two cases of the dis- ease observed by Murphy, of Chicago, began with toothache and swelling of the jaw. A few cases of dermal infection are recorded. Elsching* has seen a case in which calcified actinomyces grains were observed in the tear duct. When inhaled, the organisms enter the deeper portions of the lung and cause a suppurative broncho-pneumonia with adhesive inflammation of the contiguous pleura. After the formation of the pleuritic adhesions the disease may penetrate the newly formed tissue, extend to the chest-wall, and ultimately form external sinuses; or, it may penetrate the diaphragm and invade the abdominal organs, causing interesting and characteristic lesions in the liver and other large viscera. Lesions.—The degree of chemotactic influence exerted by the organism seems to depend upon the tissue affected, upon the pecu- liarity of the animal, and upon the virulence of the organism. When an animal is but slightly susceptible, and especially when the tongue is affected, the disease is characterized by the formation of cicatricial tissue—‘‘wooden tongue.” If, on the other hand, the animal be highly susceptible and the jaw-bone affected, suppuration, with the formation of abscesses, osteoporotic cavities, and sinuses, are apt to be noticed. - This form of the disease is called “lumpy jaw” in ‘cattle. Before the nature of the affection was understood it was con- founded with diseases of the bones, especially osteosarcoma. From the tissues primarily affected the disease spreads to the lymphatic glands, and eventually to the lungs. Israel has pointed out that certain cases of human actinomycosis begin in the peribron-_ chial tissues, probably from inhalation of the fungi. But few cases recover, the disease terminating in death from ex- haustion or from complicating pneumonia or other organic lesions. * “Centralbl. f. Bakt. u. Parasitenk.,” xvi, p. 7. CHAPTER XXXVI MYCETOMA, OR MADURA-FOOT Actinomyces Mapur (VINCENT) General Characteristics.—A non-motile, non-flagellate, sporogenous (?), non-liquefying, non-aérogenic, chromogenic, aérobic and. optionally anaérobic, branched, parasitic organism belonging to the higher bacteria, staining by ordi- nary methods and by Gram’s method, and pathogenic for man. A curious disease of not infrequent occurrence in the Indian prov- ince of Scinde and of rare occurrence in other countries is known as mycetoma, Madura-foot, or pied de Madura. Although described as peculiar to Scinde, the disease is not limited to that province, but has been met with in Madura, Hissar, Bicanir, Delhi, Bombay, Baratpur, Morocco, Algeria, and in Italy. In America less than a dozen cases of the disease have been placed on record. In India it almost invariably affects natives of the agricultural class, and in nearly all cases is referred by the patient to the prick of a thorn. It usually affects the foot, more rarely the hand, and in one instance was seen by Boyce to affect the shoulder and hip. It is more com- mon in men than in women, individuals between twenty and forty years of age suffering most frequently, though persons of any age may suffer from the disease. It is insidious in onset, no symptoms being observed in what might be called the incubation stage of a couple of weeks’ duration, except the formation of a nodular growth which gradually attains the size of a marble. Its deep attachments are indistinct and diffuse. The skin over it becomes purplish, thick- ened, indurated, and adherent. The ball of the great toe and the pads of the fingers and toes are the points most frequently invaded. The lesions progress very slowly, and in the course of a few months form distinct inflammatory nodes. After a year or two the nodes begin to soften, break down, discharge necrotic and purulent mate- rial, occasioning the formation of ulcers and sinuses. The matter discharged from the lesions at this stage of the disease is a thin serum, and contains occasional fine round pink or black bodies, similar to actinomyces “grains,” described, when pink, as resem- bling fish-roe; when black, as resembling gunpowder. It is upon the detection of these particles that the diagnosis rests. According to the color of the bodies found, cases are divided into the pale or ochroid . and melanoid varieties. The progress of the disease causes an enormous enlargement of the affected part. The malady is usually painless. ; : 741 742 Mycetoma, or Madura-foot The micro-organismal nature of the disease was early suspected. In spite of the confusion caused by some who confounded the disease with “‘guinea-worm,”’ Carter held that it was due to some indigenous fungus as early as 1874. Boyce and Surveyor found that the black particles of the melanoid variety consisted of a large branching septate fungus. Pale Variety.—Kanthack was the first to prove the identity of the fungus with the well-known actinomyces, but there seems to be considerable doubt about the identity of the species. Fig, 305.—Mycetoma. Dorsum of foot showing sinuses, some of which are covered by hard brownish crusts (courtesy of Dr. John W. Perkins). Morphology.—Under the microscope the organism was found by Vincent* to be branched and belong to the higher bacteria. It consists of long, branched bacillary threads forming a tangled mass. In many of the threads spores could be made out. He was unable to communicate the disease to animals by inoculation. Cultivation.—Vincent succeeded in isolating the specific micro- organism by puncturing one of the nodes with a sterile pipette, and **Ann, de l’Inst. Pasteur,” 1894, VII, 30. Lesions 743 cultivated it upon artificial media, acid vegetable infusions seeming best adapted to its growth. It develops scantily at the room tem- perature, better at 37°C.—in from four to five days. In twenty to thirty days a colony attains the size of a little pea. Bouillon.—In bouillon and other liquid media the organisms form little clumps resembling those of actinomyces. They cling to the glass, remain near the surface of the medium, and develop a rose- ° or bright-red color. Those which sink to the bottom form spheric balls devoid of the color. Gelatin.—The growth in gelatin is not very abundant, and forms dense, slightly reddish, rounded clumps. Sometimes there is no color. There is no liquefaction. Agar-agar.—Upon the surface of agar-agar beautiful rounded, glazed colonies are formed. They are at first colorless, but later become rose- colored or bright red. The ma- jority of the clusters remain isolated, some of them attaining the size of asmall pea. They are usually um- bilicated like a variola pustule, and present a curious appearance when the central part is pale and the pe- riphery red. As the colony ages the red color is lost and it becomes dull white or downy from the formation of aerial hyphae. The colonies are very adherent to the surface of the medium, and are of almost carti- Hib: Sebestretnonipeess aneds laginous consistence. ure in a section of diseased tis- Milk.—The organism grows in sue (Vincent). milk without causing coagulation. Potato.—Upon potato the growth of the organism is meager and slow, with very little chromogenesis. The color-production is more marked if the potato be acid in reaction. Some of the colonies upon agar-agar and potato have a powdery surface, either from the formation of spores or of aerial hyphe. Lesions,—Microscopic study of the diseased tissues in myce- toma is not without interest. The healthy tissue issharply separated from the diseased areas, which appear like large degenerated tubercles, except that they are extremely vascular. The mycelial or filamentous mass occupies the center of an area of degeneration, where it can be beautifully demonstrated by the use of appropriate stains, Gram’s and Weigert’s methods being excellent for the purpose. The tissue surrounding the nodes is infiltrated with small 744 Mycetoma, or Madura-foot round cells. The youngest nodules consist of granulation-tissue, whose development is checked by early coagulation-necrosis. Giant- cells are few. Not infrequently small hemorrhages occur from the ulcers and sinuses of the diseased tissues; the hemorrhages can be explained by the abundance of small blood-vessels in the diseased tissue. Fig. 307.—Melanoid form of mycetoma. Section showing black granules and general features of the lesions as they appear under a low-magnifying power. Zeiss a2 (James H. Wright). : Fig. 308.—Melanoid form of mycetoma, showing structure and appearance of the hyphe of the mycelium obtained from the granules. Zeiss apochromat; 4 mm. (James H. Wright). The Melanoid Form of mycetoma has been carefully investigated by Wright* and appears to depend upon an entirely different micro- organism properly classed among the hyphomycetes. Itis probably identical with the organism described by Boyce and Surveyor. In the case studied, Wright found the diseased tissues, consisting * “Journal of Experimental Medicine,” 1898, vol. 11, p. 421. The Melanoid Form 745 of several of the pads of the toes, to be either translucent and myxo- matous or yellowish and necrotic in appearance. The black granules were embedded in the tissue and appeared mulberry-like and less than 1 mm.indiameter. They were firm, and when enucleated and pressed between cover and slide did not crush. Only after digestion with a solution of caustic potash and careful teasing could the Fig. 309.—Melanoid form of mycetoma. Two bouillon cultures showing the powder-puff ball appearance. In one the black granule is seen in the center of . the growth (James H. Wright). Fig. 310.—Melanoid form of mycetoma. Potato culture of the hyphomycete obtained from the granules. The black globules are composed of a dark brown fluid (James H. Wright). granules be resolved into the hyphz of the mold. The central part of the granule formed a reticulum, with radiating, somewhat clavate elements projecting from it. In sections of tissue it was found possible to stain the fungus with Gram’s and Weigert’s stains, though prolonged washing removed most of the dye. 746 Mycetoma, or Madura-foot Cultural Characteristics—Enucleated granules carefully washed in sterile bouillon and then planted upon agar-agar afforded cultures of the mold in 25 out of 65 attempts. The growth began in five or six days, appearing on solid media as a tuft of delicate whitish filaments, springing from the black grain, and in a few days covering the entire surface of the medium with a whitish or pale brown felt-work. Upon potato this felt-work sup- ports drops of brownish fluid. The long branched hyphe thus formed were from 3 to 8 in diameter, with transverse septa in the younger ones. The older hyphz were swollen at the ends. No buds were observed. No fruit organs were detected. In fluid media the filaments radiated from the central grain with the formation of a kind of puff-ball. Eventually the whole medium becomes filled with mycelia and a definite surface growth forms. The general characteristics of the fungus are well shown in the accompanying illustrations from Wright’s paper. CHAPTER XXXVII BLASTOMYCOSIS BriasTtomyces DERMATITIDIS (GILCHRIST AND STOKES) THE first case in which yeasts or blastomycetes were definitely connected with disease seems to have been published by Busse.* He observed a case of tibial abscess in a woman thirty-one years of age, who died about a year after coming under observation. Post- mortem examination showed numbers of broken-down nodular for- mations upon the bones, and in the spleen, kidneys, and lungs. In all of these lesions he found, and from them he cultivated, an yeast, which, when introduced in pure culture into animals—mice and rats—proved infective forthem. He called the organism Saccharo- myces hominis, and the affection in which it was found ‘‘Saccharo- mycosis hominis.” In May, 1904, three months before the appearance of Busse’s paper, Gilchrist exhibited to the American Dermatological Associa- tion in Washington, microscopic sections from a case of cutaneous disease, in which peculiar bodies, recognized as plant forms, were found. After the appearance of Busse’s papers, Gilchristt more fully described and illustrated his findings, calling the lesions “‘blastomycetic dermatitis.” Though much work upon pathogenic blastomycetes has been published and pathogenic forms of these micro-organisms have been described by Sanfelice,{ Rabinowitsch,§ and others, the chief and almost the sole form in which these infec- tions make their appearance is a dermal infection known as “blastomycetic dermatitis.” The infection usually begins with the formation of a papule upon the tace or one of the extremities, which suppurates and evacuates minute quantities of viscid pus. The lesion crusts and begins to heal, but at the periphery new and usually minute foci of suppuration occur, so that while the original lesion tends to heal very slowly, with much cicatricial formation, it is always spreading. The progress is usually slow, and Gilchrist’s first case spread only 2 inches in four years. Though the progress is slow, it is sure, and there is no tendency to spontaneous recovery in most cases, nor is the condition modified by treatment. The patients may die from intercurrent disease or *“Centralbl. f. Bakt. u. Parasitenk.,” 1894, XVI, 175. + “Johns Hopkins Hospital Reports,” 1, 269, 291. t“Centralbl. f. Bakt. u. Parasitenk.,”’ 1895, XVII, 113, 625; XVIII, 521; XX, 219 § “Zeitschrift fiir Hygiene,” etc., 1896, XXI, 11. 747 748 Blastomycosis from a generalization of the blastomycetic infection, which not in- frequently happens. After the work of Gilchrist had made clear the symptomatology and parasitology of the disease, a number of other cases were reported, and Ricketts* published an excellent and lengthy summary of all the cases with references to all of the literature up to that date. An- other very interesting paper by Montgomery,f{ published in 1902, contains a splendid atlas of photographs of the various lesions and of the cultures. In addition to the cutaneous blastomycosis, a second form is also occasionally seen, and is known as Coccidioidal granuloma. It seems to have been first observed by Posadas and Wernicket and has been carefully studied by Ophiils.§ In this form of the disease the lesions are in the internal organs, macroscopically and . Fig. 311.—Cutaneous blastomycosis (Montgomery). microscopically resemble tubercles, and can only be differentiated from them by the presence of the blastomyces and the absence of tubercle bacilli. The lungs may be affected, and Walker and Montgomery|| mistook a case for miliary tuberculosis of the lungs. According to Evans** the disease seems to have a predilection for the central nervous system. There seems to be little reason for believing that there is any other difference than that of distribution between the blastomycetic dermatitis and the blastomycetic granuloma, or that they are caused by different micro-organisms. Regarding the organisms, however, we are by no means sure that there are not several species. * “Jour. Med. Research,” 1901, 1, 373. } “Jour. Amer. Med. Assoc.,” June 7, 1902, 1, 1486. . t Jour. de Micro-organismen,” 1891, Xv, 14. § “Jour. Experimental Medicine,” 1905, vi, 443. Ophiils and Mofit, “ Phila. Med. Jour.,” 1900, v, 1471. ll “Jour. Amer. Med. Assoc.,” 1902, XXXVI, 867. “Jour. of Infectious Diseases,” 1909, VI, 535. Cultivation 749 Specific Organism.—The organism presents a variety of appear- ances which may be thus brought together: First, there are round and elliptical disk-like bodies that some regard as spores, others as the primitive or yeast form. These measure 10 to 30 uw in greatest diameter, are distinctly doubly contoured, highly refracting, and, though sometimes clear and transparent, are frequently granular and vacuolated. From them buds may grow, as in the yeasts, or hypha may form, as in oidium. In artificial cultivations the hypha may form a tangled mycelium. Staining.—The organisms are usually better found without staining. They do not stain with aqueous anilin dyes, but are pene- trated by warm thionin, alkaline methylene-blue, and polychrome methylene-blue. In sections of tissue stained with hematoxylon Fig. 312.—Giant cell from a cutaneous lesion in blastomycosis, showing a group of blastomyces (Montgomery). and eosin they show as uncolored circles; with thionin and alkaline methylene-blue they may take a blue color. Cultivation.—The organism grows readily upon artificial media when once started, but the primitive culture is difficult to secure, because the cocci and other associated organisms are more numerous than the blastomyces and outgrow it. It seems most satisfactory to first infect a guinea-pig with the organism from the skin, and then start the cultivation from its lesions than to attempt it directly from the pus from human dermal lesions. When the human lesions are internal, pure cultures are easily started. Gilchrist and Stokes* were able to start cultures directly from the dermal lesions. Hiss and Zinsser recommended that this be done * “Journal of Experimental Medicine,” 1898, 1, 53. — 750 Blastomycosis by greatly diluting the culture material, so as to separate the contained organisms widely. Many culture-media prove appropriate, glycerin agar-agar and agar-agar containing 1 per cent. of dextrose being excellent. When once isolated the organism is easily Ey growing by transplanting every month or two. The colonies appear in a few days as small round hemispheric dots with numerous prickles about the surfaces. Later they have a moldy appearance from the development of aérial hypha. They are almost purely aérobic, those on the surface growing well, those deeply seated in the medium scarcely at all. Agar-agar Slants.—These at first show a creamy white layer that becomes quite thick, and is moldy and fluffy on the surface. After Fig. 313.—Blastomyces dermatitidis. Budding forms and mycelial growths from glucose agar (Irons and Graham, in “‘ Journal of Infectious Diseases’’). a few weeks the agar-agar begins to turn yellow and later may be- come brown, though the growth itself remains white and unchanged. The growth is firmly attached to the agar. When old, the growth wrinkles. Bouillon.—The growth is not luxuriant. The medium is not clouded and contains fluffy flocculi of stringy .viscid material. Sugars added to the medium may be fermented. Gelatin.—Growth takes place with aérial hypha. Liquefaction does not occur or is very slow. Potato.—Abundant growth with aérial hypha. Milk.—Not coagulated, not acidified, slowly digested. There is some difficulty in describing the cultures, as different authors describe them quite differently, evidently having different organisms or different strains under observation. Transmission 751 Pathogenesis.—The organisms are pathogenic for guinea-pigs, rabbits, and dogs, in which an abscess, not infrequently followed by a generalized infection, takes place. Lesions.—The human lesions vary somewhat. Gilchrist’s first case resembled lupus vulgaris, other cases present an exaggeration — ,of the ulcerative element. Cases have also been mistaken for Fig. 314.—Cultures of Blastomyces dermatitidis upon solid culture-media : (Montgomery). syphilis. The intractable character of the lesions is suggestive, and the finding of the micro-organisms in the viscid pus ispathognomonic. Upon section the lesions still resemble lupus and other tuberculous lesions, but here again the absence of tubercle bacilli and the presence of the blastomyces enable diagnosis to be made. Transmission.—The disease is transmissible. The source of in- fection is not known. CHAPTER XXXVIII RINGWORM TRICHOPHYTON TONSURANS (MALMSTEN) TINEA trichophytina, ringworm of the scalp, herpes tonsurans, tinea circinata, ringworm of the body, herpes circinatus, tinea unguium, onychomycosis, tinea imbricata, herpes desquamans, tinea versicolor, pityriasis versicolor, erythrasma, etc., are diseases with well-marked clinical manifestations and differences, all of which may be comprehended under the general term dermatomycosis, and are caused by closely related forms of parasitic fungi, whose generic and specific differences are matters of considerable uncertainty. That certain of the diseases affect hairy parts and others hairless parts of the body, that still others occur about the nails, and that some are superficial and practically saprophytic, while others pene- trate more deeply and are undoubtedly parasitic, do not necessarily point any more conclusively to essential differences in the infecting organisms than to accidents of infection and variations in resisting power. A review of the literature leaves the student with a deplor- able confusion of ideas, and a feeling that the synonomy is too com- plicated and the use of terms too loose to permit of systematic re- construction. The discovery of micro-organisms in these lesions seems to have been made in 1842 by Gruby,* who found mycelial threads and spores on and in the hairs, and in 1860 by Hebra,t} between the epi- thelial cells. The organism appears to have been called Trichophy- ton tonsurans in 1845 by Malmsten. The parasitology of all of the trichophyton infections was thoroughly studied by Sabouraud,t and the old species, Trichophyton tonsurans, divided into eleven new species, to which four others have since been added, so that there are now described, with or without justification, Trichophyton crateriforme, T. acuminatum, T. violaceum, T. effractum, T. ful- matum, T. umbilicatum, T. regulare, T. pilosum, T. glabrum, T. sulphureum, T. polygonum, T. exsiccatum, T. circonvulatum, T. flavum, and T. plicatili. : In general it is customary to divide the organisms into two groups, Trichophyton microsporon and T. megalosporon, the former having large, the latter small, spores. ; *“Compt.-rendu,” Paris, 1842, xv. { “Handbuch der spezulien Path. u. Therapie von Virchow,” m1, 1860. i“ Ann. de dermat. et de syphilis,” 1892, 111; 1893, 1V; 1894, Vv; “Monats- hefte,” 1896, 576; “La Practique dermatologique. Trichophytie,” 1900. 752 Cultivation 753 Morphology.—The trichophyton parasites form delicate mycelia composed of somewhat slender septate hypha. They can best be observed by extracting one of the hairs, including its root, from the diseased area, or if the affection be upon a hairless part of the body, by scraping off some of the epiderm, and mounting the material between a slide and cover in a drop of caustic potash solution (20 per cent.). Under these circumstances the spores are conspicuous and so numerous as to give the impression that they occur in rows in a kind of structureless zodglea upon the outside of the hair. In some cases, however, especially in Trichophyton megalosporon, the hypha may be observed with the spores ,. _. ass inside. The hypha measure from 2 to : 8 » in diameter, are usually simple, ‘and rarely divide. The spores are from 2 to 3 « in diameter in the Tri- chophyton microsporon and 7 to 8 yu in T. megalosporon. The former is the more common upon the hairless, the latter upon the hairy, portions of the skin, Cultivation.—The organisms may be secured in pure culture without much difficulty, except for the annoying and almost constant presence of the associ- ated bacteria of the skin. By crushing the hairs and scales in a mortar with Fig. 315.—Invasion of a hu- some dilute KOH solution, and then, man hair by trichophyton: A, epee é Points at which the parasitic after thoroughly distributing the spores fungi coming from the epider- through the alkaline medium which dis- mis are elevating the cuticle solves many of the bacteria, plates can be ue ee _ be made with high dilutions, or drops diameters (Sabouraud). of the fluid may be spread over potato, which is an excellent medium for the culture. The culture, whether upon agar-agar, glycerin agar-agar, glucose agar-agar, gelatin, or potato, occurs in the form of a tuft of white mycelial filaments with aérial hypha, looking like a tiny white powder-puff. Upon the surface of liquid culture-media the growth appears as a thick wrinkled pellicle with aérial hypha of velvety appearance. As the cultures grow older the lower mycelial growth becomes yellowish and wrinkled, but the aérial hypha maintain the velvety white appearance. Some of the colonies are ‘ mammillated, some are crateriform. Gelatin is liquefied, the growth floating upon the surface of the fluid. As the cultures become very old and dry, the velvety appearance is lost and the surface becomes powdery. The powder detaches only when the growth is touched, and does not shake off. 48 954 Ringworm Pathogenesis.—The trichophytons are pathogenic for man and for the lower animals. They spread from animal to animal by con- tact and by inoculation. Men, dogs, cats, horses, sheep, goats, and swine all suffer from the infection. The growth of the hypha be- tween the epidermal layers causes a chronic inflammation, with hyperemia, desquamation, the formation of some papules, and oc- Fig. 316.—Trichophyton tonsurans. Primary cultures twenty days old on maltose agar-agar. Natural size (Sabouraud). casional pustules. The invasion of the hair-follicles and the growth of the fungi into the hairs cause them to become fragile and break off, as well as to loosen and drop out. The name ‘‘barber’s itch” results from the frequent transmission of the infection by the barber’s razors. The disease is easily trans- missible and precautions should always be taken to prevent its dissemination. CHAPTER XXXIX FAVUS ACHORION SCHONLEINII (REMAK) Favus, or tinea favosa, is a chronic and destructive form of dermatomycosis occurring in man and animals, caused by a fungus iscovered in 1839 by Schénlein,* and called in his honor Achorion sthénleinii by Remak in 1845. This fungus is widely distributed and affects mice, cats, dogs, rabbits, fowls, and men. Among human beings it usually occurs upon the scalp and other hairy parts of the body, though it may also affect the hairless portions and even attack the roots of the nails. It is more frequent in children than in adults. The fungus grows vigorously and usually forms a small sulphur yellow disk about the base of a hair. The edges of this detach, become everted, and the whole eventually separates, forming the “scutulum,” or characteristic lesion of the disease. The reac- tion is more marked, the damage done greater, and the disease less tractable than in other forms of dermatomycosis. The infection seems to take place in most cases by way of the hair- follicles, and the mycelia of the fungi grow into and about the hairs, invading the epiderm, and causing atrophy of the hair-follicles by pressure. Beneath and around the scutulum, which consists chiefly of the fungi, an inflammatory reaction takes place, and leukocytic invasion and ulceration cause the scutulum to separate. Although usually confined to the skin, the favus infection may ex- tend to the mucous membranes, and Kaposi and Kundratf' have reported a case in which favus fungi were found to have invaded the stomach and intestines. The disease runs a course sometimes extending over many years. Crockert mentions a case that recovered after thirteen years. It may remain localized upon the scalp or may spread itself over much of the skin surface. When the lesions are large they give off an odor suggesting that peculiar to white mice. In recovering, the lesions leave considerable cicatricial scarring, and atrophy of hair- follicles, sweat, and sebaceous glands is inevitable. The Specific Organism.—The Achorion schénleinii is probably better regarded as a group of closely related organisms than as a single one. Indeed, Quincke has described three species, though they are not yet generally accepted. * Miiller’s “Archiv,” 1839. + “Ann. de Dermat. et de Syph.,” 1895, p. 104. } “Diseases of the Skin,” Phila., 1903, p. 1276. 755 756 Favus The organism can be studied by extracting a hair and examining it in KOH or NaOH solution (20 per cent.), or by teasing a scutulum in the same medium and examining with a low power. Sections of the skin may also be made when possible. The fungus resolves itself into mycelial threads, and spores. The .._ Fig. 317.—Favus. Hairs of a child infected with Achorion schénleinii. A, Magnified 260 diameters; B, 75 diameters. The large rounded bodies are drop- lets of air which always appear after treatment with 40 per cent. potash solution. The linear threads are the fungi. Some are without spores, others contain rows of spores (Sabouraud). scutulum consists of masses of sporesat the center and about the hair, with mycelia containing spores at the edges. From the mycelium hypha are given off, the ends being knobbed or clavate. The mycelial threads are highly refractile, contain granular proto- plasm, and are of varying thickness. Sometimes the terminal Cultivation . 757 hypha are simple, sometimes they fork, the ends are always clavate. The hypha give off buds at right angles along their course. The spores are oval, doubly contoured, as a rule, but may be round or pointed and more or less polyhedral. They measure 3 to 8 » in length and 3 to 4 » in breadth. They form the great central mass of the scutulum, which is the oldest part. Together with them one finds a number of detritus granules, fat-droplets, and occasional swollen epidermal cells. : Cultivation.—The cultivation of the achorion is quite easy if care be used, for the central part of each scutulum contains pure cultures of the organism. The best method is probably that of Kral,* which is as follows: ‘“‘A good deal of the material from the scutula is rubbed up in a porcelain mortar dish with previously heated diatomaceous earth, with a porcelain pestle, without exerting too much pressure. Melted agar-agar tubes are then inoculated with Fig. 318.—Achorion schdnleinii. Fig. 319.—Achorion schénleinii. Four weeks old culture upon beer- Pure culture, four weeks old, on wort agar-agar (Kolle and Wasser- beerwort agar-agar (Kolle and mann). Wassermann). two or three loopfuls of the crushed material and poured into Petri dishes. Greater dilution can be made if desired. The plates are examined after forty-eight hours. Cultures may, however, be directly made with material from the center ofascutulum. Agar-agar should be used, as the cultures grow best at the body temperature. The young colonies that appear in forty-eight hours can easily be transplanted by fishing under a lens. The best medium was found by Sabouraud to consist of maltose, 4; peptone, 2; fucus crispi, 1.5; water, 100. : As the colonies eventually become quite large it is recommended that, instead of tubes, they be made in Erlenmeyer flasks, the trans- ‘planted little colonies being placed at the center of the medium con- gealed upon the bottom of the flask. The appearance of the cultures varies considerably. Plaut gives . *See Plaut, in Kolle and Wassermann’s ‘‘Pathogene Mikrodrganismen,” I, p. 108. 758 Favus two principal varieties: (1) The waxy type—a yellowish mass of a waxy character with radiating folds and a central elevation. Asa rule no aérial hyphe, but occasionally short aérial hypha. (2) The downy type—this forms a white disk with a velvety or. plush-like covering of white aérial hypha. Sometimes instead of white the color is yellowish or reddish. A marked dimple with a smaller elevation usually occurs in the middle, and there may be radial folds. Pathogenesis.—The micro-organism is pathogenic for mice, rabbits, cats, dogs, hens, and men, in all of whom typical scutula form. Scutulum formation has not been observed in guinea-pigs. The disease readily spreads from animal to animal by direct contact and by indirect contact by the use of combs, hair-brushes, and simi- lar objects. On account of its chronicity, its obstinacy, its disfig- urement, and its transmissibility it is a dangerous disease, and one that requires prompt isolation of the patient and the utmost care for the prevention of contagion. CHAPTER XL SPOROTRICHOSIS SPOROTRICHOSIS is a somewhat rare disease of man, caused by various members of a genus of fungi known as Sporotrichum (Link- Saccardo). The first occurrence of human sporotrichosis seems to have been reported by B.R.Schenck.* Theisolated micro-organism in this case was carefully studied and later was found to be identical with a micro-organism isolated from another case of somewhat simi- lar character studied by Hektoen and Perkins,{ who described it as Sporotrichum schenckii. In 1903 de Beurmannft and his associates took up the subject in France, and Lutz and Splendore§ in Brazil, and new cases were reported. On Aug. 8, 1908, the writer of an editorial in the Journal of the American Medical Association was able to give references to 14 cases of the disease. In 1912 Ruediger|| was able to collect 57 cases that had occurred in the United States. In 1912 de Beurmann** reported that more than 200 cases had been put on record since the beginning of his work in 1903. It will thus be seen that the recognition of the cause of the disease and the im- provement in diagnosis that followed it have made possible the detection of many cases of a disease not recognized until 1900. According to de Beurmann who has shown great interest in the ’ affection and prosecuted its study with much industry, the known organisms of the Sporotrichum group comprise the following: Sporotrichum schencki. Sporotrichum beurmanni. Sporotrichum beurmanni var. asteroides (Splendore). Sporotrichum beurmanni var. indicum (Castellani). Sporotrichum jeanselmei. Sporotrichum gougerati. Specific Organism.—The sporotrichum is characterized by a filamentous spore-bearing mycelium. The filaments are fine, meas- uring about 2 # in diameter, partitioned, colorless, much branched and tangled. The chief feature is the occurrence of the spores which are situated along the length of the recumbent filaments either on * Bulletin of the Johns Hopkins Hospital,” Dec., 1898. + “Journal of Experimental Medicine,” 1900, Igot, V, 77. t Ann. de Dermatologie et Syphilographie, 1906, 538. § “Centralbl. f. Bakt., etc.,” 1907, XLV, Orig., 632. ! “Jour. of Infectious Diseases,” 1912, XI, 193. ** “British Medical Journal,’’ Aug. 10, 1912, Il, 2900. 759 460 Sporotrichosis their extremities or on branches. They are arranged in cylindrical cuffs about 10 in size andin glomeruli. As a matter of fact the spores are readily isolated from one another. They arise one by one in variable numbers along the mycelium, but as a rule in very large quantity in each segment of the thallus. There is no apparent order in their arrangement. So long as it remains on the filament the spore appears pear-shaped. It is attached by a very fine sterigma, from 1-2 “in length and fromo.5 win width. When shed, the spore is oval. Its dimensions vary from 3-5—6 m in length and from 2-3-4 mw in breadth. The form, the distribution and the brown color of the spores and their fructification in the form of cylindrical cuffs, arranged in branches at the extremities of the filaments, constitute together Fig. 320.—Sporothrix schenckii. Fig. 321.—Sporothrix schenckii. . Margin of living hanging-drop cul- Slant culture on glucose agar, eight ture (gelatin) X about 150 (Hektoen days old (Hektoen and Perkins, in eh ae in “Jour. of Exper. ‘‘Jour. of Exper. Med.”). ed.’’). with the original substratum of the fungus, a group of characters which differentiates Sporotrichum beurmanni sharply from all other sporotrichs (Matruchat). Hektoen and Perkins thus describe Sporotrichum schenckii: The threads of the mycelium are seen to be doubly contoured; the proto- plasm is somewhat granular and interrupted at fairly regular in- tervals by transverse septa; the diameter of the threads varies some- what, the average being about 2 u; the branches are not frequent and do not bear any fixed relations to the septa. In the hanging-drop cultures the relations of the conidia to the mycelium are very nicely shown. The spore-bearing branches which grow out in a radiating manner from the central feltwork, are commonly tipped by a cluster Staining 461 of from three to six or more conidia, which, in the case of the larger cluster, are attached by the smaller end to the slightly expanded extremity of the branch. Similar ovate buds also arise from the sides of the hyphe at shorter or longer intervals. The spores are also doubly contoured and granular, resembling very much yeast cells. These various features are well shown in the photographs on the accompanying plate. The attachment, by means of the short pedicles of the spores to the threads, is very easily severed as shown by the difficulty in obtaining stained preparations with the spores iz situ. When placed in the hanging drop, the conidia grow out into one or more straight germ tubes which spring from either or both ends or from! the side. These embryonal threads again give rise to lateral or terminal buds, which in all particulars resembles the spores and some of which form branching spore-pro- ducing threads, so that in the early stages very peculiar-looking bodies are produced. In the tissues and in the pus from the lesions of the disease the parasites have quite a different appearance, assuming a short oblong form like a thick short ba- cillus 3-5 uw in length and 2-3 » broad, basophilic, finely granular and surrounded by avery delicate, colorlessmembrane. de Beurmann has watched the growth of this degraded form of the parasite into the filamentous and spore-bearing form, in ar- tificial culture. Staining.—The micro-organism is much : as Fig. 322.—Abscesses better examined in thefresh andlivingcon- caused” by — sporothrix dition than dried and stained as it greatly schenckii. Arm of patient s Stace i 1 changes in appearance through shrinking. ee ee It does stain, however, with the usual dyes, (Hektoen and Perkins, in and retains Gram’s stain except when “Jour. of Exper. Med.”). the alcohol washing is unduly prolonged. Cultivation, Colonies.—Upon agar-agar, at the end of about forty-eight hours, the colonies appear elevated, whitish, with feathery . fringes and some filamentous downgrowths into the medium. Upon gelatin the downward growth results in liquefaction and the growing colonies sink below the surface. Agar-agar.—Along the needle track made by a stroke culture, a grayish granular slightly elevated line with feathery edges forms in forty-eight hours and in seventy-two hours assumes the form of a 762 Sporotrichosis band with numerous transverse wrinkles; in a couple of days more “the surface becomes more markedly corrugated and looks like a chain of mountains on a map.” About the seventh day, the growth, which has increased in thickness, becomes light brownish in color, the margins being smooth and wavy and marked by shallow transverse grooves. Still later the growth becomes dark brown, wrinkled and covered by a delicate fuzz. The agar-agar becomes brown. Gelatin.—In gelatin punctures the growth is confined to the upper strata. Lateral branches are sent out from the needle track. A sur- face felt-like mass of mycelial threads forms beneath which the gela- tin liquefies. The surface growth sinks into the liquid medium. Blood-serum.—The growth is somewhat like that on agar-agar but not so massive. Itis apt to be covered by a white down. Bouillon.—The growth which is fairly abundant, is in flakes and tufts, shreds and filaments that settle to the bottom or cling to the sides. A white surface film is apt to cover the liquid. No fermenta- tion occurs in sugar bouillon. Potato.—Upon potato tufts form in twenty-four hours. These have a brownish-gray color and soon become raised, wrinkled, and frosted. The potato is darkened. Milk.—The growth is scanty and owing to the opacity of the medium, difficult to see. Litmus milk is not acidified. There is no coagulation. Vital Resistance.—The optimum temperatureisabout 37°C. The organism grows slowly at room temperature but in the end attains pretty much the same magnitude as those kept in the thermostat. The death point is 55°C. for one hour. Hektoen and Perkins found S. schenckii killed in four and one-half minutes at 60°C. Metabolic Products.—The organism produces no curdling or proteolytic ferments for milk or blood-serum. It does, however, liquefy gelatin. It grows aérobically or anaérobically, but under the latter conditions it does not produce acid or ferment sugars, or evolve gas. No indol is formed. It has a remarkable tolerance for acid media. Page, Frothingham and Paige* found that it grew well in media at least six times as acid as those ordinarily employed for bacteria. They also found that the organism does produce acid in media containing dextrose. Distribution in Nature.—According to de Beurmann, the sporotri- chum is a widely distributed micru-organism in nature. It has been found on green vegetables, upon bark, thorns, potatoes, various im- plements, in the soil, and in infected insects. Pathogenesis.—The sporotrichum is pathogenic for men, horses, rats, dogs, and white mice. It would seem as though the rarity of its occurrence as a patho- genic agent signified that it was by no means easy for it to effect the * “Jour. Med. Research,”’ 1910, XXII, p. 129. Pathogenesis 763 invasion of the animal body. However, de Beurmann mentions a man wounded in the forehead by a coster’s awl whom he believed to have been infected by a cap, used to conceal the untreated wound, that usually lay on the fruit and vegetables that filled his barrow; a market woman infected by the salad that she was in the habit of handling all day. Dominici and Duval report a case following a cut inflicted while peeling a potato; Saint-Girons, a case following the prick of a thorn of a barberry bush. A patient of Lutz’s was inocu- lated through the bite of a cat; one of Wyse-Lauzun’s through the bite of a parrot. Perkins’ case was that of a child that had abraded a finger with a hammer. de Beurmann found the organism ‘in the pharynx of healthy persons “carriers,” whose saliva might, therefore, beinfectious. He believes that infection may take place through the hair-follicles; that the healthy skin may be penetrated, and that the healthy. gastro-intestinal mucosa may be penetrated. Lesions.—The seat of primary disturbance is the seat of a chronic and destructive ulceration from which the disease spreads to nu- merous secondary foci chiefly bylymphaticmetastasis. Hektoen and Perkins describe the appearance of the primary lesion in Perkins’ case of infection by S.schenckii, thus: “thefinger from the first to the third joints is swollen to twice its original size, presenting in the center a deep, well-defined, sharp, undermined ulceration, the size of a ten-cent piece. The base of the ulceration is rough and covered with grayish-looking pus. This, when sponged away, leaves a bright red surface; the ulcer extends through the whole thickness of the skin. Surrounding the ulcer over about one-half of the infiltrated area, are a large number of vesicles and a few pustules. The dorsal surface of the hand and the extensor surface of the forearm present a chain of swollen lymphatics along which are about twenty nodules the size of a small pea to a large hazelnut. ... This little patient does not complain of much pain.” In the course of two months Perkins opened and treated more than twenty abscesses resulting from the enlargement and softening of the nodes. De Beurmann and Gougerot found that the most characteristic lesion of the skin is a nodule in which three processes are found, some- times mixed up in an irregular manner, but most frequently arranged concentrically. ‘In the center an abscess containing polymorpho- nuclear leukocytes and macrophages; in the intermediate zone an area of degenerated epithelioid giant cells and tuberculous follicles, and at the periphery a proliferation of basophile lymph and con- nective-tissue cells or a fibro-cellular infiltration.” ‘‘The structure of the sporotrichoma is, therefore, very closely allied to that of the lesions caused by syphilis, tuberculosis, and by the agents of chronic suppuration, and it resembles sometimes the one, sometimes the other.” De Beurmann and Raymond, 1903, and de Beurmann and Gougerot, 1906, describe three clinical varieties of the disease. 764 Sporotrichosis 1. Disseminated Gummatous Sporotrichosis.—The onset is insidious. An accident usually leads to the discovery of the first gummata. The number of gummata may vary up tooo. The first takes origin from any point in the sub- cutaneous tissue. Others disseminate themselves over the whole body. Each gumma has an autonomous evolution which is the same for all. At first it is a little rounded mass, hard, elastic, painless and invariably in the subcutaneous tissue. The mass evolves rapidly in the direction of softening and in four or six weeks terminates in a characteristic cold abscess. When it undergoes lique- faction, it contains a fluid which is at first transparent, viscid, gummy, and with purulent streaks and later becomes opaque, thick and purulent. It does not undergo complete softening, and when it becomes fluctuating we find a central cup-shaped depression surrounded by a firm and resisting zone, and when its contents are evacuated, there remains round the empty pocket a persistent and indurated ring. 2. Disseminated Subcutaneous, Gummatous Sporotrichosis with Ulceration. —In this variety, the subcutaneous gummata after having passed through the phases described above, become hypodermo-dermic and destroy the skin by” ulceration more or less rapidly, sometimes in twenty days, sometimes in two or three months. Asa rule the ulcers are tuberculous in appearance. Frequently the ulceration is at first no more than a narrow fistula from which oozes a viscid, colorless and sometimes reddish pus or a yellowish serous fluid. 3. Mixed forms are frequent. When the disease has existed for a long time it presents a complete clinical picture. Side by side are lesions of different age with different tendencies and different appearances; tuberculous looking, syphilitic looking, ecthymous, rupial and furuncular. There may be associated lesions of thelymphatics, and lesions of the dermis, epidermis, mucous membranes, muscles, osseous tissues, synovial membranes, eyes, epididymis, etc. 4. Localized Sporotrichosis——The sporotrichum penetrates by a cutaneous lesion at the site of which it produces an initial lesion, which may be called the “‘sporotrichotic chancre.” Then it gradually invades the lymphatics and a hard lymphatic cord studded with gummata—centripetal gummatous sporotrichosis— makes its appearance. Sometimes the lymph-nodes of the region react, but this is not constant. The disease remains localized to the region primarily affected. Sporotrichosis of the mucous membranes, of the muscles, of the bones and joints, of the synovial membranes, of the eye, of the epididymis, of the kidney, and of the lung are described by de Beurmann.* — Bacteriologic Diagnosis.—Diagnosis by immediate and direct — examination of the pus either stained or unstained is difficult be- cause the parasites are few in number, and are present in the bacil- lary form that is so difficult to recognize. The approved method is to carefully cleanse the skin over one of the closed lesions, disinfect it with iodine, and then puncture the abscess with a hollow needle. The pus obtained is spread plenti- fully over the surface of culture-media in a number of tubes and stood in the incubating oven. The characteristic colonies should appear in from four to twelve days. Should cultures be on hand in the laboratory at the time a case presents itself for diagnosis, two other methods may be employed. - 1. The Agglutination Test.—A suspension of the spores from cul- tures of the sporotrichum will be agglutinated by the patient’s serum in dilutions of 1-400 to 1-500 on the average. 2. The Complement-fixation Test.—The entire culture is used as an antigen, the serum of the patient and guinea-pig complement em- ployea as usual. As, however, oidium, actinomyces, discomyces *“Brit. Med. Jour.,” 1912, Il, 293. Bacteriologic Diagnosis 765 and other fungi give the same degree of fixation, the method lacks precision. Bloch has also employed an intra-dermic injection of a sterilized emulsion of the sporotrichum for purposes of diagnosis. In twenty-four hours, patients with sporotrichosis give a marked re- action in the form of an indurated nodule with a broad reddish surrounding areola. ~BIBLIOGRAPHIC INDEX ABBOTT, 85, 156, 198, 207, 322, 586, 605 Abbott and Bergey, 587, 588 Abbott and Gildersleeve, 411, 693 Abbott and Welch, 413 Abderhalden, 140, 143 Abderhalden and Freund, 142 Abel, 110, 460, 548 Abel and Claussen, 574 Abel and Léffler, 594, 602, 621 Abelous, 324 Achard and Bensaude, 614 Adami, 66, 73 Adami and Chapin, 608 Afanassiew, 441 Agnew, 23 Agramonte, Reed, and Carroll, 538 Agramonte, Reed, Carroll, and Lazear, 536 . Alav, 438 Albrech and Ghon, 391 Albrecht, 552 Alessi, 84 Alt, 408 Altmann, 223 Alvarez and Tavel, 692 Anaximander, 17 Anderson and Forst, 384 Anderson and Goldberger, 541, 542 Anderson and McClintic, 253, 255, 256, 257, 258, 260, 261 Anderson and Rosenau, 103,, 104, 132 Andrewes and Gordon, 299 Andrewes and Horder, 314 Andrews, 175 Anjeszky, 157 Aoyama, 546 Aristotle, 17 Arloing, 96, 360, 683, 686 Arnaud, 631 Arning, 702 Arnold, 171 Arrhenius, 24 Arustamoff, 37 Aschoff, 110 Aschoff and Gaylord, 166 Audanard and Eberth, 324 Auld, 448 Austin, 517 Axenfeld, 387, 408, 409, 452 BaBES, 313, 324, 372, 429, 433) 434, 467, 710, 714 Babes and Cornil, 433, 572 Babes and Lepp, 98, 380 Babes and Proca, 684 Bacot, 554, 560, 561, 562 Bacot and Martin, 554 Bail, 119, 123 Baker, 507 Baldwin and Trudeau, 680, 681 Baldwin, Graham, and Stewart, 337» 339 Banti, 212, 452 Barbagallo and Casagrandi, 654 Barker, 324 Barker and Flint, 557 Barker (L. F.), 324 Barlow, 655 Barron, 507 Bass, 474, 484 Bass and Johns, 484, 485 Bassett and Duval, 648 Bassett-Smith, 294, 468, 469 Bateman, 513 Baumgarten, 74, 432, 656, 670, 672, 7II Baumgarten and Walz, 682 Bauzhaf and Steinhardt, 130 Bayon, 510, 529 Beattie and Dickson, 503, 504, 527 Beck and Pfeiffer, 465 Beck and Proskauer, 51, 667 Becker, 307 Beckman, 608 Beebe, Park, and Biggs, 424 Behrend, 438 Behring, 24, 98, 127, 128, 120, 177, 345, 426, 456, 670, 676, 683, 689 Behring and Kitasato, 99, 131 Behring and Nissen, 109 Behring and Nocht, 177 Beitzke, 437 Belfanti and Carbone, 116, 133 Beninde, 669 Bensaude and Achard, 614 Benzancon, Griffon, and Le Sours, 404 Berestneff, 38 Berestnew, 733 Berg, 438 Bergell ae Meyer, 603 Bergey, 5 Bergey oF Abbott, 587, 588 Bergholm, 71 Berkefeld, 174 Bernheim, 683 Bernheim and Hildebrand, 69 © Bernheim and Popischell, 437 Bertarelli, 720 Bertarelli and Bocchia, 175 Bertarelli and Volpino, 721 Bertrand and Phisalix, 99, 100, 132 Besredka, 315, 387, 443) 558, 594 767 768 Besredka and Metcchnikoff, 268 Besredka and Steinhardt, 104 Besson, 333, 416, 556 Bettencourt and Franca, 392 Beyer, Rosenau, Parker, and Francis, 539 Beyerinck, 64 Bezancon, 321 Bielonovsky, 550 Biggs, 423 Biggs, Park, and Beebe, 424 Bignami, 472 Billet, 478, 479 Billroth, 23, 35, 233 Binger and Wolbach, srs, 516 Biondi, 70, 165 Biondi and Heidenhain, 165 Birch-Hirschfeld, 669 Birt and Lamb, 468 Bitter, 60, 575 Bittu and Klemperer, 692 Blacklock, 521 Blaizot, Nicolle, and Conseil, 498 Blanchard, 25, 482, 492 Blasi and Russo-Travali, 420 Bloch, 765 Blum, 324 Blumer, 324 Bockhart, 72, 306 Boehm, 22 Boland, 323 Bollinger, 37, 732 Bolton, 110, 138 Bolton and Globig, 197 Bolton and Pease, 53 Bolton, Dorset, and McBryde, 626 Bomstein, 423 Bonhoff, 588 Bonney and Foulerton, 452 Bonome, 98, 710 Bonome and Gros, 54 Bonome and Viola, 53 Bordet, 24, 101, 116, 118, 120, 133, 135, 139, 283, 718 Bordet and Gay, 137 : Bordet and Gengou, 100, 280, 294, 441, 442, 443 Bordoni-Uffreduzzi, 327, 448, 452, 6097, 698 Borrel, 556, 559 Borrel and Roux, 350 Bostrém, 732, 738 Botkin, 217 Bousfield, 498 Bowhill, 549 Boxmeyer, 627 Boyce, 741 Boyce and Surveyor, 742, 744 Brault, 507 Braum, 652, 653 Brebeck- -Fischer, 438 Brefeld, 40, 42 Breinl, 498 Brieger, 344, 575, 594 McClintock, and Siffer, Bibliographic Index Brieger and Cohn, 345 Brieger and Ehrlich, 108, 332 Brieger and Frankel, 76, 345, 357, 417, 575, 593 Brown, 400, 401, 404, 405, 412, 532, 739 Brown and Wright, 733, 734 Bruce, 467, 469, 5212, 513 Bruce and Nabarro, 509, 513 Bruce, Nabarro, and Greig, 513 Bruck and Neisser, 727 Bruck and Wassermann, 726 Bruck, Wassermann, and Neisser, 279, 281, 283 Bruckner and Galasesco, 723 Brues and Rosenau, 384 Brumpt, 491, 493, 504, 507, 512, 513, 517, 521, 653, 054 Brunner, 629 Buchner, 32, 108, 109, 135, 217, 219 Buchner and Daremberg, 116 Buerger, 447, 454 Bujwid, 130 Bullock and Hunter, 323 Bumm, 306, 394 Bumm and Nisot, 419 Burn, 523 Burri, 721 Burroughs and McCollum, 428 Burse, 39 Busse, 747 Buswell and Kraus, 602 Biitschli, 472 Buxton, 613, 614 Buxton and Coleman, 611 Buxton and Torry, 106 Buxton and Vaughan, 124] CaBot, 378 Cadio, 690 Calkins, 27, 363, 364, 655 Calkins and Williams, 636 Calmette, 99, 132, 133, 324, 556, 559, 604, 679 Calmette and Guérin, 689 Cameron, 672 — Camus and Gley, 133 Canon, 462 Canon and Pfeiffer, 24 Cantani, 575 Cantanni (A. Jr.), 465 Capaldi, 610 Carbone and Belfanti, 116, 133 Cardan, 17 Carmona y Valle, 536 Carrasquilla, 704 Carroll, 217, 537 Carroll’ and Reed, 539 Carroll, Reed, and Agramonte, 538 Carroll; Reed, Lazear, and Agramonte, 536 Carter, 536, 537, 742 Carter and Hughes, 456 Casagrandi and Barbagallo, 654 Castellani, 25, 508, 729, 730, 731, 759 Bibliographic Index _Cazeneuve, 490 Celli, 472, 478, 647 Celli and Fiocca, 631, 633 Celli and Marchiafava, 386 Celli and Shiga, 615 Centanni and Tizzoni, 683 Chagas, 518, 520, 521, 523 Chamberland, 173, 174, 360 Chamberland and Roux, 98, 332 Chamberland, Pasteur, and Roux, 363 Chantemesse, 590, 602, 604, 694 Chantemesse and Widal, 599, 601, 602, 647 Chapin and Adami, 608 Charin, 53 Charrin, 98, 321, 694 Charrin and Roger, 122, 85 Chauffard and Quénu, 350 Chauveau, 98, 105, 360 Cheinisse, 403 Chenot and Picq, 714 Chester, 27, 36, 230 Chevreul and Pasteur, 20 Cheyne, 82 Chisives, 92 Christmas, 397, 398 Christy, Dutton, and Todd, 509 Cienkowsky, 633 Citron and Wassermann, 288 Ciuffo, 726 Clark, 431 Clark and Flexner, 385 Clark and Howard, 3384 Clarke and Miller, 175 Claudius, 175 Claussen and Abel, 574 Clegg, 699, 701 Clegg and Musgrave, 636, 637, 642, 644 Cobbett, 89, 110, 431 Cohn, 32, 204, 441 Cohn and Brieger, 345 Cohnheim, 656 Colbach, 21 oe and Buxton, 611 oley, 54, 316 Colla, 86 Comte and Nicolle, 494, 531 Comus and Gley, 138 Conn, 80 Conradi, 357 Conradi and Drigalski, 608 Conseil and Nicolle, 542 Conseil, Nicolle and Blaizot, 498 Conseil, Nicolle, and Couer, 541, 542 Cooley and Vaughan, 619 Cooley, Vaughan, and one 75 Coplin, 151 Cornet, 657 Cornevin, 332 3 Cornevin and Thomas, 96 Cornil and Babes, 433, 571 Couer, Nicolle, and Conseil, 541, 542 Councilman, 300, 386, 431 Councilman and Lafleur, 25, 632, 633, 634 49 769 Councilman, Mallory, and Pearce, 423 Countess del Cinch6n, 472 Courmont, 683 Cousland, 730 Coventon and Pelletier, 472 Cowie, 692 Cragg and Patton, 489, 501, 502, 5175 519; 523, 562 cup 635, 636, 639, 641, 642, 643, 644, 55 Crocker, 755 Crooke, 313 Crookshank, 739 Cruveilheir, 131 Cullum, 540 Cumston, 621 Cunningham, 533 Curry, 460 Curtis, 39, 343, 3 56, 357, 459, 667, 737 Cushing, 596, ton 14, 615 Guslee 692, 696, 697 Czaplewski and Hensel, 441 Czenzynke, 462 Czerny, 316 Datrton and Eyre, 467 Daniels, 163 Danysz, 630 Daremberg and Buchner, 116 Darling, 534, 535, 636 d@’Arsonval, 53 Davaine, 22, 353 Davaine and Pollender, 24 Davidson, 471 Davis, 403, 404, 405, 441, 464 Dean, 596 de Beurmann, 759, 761, 762, 763, 764 de Beurmann and Gougerot, 763 de Beurmann and Raymond, 763 De Foe, 543 de Geer, 505 Deichler, 441 Delage, 27 Delépine, 178 Delezene, 102, 134 Delius and Kolle, 465 de Mondeville, 21 Denecke, 583, 588 Denny, 412, 423 Denys, 680 Denys and Van de Velde, 307 De Renzi, 456 de Silvestri, 631 De Schweinitz, 627, 675, 684 De Schweinitz and Dorset, 626 De Schweinitz and Veasy, "408 Descos and Nicholas, 73 Detre, 283 Detweiler, 75 Deutsch, 97 — Deutsch and Feistmantel, 97 Devell, 551 Devonshire, 565 Deycke, 197, 631 Dickson and Beattie, 503, 504, 527 ' 1? di Vestea and Maffucci, 684 Dineur, 123 Dobbin, 337 Déderlein, 440 Déderlein and Winterintz, 71 Doflein, 328, 502 Doleris and Pasteur, 308 Dominici and Duval, 763 Donitz, 111, 345, 350 Donné, 728 Donovan, 525 Donovan and Leishman, 25 Donovan and Patton, 530 Dopter and Vaillard, 651 Dorser, 665 Dorset, 665, 666 Dorset and De Schweinitz, 626 Dorset, Bolton, and McBryde, 626 Dorset, McBryde, and Niles, 626 Douglas and Distaso, 30 Douglas and Wright, 107, 270, 277 Doutrelepont, 692 Draper, 619 Dreyfus, 620 Drigalski and Conradi, 608 Droba, 595 Drysdale, 512 Dubarre and Terre, 691 du Bary, 43 Dubois, 416 Du Bois-Reymond, 53 Duboscq and Leger, 653 Ducrey, 403, 699 Dujardin and Ehrenberg, 26 Dunbar, 588 Diingern, 100, 102, 116, 134 Dunham, 199, 200, 333, 337, 414, 615, 618, 622 Dunham and Park, 648 Durham, 116, 614 Durham and Gruber, 122 Durme, 305 Dutton, 495, 506, 507 Dutton and Forde, 25, 507, 500, 514 Dutton and Todd, 494, 495, 499, 507 Dutton, Todd, and Christy, 509 Duval, 696, 699, 700, 701 Duval and Bassett, 648 Duval and Dominici, 763 Duval and Vedder, 648 EAGER, 544 Eberth, 24, 241, 589, 615, 694 -Eberth and Audanard, 324 Effront, 58 Ehlers, 324 Ehrenberg, 19, 240, 241 Ehrenberg and Dujardin, 26 Ehrlich, 24, 91, 99, 100, 110, 111, 112, I13, 118, 119, 123, 125, 129, 130, 139, 152, 153, 154, 156, 158, 345, 417, 427, 658, 659, 661, 663, 696 Ehrlich and Brieger, 108, 332 Ehrlich and Marshall, 121 Bibliographic Index Ehrlich and Morgenroth, 101, 103, 110, 133, 135, 283 Eichhorn and Mohler, 709, 713, 714 Eisenberg, 123, 230, 240, 241 Eisner, 604 Eisner and Wolff, 680, 726 Elders, 433 Ellermann, 434 Elmassian and Morax, 422 Elsching, 740 Elser, 389 Elser and Huntoon, 393 Elsner, 605, 606, 622 Emery, 413 Emmerich, 616 Emmerich and Liw, 65, 323 Emory, 70 Empedocles, 17 Endo, 610 Engle and Reichel, 369 Eppinger, 38 Ernst, 130, 321, 324, 337, 338 Ernst and Robey, 123 Escherich, 33, 241, 615, 616 Esmarch, 186, 197, 204, 207, 215, 238 Evans, 182, 748 Evans and Russell, 182 Eyre, 44 Eyre and Dalton, 467 FANTHAM and Stephens, 506, 509 Farran, 342 Fasching, 457 Favre, 726 Fehleisen, 308, 318 Fehling, 200 Feistmantel and Deutsch, 97 Feletti and Grassi, 471, 478, 479, 482 Fermi, 60 Fermi and Pernoss, 345 Ferran, 579 Fick, 432 Field, 344 Finkelstein, 324 Finkler and Prior, 580, 581, 588 Finlay, 536, 537 Fiocca, 157, 647 Fiocca and Celli, 631, 633 Firth, 531, 533 Fisch, 684 Fischel and Wunschheim, 110 Fischer (E.), 113 Fish, 120 - Fitzpatrick, 559 Flatten, 386 Flexner, 38, 312, 328, 333, 335, 387, 390 oe 393, 423, 632, 647, 050, 651, Flexner de Clark, 385 Flexner and Harris, 599 Flexner and Jobling, 393 Flexner and Lewis, 381 Flexner and Noguchi, 25, 132, 133, 344» 383, 384 Bibliographic Index Flexner and Shiga, 651 Flexner and Welch, 332, 337, 419 Flint and Barker, 557 Flournoy, Norris and Pappenheimer, 495, 497 Fliigge, 55, 79, 107, 109, 151, 180, 181, 240, 241, 243, 314, 321, 325, 340, 351, 386, 445, 566, 669 Fliigge and Hiss, 179 Foa, 452 Fodor, 107 Foley and Sergent, 498 Forde, 507 Forde and Dutton, 25, 507, 509, 514 Forneaca, 321 Forssner, 120 Forst and Anderson, 384 Foulerton, 37 Foulerton and Bonney, 452 Fournier and Gilbert, 625 Fox and Longcope, 445 Fracastorius, 21 Franca and Bettencourt, 392 Francis and Grubs, 62 Francis, Rosenau, Parker, and Beyer, 539 Frank and Heiman, 143 Franke, 432 Frankel, 55, 89, 215, 216, 226, 243, 244, 332, 358, 362, 387, 388, 432, 443, 444, 452, 457, 495, 571, 574, 5755 576, 582, 584, 591, 599 Frankel and Brieger, 76, 345, 357, 593 Frankel and Pfeiffer, 304, 309, 330, 341, 342, 352, 354, 355, 415, 453, 565, 579, 581, 586, 657, 668, 707 Frankel and Trendenburg, 313 Frankel and Weichselbaum, 328, 458 Frankel and Wollstein, 443 Frankforter, 182 Frankland, 240, 241 Fredericq, 107 Freejmuth and Petruschky, 437 Freire, 536 Freund and Abderhalden, 143 Freymuth, 579 Friedlander, 31, 152, 410, 457, 459, 460, 650 Frisch, 324, 715, 716 Frosch, 419 Frosch and Kolle, 314 Frost, 55, 208, 209, 210, 211, 238, 239 ; Frothingham, 370 Frothingham, Page, and Paige, 762 Frugoni, 667 Fulleborn, 500 Fuller, 188, 242 Funck, 102 GABBET, 661, 696 Gabbi, 452 Gaffky, 318, 319, 589, 599, 633 Gaffky and Koch, 632 Galasesco and Bruckner, 723 Galeotti, 61 77% Coe 54, 553, 631 Galtier, 363 Gamaléia, 443, 450, 575, 584, 586, 588 Garini, 200 Garré, 72, 306 Gartner, 614, 615, 624, 650 Gaspard, 20 Gaultier de Sauvage, 540 Gauss and Schumburg, 31 Gauthier and Jodasshon, 726 Gavefio and Girard, 541 Gay, 104 Gay and Bordet, 137 Gay and Southard, 104 Gaylord and Aschoff, 166 Geddings and Wasdin, 536 Gelston, 75 Gelston and Marshall, 75 Gelston, Vaughan, and Cooley, 75 Gengou and Bordet, 100, 280, 294, 441, 442, 443 Gerhard, 540 Germano and Maurea, 599 Gescheidel and Traube, 135 Gessard, 61, 240, 321 Gheorghiewski, 100, 323 © Ghon, 550, 552 Ghon and Albrech, 391 Ghoreyeb, 719 Ghriskey and Robb, 69, 300 Gibier, 85 Gibson, 130 Giemsa, 163, 365, 366, 368, 384, 726 Giemson, 368 - Gilbert and Fournier, 625 Gilbert and Roger, 690 Gilbert, Zinsser, and Hopkins, 724 Gilchrist, 39, 747, 748, 751 Gilchrist and Stokes, 747, 749 Gildersleeve and Abbott, 411, 693 Gilliland and Pearson, 689 Girard and Gavefio, 541 Gley and Camus, 133 Gley and Comus, 138 Globig and Bolton, 197 Goldberger and Anderson, 541, 542 Goldhorn, 719 Goldschmidt, 389 Golgi, 472, 474, 478, 479 Gomez, 472 Goodby, 70 Goodsir, 233 Goodwin and Sholly, 392 Goppert, 386 Gorden, 160 Gordon, 314, 315, 546, 577 Gordon and Andrewes, 299 Gorgas, 539 Gorham, 62 Gottschalk and Immerwahr, 71 Gottstein, 103 Gougerot and de Beurmann, 763 Gourvitsch, 653 Gradenigo, 324 Graham and Irons, 38, 75° 772 Graham, Stewart, and Baldwin, 337, 339 Graham-Smith, 498 Gram, 152,153,154, 165, 300, 302, 308, 310, 318, 319, 321, 322, 325, 329, 332, 334) 349 351, 352, 354, 384, 385, 388, 380, 393, 394, 395, 398, 400, 401, 403, 406, 408, 409, 41T, 413, 444, 457, 462, 407, 494, 497, 543, 546, 564, 566, 568, 584, 589, 590, 624, 625, 626, 627, 628, 620, 649, 656, 659, 663, 604, 695, 696, 706, 707, 715, 718, 732, 734) 741; 743) 745, 761 Gram and Weigert, 154 Grassi, 475 Grassi and Feletti, 471, 478, 479, 482 Grawitz, 39, 438, 440 Greig, Bruce, and Nabarro, 513 Greite, 133 - Griffon, Benzancon, and Le Sours, 404 Grigorjeff, 631 Grigorjeff and Ukke, 332 Grimme, 146 Grixoni, 342 Grohman, 107 Gromakowsky, 316 Gros and Bonome, 54 Grosset, 440 Gruber, 116, 215 Gruber and Durham, 122 Gruber and Wiener, 578 Griibler, 146, 155 Grubs and Francis, 62 Gruby, 438, 752 Griinbaum, 599 Griinbaum and Widal, 603 Grysez and van Steenberghe, 73 Gscheidel and Traube, 107 Guarniere, 448 Guérin and Calmette, 689 Guiart, 516 Guidi, 438 Guiteras, 539 eee 193, 234, 238, 243, 302, 331, Giinther and Wagner, 721 Gwyn, 598, 614 HaEcKEL, 26 Haffkine, 97, 263, 546, 547, 557, 558; 578, 579, 600 Halberstadter, 731 Hall, 527 Hallein, 438 Hallier, 233 Hamburger, 604 Hamerton, 513 Hamilton, 431 Hankin, 55, 85, 108, 361 Hankin and Leumann, 549 Hankin and Wesbrook, 357 Hansen, 24, 58, 216, 440, 695, 697 Harris, 368, 379, 646 Harris and Flexner, 599 Bibliographic Index Harris and Shackell, 378 Hartmann, 636 Harvey, 118 Harvey and McKendrick, 380 Hashimoto, 574 Hasslauer, 72 Haupt, 409 Hauser, 325, 326 Havelburg, 536, 555 Hebra, 752 Heidenhain, 165 Heidenhain and Biondi, 165 Heider, 588 Heim, 303, 320, 438, 463, 572, 591, 617 Heiman, 396 Heiman and Frank, 143 Heinemann, 359 Hektoen, 309 Hektoen and Perkins, 759, 760, 761, 762, 763 Henle, 22 | Hensel and Czaplewski, 441 Herman, 82 Herzog, 553 Hesse, 219, 234, 235, 610 Hesse and Liborius, 219 Hewlett, 111, 113, 614 Hewlett. and Nolen, 424 Heymans, 111 Heyman-Sticher, 669 Hildebrand, 100 Hildebrand and Bernheim, 69 Hill, 145, 146, 207, 253, 609 Hippocrates, 631 Hirsh, 312 Hiss, 44, 318, 390, 446, 448, 455, 592, 607, 622, 679, 721 Hiss and Fliigge, 179 Hiss and Russell, 648 / Hiss and Zinsser, 36, 188, 310, 319, 387, 396, 447, 448, 456, 580, 614, 708, 749 Hodenpyl, 671 Hodenpyl and Prudden, 686 ' Hoffa, 357 Hoffmann, 495 Hoffmann and Muhlens, 723 Hoffmann and Prowazek, 728 Hoffmann and Schaudinn, 24, 69, es 728, 730 Hofmann, 423, 429, 430, 431, 592 Hégyes, 374, 378, 385 Holmes, 22 Holst, 80, 314 Hopkins, Zinsser, and Gilbext, 724 Horder, 464 Horder and Andrewes, 314 Howard, 420, 429, 431, 452, 460, 487 Howard and Clark, 384 Howard and Perkins, 317 Howard, Jr., 339 Hiickel and Losch, 42 Hughes, 469 Hughes and Carter, 456 Humer, 595 Bibliographic Index ‘Huntemiiller and Lentz, 383 Hunter and Bullock, 323 Huntoon and Elser, 393 Hunziker, 215 Hiippe, 241, 361, 566, 571, 650 Hiippe and Wood, 362 Huxley, 27 Incutey and Nuttall, 122 Trons, 349 Irons and Graham, 38, 750 Irons and Savage, 607 Israel, 732, 734, 738, 740 Issaéff, 122 Issaéff and Kolle, 577 Itzerott and Niemann, 321, 581, 583, 585, 694 Iwanow, 357 JACKSON, 534, 612 Jacob, 619 Jacobsohn and Pick, 388 Jacoby, 120 - Jadkewitsch, 324 Jager, 241, 386, 387 Jamieson and Johnston, 703 Jasuhara and Ogata, 99, 361 Jenner, 93, 95, 163, 263,276 Jez, 602 Jobling and Flexner, 393 Jochmann and Krauss, 441 Jodasshon and Gauthier, 726 Johannsen and Riley, 489 Johns and Bass, 484, 485 Johnson, 509, 614 Johnston and Jamieson, 703 Joos, 123 Jordan, 241, 323, 602, 615 Jordan, Russel, and Zeit, 593 | Jérgensen, 58 ; Justinian, 543 KAENSCHE, 59 Kamen, 348 Kanthack, 742 Kaplan, 290 Kaposi and Kundrat, 755 Karlinski, 299, 324 Karlinski and Lubarsch, 624 Kartulis, 328, 406, 632, 633, 634 Kashida, 606 Kastle, Rosenau, and Lumsden, 594 Kazarinow, 651 Keen, 596 Kehrer, 438 Keidel, 281 Kerr, MacNeal, and Latzer, 71 Kimla, Poupé, and Vesley, 666 Kinghorn and Todd, 498 Kinghorn and Yorke, 513 Kircher, 17, 21 Kirchner, 400, 401 Kitasato, 24, 98, 99, 174, 219, 226, 340, 344, 347, 348, 446, 463, 543, 545, 546, 547, 549, 559, 574, 575, 632 Kitasato and Behring, 99, 131 773 Kitasato and Weil, 219 Kitasato and Yersin, 24 Kitt, 96, 712 wT 105, 411, 575, 631, 656, 675, 0 Klein, 548, 551, 554 Klemperer, 452 Klemperer and Bittu, 692 Klemperer and Levy, 461, 592, 594 Klemperer (G. and F.), 455 Klencki, 620 Klimenko, 443, 654 Kline, 332, 623 Knapp, 431 Knapp and Novy, 497, 500, sor Knapp, Levaditi, and Novy, 497 Knisl, 582 Knépfelmacher, 381 Knorr, 344, 556 Kny, 41 Koch, 22, 23, 24, 50, 106, 178, 196, 201, 204, 205, 206, 207, 220, 222, 223, 237, 252, 308, 324, 329, 352, 353, 358, 359, 406, 407, 475, 485, 495, 497, 499, 504, 514, 565, 568, 560, 579, 571, 574, 575, 576, 582, 585, 588, 589, 633, 634, 656, 657, 658, 660, 661, 664, 665, 670, 671, 676, 677, 680, 681, 682, 683, 685, 686, 687, 725 Koch and Gaffky, 632 Kock (C. L.), gor Kohlbrugge, 71 Kolisko and Paltauf, 419 Kolle, 151, 555, 556 Kolle and Delius, 465 Kolle and Frosch, 314 Kolle and Issaéff, 577 Kolle and Otto, 307, 558 Kolle and Pfeiffer, 594, 600, 602 Kolle and Strong, 558 Kolle and Wassermann, 37, 40, 42, 110, 392, 393, 439, 480, 482, 483, 405, 496, 547, 696, 697, 757 Kolmer, 141, 224, .81, 388, 389,428,429 Koplik, 441 Korn, 693 Kossee and Overbeck, 550 Kossel, 99, 100, 133, 138, 324 Kral, 757 Krannhals, 324 Kratter, 396 Kraus, 100, 116, 120, 398 Kraus and Buswell, 602 Kraus and Levaditi, 374 Kraus and Wernicke, 383 Krauss, 305 Krauss and Jochmann, 441 Krefting, 403 Kronig, 175 Kronig and Menge, 337 Kronig and Paul, 177 Kruger, 53 Krumweide and Park, 687 - Krumweide and Pratt, 434 774 oe 325; 351, 509, 566, 618, 632, 4 Kruse and Pasquale, 632 Kubel and Tiemann, 608, 609 Kiihne, 707 Kundrat and Kaposi, 755 Kurloff, 441 Kurth, 311, 313 Kutcher, 709 Kutschbert and Weisser, 431 Lapse, 478, 479, 482 Laennec, 673 Lafleur and Councilman, 25, 632, 633, 634 Laitinen, 396 Lamar and Meltzer, 451, 460 Lamb and Birt, 468 Lambert, 345, 374, 453 Lambert, Steinhardt, and Poor, 365 Lambl, 631, 633 Lammershirt, 433 Landois, 133 Landsteiner, 102 Landsteiner and Popper, 381 Langenbeck, 438, 732 Laplace, 177 Larkin, 38 Lartigau, 320, 324, 674 Laschtschenko, 669 Lassar, 718 Latapie, 135, 225, 226 Latour, 19 © Latour and Schwann, 19 Latzer, MacNeal, and Kerr, 71 Laurent, 438 Laveran, 25, 471, 472, 474, 477, 478, 479, 482, 494, 509 Laveran and Mesnil, 507, 508, 510, 525 La Wall and Leffmann, 192 Lazear, 538 Lazear, Reed, Carroll, and Agramonte, 536 Leach, 75, 505 Leber, 43, 305, 432 Leclainche and Nocard, 482 Le Dantec, 340 Ledderhose, 323 Leeuwenhoek, 18, 19, 26 Leffmann and La Wall, 192 Leger and Duboscq, 653 Lehman and Neumann, 230, 232 Leichtenstern, 386 Leishman, 163, 270, 276, 277, 499, 525, 526, 528 Leishman and Donovan, 25 Lemoine, 313 Lenglet, 4c5 Lennholm and Miller, 58 Le Noir, 324 Lentz, 648 Lentz and Huntemiiller, 383 Leo, 85, 714 Lepierre, 391 Lepp and Babes, 98, 380 Bibliographic Index Lesage, 240, 621 Lesage and Thiercelin, 324 Le Sours, Benzancon, and Griffon, 404 Leubarth, 313 Leuchs and von Lingelsheim, 392 Leumann 557 Leumann and Hankin, 549 Levaditi, 276, 721 Levaditi and Kraus, 374 Levaditi and Manouelian, 722 Levaditi and McIntosh, 719, 722 Levaditi and Nattan-Larrier, 731 Levaditi and Yamanouchi, 280 Levaditi, Novy, and Knapp, 497 Levene, 676 Levin, 315 Levy, 452, 680 Levy and Klemperer, 461, 592, 504 Levy and Steinmetz, 709 Lewis, 25 Lewis and Flexner, 381 Lexer, 358 Leyden, 603 Libman, 314, 614 Liborius, 216, 219 Liborius and Hesse, 219 Lichtowitz, 433 Liebig, 20 Ligniéres, 679 Limbourg, 611 Lincoln and McFarland, 456 Lindemann, 102 Lindt, 43 Lingelsheim, 304, 310, 386 Link, 759 Linn, 505 Linossier, 438 Linton and Thomas, 509 Lisbon, 553 Lister, 23, 172 Livingstone, 512 Loag and Van der Pluyn, 394 Lockwood, 174 Léffler, 24, 151, 158, 197, 206, 333, 351, 389, 305, 408, 411, 413, 414, 415, 416, 417, 420, 577, O11, 615, 628, 629, 707, 710 Loffler and Abel, 594, 602, 621 Loffler and Schiitz, 24, 566, 706, 711 Longcope, 614 Longcope and Fox, 445 Lord, 400, 401 Losch, 25, 631, 633, 634, 642 Lésener, 599 Low, 522, 599 Low and Emmerich, 65, 323 Low and Sambon, 473 Lowden and Williams, 364, 368, 370, 371 Lubarsch, 109, 360 Lubarsch and Karlinski, 624 Lubarsch and Oestertag, 387 Liibbert, 177 Lubenau, 315 Lubinski, 351 Bibliographic Index Lugol, 152 Lihe, 477 Lumsden, Rosenau, and Kastle, 594 Lutz, 763 Lutz and Splendore, 759 Luzzani, 369 MacCaLtvm, 473, 474, 477 MacConkey, 612 Macfadyen, 449, 594, 602 Macfadyen and Rowland, 76, 594 Macgregor, 631 Mackie, 498, 513 MacNeal, Latzer, and Kerr, 71 Madsen, 24, 102, III, 131 Madsen and Noguchi, 132 Madsen and Salmonson, 115 Maffucci and di Vestea, 684 Mafucci, 690 Magendie, 103 Maggiora, 68, 324, 631 Maher, 619, 659 Malassez, 694 Mallory, 155, 368, 597, 647 Mallory and Wright, 163, 165, 220, 386 Mallory, Councilman, and Pearce, 423 Malmsten, 652, 752 Malvoz, 123 Manceaux and Nicolle, 533 Mann, 369 Mannatti, 305 Manouelian and Levaditi, 722 _ Manson, 413, 472, 473, 477, 488, 506, 507, 520, 655 Manuelian, 365 Maragliano, 683 Marburg, 294 Marchiafava, 472 Marchiafava and Celli, 386 Marchoux, 361 Marchoux and Salimbeni, 494 Marie, 380 Marie and Morax, 346° Marino, 163, 164, 165, 276 Marks, 383 Marmier, 357 Marmorek, 81, 314, 315, 316, 453, 456 Marshall and Ehrlich, rar Marshall and Gelston, 75 Martha, 324 Martin, 127, 132, 323, 357 Martin and Bacot, 554 Martin and Meyer, 500 Martin and Roux, 110 Marx, 146, 377 Masselin, 590 Masselin and Thoinot, 564 Masterman, 532 Matruchat, 760 Matschinsky and Rymowitsch, 407, 409 Matterstock, 692 Mattson, 103 Matzenauer, 433 Maurea and Germano, 599 775 Mayer, 351, 369 McBryde, Dorset, and Bolton, 626 McBryde, Dorset, and Niles, 626 McCarthy and Ravenel, 372 McClintic and Anderson, 253, 255, 256, 257, 258, 260, 261 poe ureers Boxmeyer, and Siffer, 27 McCollum and Burroughs, 428 McConkey, 650 McConnell, 703 McCoy and Smith, 551 McDaniel and Wilson, 424 McFadyen, 689, 709 McFarland, 362, 427, 684 McFarland and l’Engle, 277 McFarland and Lincoln, 456 McFarland and Small, 62 McIntosh and Levaditi, 719, 722 | McIntyre, 75 McKendrick and Harvey, 380 McNeal, 527 McNeal and Novy, 510, 521, 700 Megnin, 512 Meier and Porges, 280 Meirowsky, 726 Melcher and Ortmann, 7o1 Meltzer and Lamar, 451, 460 Menge and Kronig, 337 Mense, 526 Mesnil, 107, 509, 530 Mesnil and Laveran, 507, 508, 510, 525 Messea, 31 Metalnikoff, 102, 134 Metschnikoff, 24, 88, 90, ror, 102, 106, 107, 108, Log, 110, 116, 118, II09, I22, 123, 138, 270, 718 Metschnikoff and Besredka, 268 Metschnikoff and Roux, 718 Meunier, 54 Meyer, 149, 150, 222, 223 Meyer and Bergell, 603 Meyer and Martin, 500 Meyer and Ransom, 346, 347 Michel, 416 Migula, 27, 32, 34, 35, 36, 230, 232, 233, 445, 458, 616, 629, 658, 717 Miller, 69, 70, 272, 273, 274, 275, 276, 433, 494, 588, 595 Miller and Clarke, 175 Miller and Lennholm, 58 Milne and Ross, 494, 495, 499 Miquel, 235 Mitchell, 22 Mitchell and Stewart, 133 Mithridates, 93 Mittman, 68 Moczutkowski, 540 Moffit and Ophiils, 748 Mohler and Eichhorn, 709, 713, 714 Miller, 157, 499, 692, 693 Monnier, 324 Montague, 92 Montesano and Montesson, 349 Montesson and Montesano, 349 776 Montgomery, 73, 748, 749, 751 Montgomery and Walker, 748 Monti, 450 Moon, 366 Moore and Taylor, 709 Morax, 406, 407, 408, 409 Morax and Elmassian, 422 Morax and Marie, 346 Morgenroth, 100, 111, 116, 121 Morgenroth and Ehrlich, 1o1, II0, 133, 135, 283 Mori, 4 58 Moriya, 687 Moro, 108, 679 Morse, 305 Moschcowitz, 349 . Moser, 316 Moses, 695 Mosso, 133 Mott, 515 Motz, 324 Mouton, 107 Much, 659 Muhlens and Hoffmann, 723 Muir and Ritchie, 153, 156, 160, 640, ‘650 Miiller, 150, 213, 582, 755 Murchison, 540 Murphy, 740 Murray, 499, 502 Musgrave and Clegg, 636, 637, 642, 644 Musgrave and Strong, 647, 648, 654 Myers, 99, 101, 102, III, 120 103, Naparro and Bruce, 509, 513 Nabarro, Bruce, and Greig, 513 Nattan-Larrier and Levaditi, 731 Neélow, 74 Negri, 363, 364, 365, 366, 367, 368, 360, _ 372 371, 372 Neisser, 24, 394, 401, 413, 588, 727 Neisser and Bruck, 727 Neisser and Kutschbert, 431 Neisser and Sachs, 139 Neisser and Wechsberg, 136, 137, 138, _ 395, 307 Neisser, Wassermann, and Bruck, 270, 281, 283 Neiva, 524 Nelis and Van Gehuchten, 372 Nepveu, 507 Nessler, 64 Netter, 452 Neufeld, 454 Neuman and Swithinbank, 246 Neumann, 324, 424, 441 Neumann and Lehman, 230, 232 Newman, 161 Newman and Swithinbank, 669 Newmark, 294 Newsholme, 595 Nicati and Rietsch, 575, 576 Nicholas, 726 Nicholas and Descos, 73 Bibliographic Index Nicholls, 73 Nichols and Schmitter, 217, 218 Nicolaier, 24, 340 Nicolaysen, 397 Nicolle, 154, 403, 433, 527, 530, 531, 534, 541, 701 Nicolle and Comte, 494, 531 Nicolle and Conseil, 542 Nicolle and Manceaux, 533 Nicolle, Blaizot, and Conseil, 498 Nicolle, Couer, and Conseil, 541, 542 Niemann and Itzerott, 321, 581, 583, 585, 604 Niles, Dorset, and McBryde, 626 Nisot and Bumm, 419 Nissen, 109, 178 Nissen and Behring, 109 Nitzsch, 505 Noble, 726 Nocard, 37, 348, 350, 614, 625, 665 - Nocard and Leclainche, 482 Nocard and Railliet, 512 Nocard and Roux, 195, 665 Nocht and Behring, 177 Noguchi, 25, 132, 133, 280, 282, 283, 287, 204, 295, 296, 297, 365, 366, 498, 719, 723, 724, 727, 728 Noguchi and Flexner, 25, 132, 133, 344, 383, 384 Noguchi and Madsen, 132 Noissette, 440 Nolen and Hewlett, 424 Nolf, 120 Norris, 38 Norris and Oliver, 61 Norris, Pappenheimer, and Flournoy, 495, 497 Novy, 148, 215, 216, 217, 229, 495, 496, 497, 527, $31. 627, 692 Novy and Knapp, 497, 500, 5or Novy and McNeal, 510, 521, 700 Novy and Vaughan, 58, 247 Nuttall, 107, 108, 121, 122, 133, 146, 147, 359, 496, 501, 552, 553, 662 Nuttall and Inchley, 122 Nuttall and Welch, 332, 334, 337 OBERMEIER, 23, 24, 404 Oertel, 419 Oestertag and Lubarsch, 387 Oettinger, 324 Ogata, 545, 540, 553, 631 Ogata and Jasuhara, 99, 361 Ogston, 302, 308. Ohlmacher, 426, 429, 599, 622 Oliver and Norris, 61 Olsen, 438 Ophiils, 30, 748 Ophiils and Moffitt, 748 Oppenheim, 294 Oriste-Armanni, 566 Orlowski and Palmirski, 417 Orth, 154 Ortmann, 448 Ortmann and Melcher, 7or Bibliographic Index Oshida, 375, Osler, 631, 632, 633 Otero, 541 Otto, 103 Otto and Kolle, 307, 558 Overbeck and Kossee, 550 Ovid, 17 Oviedo, 729 Pace, Frothingham, and Paige, 762 Paige, Frothingham, and Page, 762 Palmirski and Orloswki, 417 Paltauf, 42 Paltauf and Kolisko, 419 _ Pane, 456 Panfili, 177 Pansini, 324 Pappenheim, 661 Pappenheimer, Norris, and Flournoy, 495, 497 Paquin, 683 Pariette, 609 Park, 81, 220, 349, 388, 390, 413, 425, 428, 429 Park and Dunham, 648 Park and Krumwiede, 687 Park, Biggs, and Beebe, 424 Parke and Williams, 445 Parker, Rosenau, Francis, and Beyer, 539 Pasquale and Kruse, 632 Passet, 300, 308, 616 Passler, 456 Pasteur, 19, 20, 24, 85, 95, 96, 105, 113, 173, 215, 218, 263, 267, 329, 358, 360, 361, 363, 373, 374, 377, 378, 444, 504, 565 Pasteur and Chevreul, 20 Pasteur and Doleris, 308 Pasteur and Toussaint, 564 ; Pasteur, Chamberland, and Roux, 363 Paterson, 684 Patton, 529, 530 Patton and Cragg, 489, 501, 502, 517, 519, 523, 562 Patton and Donovan, 530 Paul and Krénig, 177 Paulicki, 690 Pawlowski, 54, 666 Pawlowsky, 578, 579 Peabody and Pratt, 596, 604, 611 Pearce, 313, 420, 421 Pearce, Councilman, and Mallory, 423 Pearson, 710 Pearson and Gilliland, 689 Pease and Bolton, 53 Peckham, 620 Pelletier and Coventou, 472 Perkins, 324, 459, 742, 763 Perkins and Hektoen, 759, 760, 761, 762, 763 Perkins and Howard, 317 Pernoss and Fermi, 345 Perroncita, 615 Perroncito, 564 777 Peterson, 403 Petkowitsch, 608 Petri, 204, 206, 207, 217, 218, 235, 236, 430, 693 Petruschky, 36, 38, 199, 314, 598, 599, 615, 624, 678 Petruschky and Freejmuth, 437 Pfeiffer, tor, 116, 135, 151, 195, 462, 463, 464, 465, 466, 578, 584, 585, , 586, 587, 694 Pfeiffer and Beck, 465 _ Pfeiffer and Canon, 24 Pfeiffer and Frankel, 304, 309, 330, 341, 342, 352, 354, 355, 415, 4535 , 595, 570, 581, 586, 657, 668, 707 Pfeiffer and Kolle, 594, 600, 602 Pfeiffer and Vogedes, 578 Pfuhl, 327, 676° Phisalix and Bertrand, 99, 100, 132 Piaget, 505 Pianese, 530 Piatkowski, 663 Pick and Jacobsohn, 388 Picq and Chenot, 714 Pictet and Yung, 55 Pierce, 452 Piorkowski, 608, 622 Pirquet, 427, 670, 726 Pirquet and Schick, 103 Pitfield, 159, 345, 627 Platania, 85 Plaut, 42, 433, 438, 439, 440, 757 Plencig, 21 : Plett, 93 Pohl, 241 Pollender, 22, 353 Pollender and Davaine, 24 Poor and Steinhardt, 367 Poor, Steinhardt, and Lambert, 365 Pope, 602 Popischell and Bernheim, 437 Popper and Landsteiner, 381 Porges and Meier, 280 Portier and Richet, 103 Posadas and Wernicke, 748 Pott, 54 Poupé, Kimla, and Vesley, 666 Pratt and Krumweide, 434 Pratt and Peabody, 596, 604, 611 Preindelsberger, 69 Prescott, 58, 616 Prescott and Winslow, 199 Prior and Finkler, 580, 581, 588 Proca and Babes, 684 Proskauer and Beck, 51, 667 Proskauer and Voges, 650 Prowazek, 328, 511 Prowazek and Hoffmann, 728 Prudden, 239, 312, 671 Prudden and Hodenpyl, 686 Quénv and Chauffard, 350 Quincke, 755 Quincke and Roos, 632 Quinquaud, 438 778 RaBINOWITSCH, 246, 693, 747 Railliet and Nocard, 512 Ramon, 345 Ranken, 511 Ransom and Meyer, 346, 347 Rappaport, 549 _ Raskin, 313 Ravenel, 55, 73, 194, 197, 198, 201, 202, 215, 240, 241, 244, 686 Ravenel and McCarthy, 372 Raymond and de Beurmann, 763 Redi, 17, 18 Reed and Carroll, 539 Reed, Carroll, and Agramonte, 538 Reed, Carroll, Lazear, and Agramonte, 536 Reed, Vaughan, and Shakespeare, 595 Reichel, 174, 666 Reichel and Engle, 369 Remak, 755 Rémy, 606 Ress, 438 Rettger, 71, 361 Reyes, 416 Ribbert, 305, 307 Richards, 715, 716 Richardson, 598, 605 Richet and Portier, 103 Ricketts, 748 Ricketts and Wilder, 542 Rideal, 178 Rideal and Walker, 253 Ridi, 505 Riedel and Wolffhiigel, 570 Rieder, 54 Rieger, 386 Rietsch, 575 Rietsch and Nicati, 575, 576 Riley and Johannsen, 489 Rindfleisch, 585 Rist, 418 Ritchie, 350 Ritchieand Muir, 153,156, 160,649,650 Ritter, 441 Rivolta, 25, 690 Robb and Ghriskey, 69, 300 Robb and Welch, 174 Robertson, 593 Robey and Ernst, 123 Robin, 438 Robinson, 182 Rodet, 307 Roger, 82, 84, 361, 440, 604 Roger and Charrin, 85, 122 Roger and Gilbert, 690 Rogers, 399, 525, 527, 529, 642 Rogone, 175 Rolleston, 619 Roloff, 690 Romanowsky, 163, 165, 367 Roos and Quincke, 632 Rosenau, 104, 130, 182, 428, 550, 630, 667, 669 Rosenau and Anderson, 103, 104, 132 Rosenau and Brues, 384 Bibliographic Index Rosenau, Lumsden, and Kastle, 594 Rosenau, Parker, Francis, and Beyer, 539 Rosenbach, 300, 302, 307, 308, 318 Rosenberger, 207 Rosenow, 449, 453, 456 Roser, 10 Ross, 165, 472, 473, 474, 478, 482, 499, 525, 536 Ross and Milne, 494, 495, 499 Rossi, 160 Rost, 699, 704 Rothberger, 607 Roudoni and Sachs, 296 Rouget and Vaillard, 348 Roux, 24, 98, 128, 170, 215, 218, 222, 223, 300, 413, 438 Roux and Borrel, 345, 350 Roux and Chamberland, 98, 332 Roux and Martin, 110 Roux and Metschnikoff, 718 Roux and Nocard, 195, 665 Roux and Yersin, 76, 98, 416, 417 419 Roux, Pasteur, and Chamberland, 363 Row, 529, 533, 534 Rowland, 558 Rowland and Macfadyen, 76, 594 Rudolph, 699 Ruediger, 311, 312, 455, 759 Ruediger and Slyfield, 242 Ruffer, 578 Rumpf, 602 Ruppel, 675 Russel, Jordan, and Zeit, 593 Russell and Evans, 182 Russell and Hiss, 648 Russo-Travali and Blasi, 420 Ruzicka, 322 Rymowitsch and Matschinsky, 407, 409 SABOURAUD, 752, 753, 754, 756, 757 Sabrazes, 433 Saccardo, 759 Sacharoff, 494 Sachs and Neisser, 139 Sachs and Roudoni, 296 Saint-Girons, 763 Salamonsen, 220 Salant, 86 Salimbeni and Marchoux, 494 Salkowski, 62, 618 Salmon, 566, 567, 615, 625, 686 Salmon and Smith, 98, 566, 615, 625, 626 : Salmonson and Madsen, 115 Sambon, 478, 513 Sambon and Low, 473 Sanarelli, 536, 615, 627, 628 Sander, 666 Sanfelice, 351, 747 Sattler, 432 Savage and Irons, 607 Scala, 647 Schaudinn, 482, 495, 633, 634, 636, 643, 644 Bibliographic Index Schaudinn and Hoffmann, 24, 69, 718, 728, 730 Schenck, 759 Scherer, 386, 387, 389 Schereschewsky, 722 Schering, 150, 179 Schick, 428, 429 Schick and von Pirquet, 103 Schleich, 432 Schmidt, 386 Schmitter and Nichols, 217, 218 Schneider, 177, 387 Schonlein, 755 Schottelius, 572 Schottmiiller, 311, 312, 317 Schréder, 452 Schréder and Van Dusch, 24, 170 Schréter, 241 ; Schubler, 379 Schulze, 18, 19 Schumburg and Gauss, 31 Schiitz and Léffler, 24, 566, 706, 711 Schiitze and Wassermann, Io1I, 121 Schwalve, 353 Schwann and Latour, 19 Sedgwick, 235, 612 Sedgwick and Tucker, 235, 236 Sedgwick and Winslow, 55, 593 Seifert, 400 Seiner, 437 Selter, 200, 714 Semmelweiss, 22 Semple and Wright, 600 Sergent and Foley, 498 Shackell, 378 Shackell and Harris, 378 Shakespeare, 573, 582, 583 Shakespeare, Reed, and Vaughan, 595 Shaw, 81 Shiga, 24, 632, 647, 648, 650, 652 Shiga and Celli, 615 Shiga and Flexner, 651 Sholly and Goodwin, 392 _ Shiitz and Léffler, 24 Sicard and Widal, 123 Sievenmann, 44 Siffer, McClintock, and Boxmeyer, 627 Silber, 248 Silverschmidt, 327, 437 Simon, 315 Simond, 551 Simonds, 336 Simpson, 544, 548 Sjéo and Tornell, 663 Slyfield and Ruediger, 242 Small, 268 Small and McFarland, 62 Smirnow, 53 Smith, 159, 190, 192, 239, 417, 420, 460, 598, 622, 626, 627, 665, 666 Smith and McCoy, 551 Smith and Salmon, 98, 566, 615, 625, 626 Smith and Weidman, 328 Smith (L.), 161, 197 779 Smith (T.), 59, 60, 103, 124, 127, 200, 220, 344, 612, 666, 685, 686, 689 Sobernheim, 575, 578 Solowiew, 654 Somers, 609 Southard and Gay, 104 Sowade, 723 Soyka, 50 Spallanzani, 18 Spengler, 441 Spiller, 372 Splendore, 759 Splendore and Lutz, 759 Spronck, 415, 648, 699 Starkey, 609 Steel, 392 Steele, 71, 602 Steinhardt and Bauzhof, 130 Steinhardt and Besredka, 104 Steinhardt and Poor, 367 Steinhardt, Poor, and Lambert, 365 Steinmetz and Levy, 709 Stephens, 509 Stephens and Fantham, 506, 509 Stern, 110, 601, 720, 726 Sternberg, 24, 60, 106, 235, 250, 252, 253, 304, 325, 343, 444, 459, 536, 574, 590, 592 Stewart, 149 Stewart and Mitchell, 133 Stewart, Graham, and Baldwin, 337, , 339 Sticker, 43, 702 Stiles, 633 Stimson, 375, 376 Stitt, 489, 531 Stokes, 245 Stokes and Gilchrist, 747, 749 Stokvis and Winogradow, 655 Stooss, 439 Strasburger, 71 Straus, 708, 709 Strauss and Huntoon, 381 Strehl, 185 Strickland, 560 Strong, 558 Strong and Kolle, 558 Strong and Musgrave, 647, 648, 654 Stuhlern, 457 Sugai, 701 Surveyor and Boyce, 742, 744 Swithinbank and Neuman, 246 Swithinbank and Newman, 669 Szekely, 33 Szemetzchenko, 441 Taxaxki and Wassermann, 99, 345 Tangl, 417 Tashiro, 701 Taube and Weber, 691 Tavel, 41, 316, 351, 592 Tavel and Alvarez, 692 Taylor and Moore, 709 Tchistowitch, 101, 120, 450 Tedeschi, 713, 726 780 Bibliographic Index Telamon, 444 Terre and Dubarre, 691 Theiler, 494 Thelling, 682, 683 Theodoric, 21 Thiercelin and Lesage, 324 Thoinot and Masselin, 564 Thomas and Cornevin, 96 | Thomas and Linton, 509 Thompson, 644 Thompson and Yates, 507, 509, 612 Tictin, 498 Tidswell, 553 Tiemann and Kubel, 608, 609 Timpé, 190 Tizzoni and Centanni, 683 Todd, 507 Todd and Dutton, 494, 495» 499, 507 Todd and Kinghorn, 498 Todd, Dutton, and Christy, 509 Tornell and Sjio, 663 Torrey, 399 Torry and Buxton, 106 Toussaint, 360 Toussaint and Pasteur, 564 Trambusti, 56 Traube and Gscheidel, 107, 135 Trendenburg and Frankel, 313 Treskinskaja, 52 Triboulet, 324 Trillat, 180 Trudeau, 682 Trudeau and Baldwin, 680, 681 Tsiklinsky, 55 Tsugitani, 637 Tucker and Sedgwick, 235, 236 Tunnicliff, 434, 435, 436, 437 Tyndall, 17, 19, 50 UCKE, 420 Uhlenhuth, rar Uhlenhuth and Xylander, 664 Ukke and Grigorjeff, 332 Unna, 68, 155, 368, 403, 663, 696 Uschinsky, 418, 618 VAILLARD and Dopter, 651 Vaillard and Rouget, 348 Valagussa, 631 ~ Vallery-Radot, 565 Van der Pluyn and Loag, 394 Van de Velde, 305, 316 Van de Velde and Denys, 307 Van Dusch and Schréder, 24, 170 Van Ermengem, 159, 247, 575, 576, 721 Van Gehuchten and Nelis, 372 Van Gieson, 365 Van Helmont, 17 Van Steenberghe and Grysez, 73 Varro, 20 Vaughan, 75, 105, 247, 306, 510, 594 Vaughan and Buxton, 124 Vaughan and Cooley,” 619 Vaughan and Novy, 58, 247 Vaughan, Cooley, and Gelston, 75 Vaughan (J. V.), 75 Vaughan, Reed, and Shakespeare, 595 Veasy and De Schweinitz, 408 Vedder, 642 Vedder and Duval, 648 Veillon and Zuber, 333, 434, 437 Vergbitski, 553 Verneuil, 340 Vesley, Kimla, and Poupé, 666 Viereck, 633, 635, 643 Vierordt, 571 Vignal, 37, 694 Villemin, 656 Villiers, 575 Vincent, 433, 434, 437, 741, 742, 743 Vincentini, 70 Vincenzi, 441 Viola and Bonome, 53 Viquerat, 307, 683 © Virchow, 677, 702 Virgil, 17 Vogedes and Pfeiffer, 578 Voges and Proskauer, 650 Voll, 123 Volpino and Bertarelli, 721 von Diingern, 100, 102, 116, 134 von Fodor, 107 von Frisch, 715, 716 von Leyden, 603 von Lindt, 43 von Lingelsheim, 304, 310, 386 von Lingelsheim and Leuchs, 392 von Mayer, 351 von Pirquet, 427, 679, 726 von Pirquet and Schick, 103 von Szekely, 33 : Vuillemin, 438 WADSWORTH, 451, 454. Wagner, 85 Wagner and Giinther, 721 Walger, 602 Walker, 119, 253, 636 Walker and Montgomery, 748 . Walker and Rideal, 253 Walz and Baumgarten, 682 Warren, 191, 427, 473 Wasdin and Geddings, 536 Washbourn, 453, 456 Wassermann, 24, 99, 121, 279, 280, 283, 284, 286, 288, 290, 291, 293, 204, 207; 323, 396, 397, 398, 726, 728, I Wassermann and Bruck, 726 Wassermann and Citron, 288 Wassermann and Kolle, 37, 40, 42, 110, 392, 393, 439, 480, 482, 483, 405, 496, 547, 696, 607, 757 Wassermann and ‘Schiitze, IOI, 121 Wassermann and Takaki, go, 345 Wassermann, Neisser, and Bruck, 279, 281, 283 Weaver, 434 Weber and Taube, 691 Wechsberg and Neisser, 136, 137, 138, 305, 307 Bibliographic Index Weeks, 406, 407, 408, 432 Weibel, 588 Weichselbaum, 241, 386, 387, 389, 301 392, 444, 452, 552, 509 Weichselbaum and Frankel, 328, 458 Weidman and Smith, 328 Weigert, 24, 114, 144, 146, 354, 413, 663, 696, 743, 745 Weigert and Gram, 154 Weil and Kitasato, 219 Weinzirl, 52 _ 69, ITO, T19, 300, 332, 333) 339, 9, 396, 428, 445, 471, 482 Welch, and Abbott, 413 Welch and Flexner, 332, 337, 419 Welch and Nuttall, 332, 334, 337 Welch and Robb, 174 Wellenhof, 429 Wenyon, 635 Wernich, 105 Wernicke, 24, 550, 588 Wernicke and Kraus, 383 Wernicke and Posadas, 748 Wertheim, 394, 395, 396 Wesbrook, 424, 425, 608 Wesbrook and Hankin, 357 Wesenberg, 327 Westbrook, 416 Wheeler, 75 Whitman, 636 Wickman, 381 Widal, 122, 590, 603 Widal and Chantemesse, 599, 601, 602, 647 Widal and Griinbaum, 603 Widal and Sicard, 123 Wiener and Gruber, 578 Wiens, 619 - Wigura, 69 Wilder, 542 Wilder and Ricketts, 542 Willcomb and Winslow, 238 Williams, 324, 337, 366, 367, 419, 537, 721 Williams and Calkins, 636 Williams and Lowden, 364, 368, 370, 371 Williams and Parke, 445 Wilson, 550 Wilson and McDaniel, 424 Wilson and Yersin, 549 Winckel, 619 Windsor and Wright, 469 Winkler, 214 Winogradow and Stokvis, 655 Winogradsky, 63 Winslow, 69, 618 Winslow and Prescott, 199 Winslow and Sedgwick, 55, 593 Winslow and Willcomb, 238 Winterbottom, 506, 515 Winterintz and Déderlein, 71 Witte, 190, 191, 200, 610, 612 Wladimiroff, 496 Wolbach, 437 481 Wolbach and Binger, 515, 516 Wolf, 452 Wolff, 604, 734 Wolff and Eisner, 680, 726 Wolffhiigel and Riedel, 570 Wolfhiigel, 237, 238 Wollstein, 443, 466, 648 Wollstein and Frankel, 443 Wood, 148, 457, 729 Wood and Hiippe, 362 Woodhead, 32, 739 Woodward, 631 Wright, 163, 165, 218, 220, 221, 237, 238, 240, 241, 263, 264, 265, 267, 268, 271, 273, 2745-275, 277, 307; 396, 468, 532, 594, 600, 6or, 643, _ 733, 736, 738; 744, 746 Wright (A. E.), 97; 307, 682 Wright and Brown, 733, 734 Wright and Douglas, 107, 270, 277 Wright and Mallory, 163, 165, 220, 386 Wright and Semple, 600 Wright and Windsor, 469 | Wright (J. H.), 276, 533, 744, 745 Wunschheim and Fischel, 110 Wiirtz, 606, 618, 623 Wyman, 544, 549 Wynekoop, 466° Wyse-Lauzun, 763 Wyssokowitsch and Zabolotny, 551, 559 XYLANDER and Uhlenhuth, 664 Yamanoucui and Levaditi, 280 Yates and Thompson, 507, 509, 612 Yersin, 543, 544, 545, 546, 547, 549, 552, 556) 559 Yersin and Kitasato, 24 Yersin and Roux, 76, 98, 416, 417, 419 Yersin and Wilson, 549 Yorke and Kinghorn, 513 Young, 396, 397, 398 Yung and Pictet, 55 ZABOLOTNY and Wyssokowitsch, 551, / 559 Zaufal, 452 Zeit, 53, 712 Zeit, Jordan, and Russel, 593 Zenker, 149, 155, 165, 368, 369 Ziegler, 631 Ziehl, 151, 157, 590, 660, 661 Zieler, 155 Zimmermann, 240, 241 Zinno, 415 Zinsser, 218, 460 Zinsser and Hiss, 36, 188, 310, 319, 387, 396, 447, 448, 456, 589, 614, 708, 74 Vingsers Hopkins, and Gilbert, 724 Zopf, 33, 241, 457 Zuber and Veillon, 333, 434, 437 Zupinski, 215 Zupnik, 346, 347 Zur Nedden, 409 INDEX AspoTr’s method of staining spores, 156 Abderhalden reaction, 140 dialysis test, 140 optical test, 140 technic of, 142 Abscess of liver in amebic dysentery, 644 Acetic fermentation, 58 Achorion, 41 schinleinii, 41, 755 cultivation, 757 Kral’s method, 757 pathogenesis, 758 Acid, carbolic, as disinfectant, 178 tuberculinic, 676 Acids as disinfectants, 177 production of, by bacteria, 60 Acquired immunity, 91 passive, 98 Actinodiastase, 107 Actinomyces, 38 bovis, 732 cultivation, 734 distribution, 732 general characteristics, 732 lesions produced by, 740 metabolism, 738 morphology, 733 pathogenesis, 738 temperature, 738 virulence, 738 grain, 734 madure, 741 cultivation, 742 cultural characteristics, 746 general characteristics, 741 lesions produced by, 743 morphology, 742 pale variety, 742 mode of infection with, 739 Actinomycosis, 732 lesions, 740, 743 mode of infection, 739 Active immunity, 89 Acute anterior poliomyelitis, 381 avenues of infection, 385 cause, 381 characteristics, 382 histological changes, 382 immunization against, 385 possible infective agent, 384 transmission, 384, 385 virus, 382 contagious conjunctivitis, 406 Adami and Chapin’s method of isola- tion of Bacillus typhosus, 608 Addiment, tor, 118 Adhesion cultures, 212 Aérobes, 51 Aérobic bacteria, 51 Aérogens, 57 African lethargy, 506. 4 ing sickness gar-agar, 193 blood, 195 culture, 211 glycerin, 195 preparation of, 193 Agglutination, 122 test in diagnosis of sporotrichosis, 764 technic of, 124 Widal reaction of, 603 Agglutinins, 116, 122 Agglutometer, 603 Aggressins, 84, 119 Ague-cake, 486 Air, bacteria in, 50, 234 quantitative estimation by Hesse’s method, 234 by Petri’s method, 235 by Sedgwick’s method, 235 bacteriology of, 234 Air-examination, Petri’s sand filter for, 236 Sedgwick and Tucker’s expanded tube for, 236 : Alcoholic fermentation, 57 Aleppo boil, 531 Alexines, 108, 118, 135 : Alkali-albuminate, Deycke’s, 197 Alkalies as disinfectants, 177 production of, by bacteria, 60 Allergia, 103 Altmann’s syringe, 223 Amboceptor, dose, in Wassermann re- See also Sleep- action, 286 hemolytic, for Wassermann reac- tion, 284 unit, in Wassermann reaction, 286 Ameba, parasitic, reproduction cycle of, 635 Amebadiastase, 107 Amebic dysentery, 633 liver abscess in, 644 American sleeping sickness, 518 diagnosis, 522 prophylaxis, 523 transmission, 521 783 784 American trypanosomiasis, 518. See also American sleeping sickness Ameeba coli, 633 rhizopoda, 633 dysenteriz, 633 Anderobes, 51 optional, 51 : Anaérobic bacteria, cultivation of, 215 by absorption of atmospheric oxygen, 215, 217 by displaceme t of air by inert gases, 215 , by exclusion of atmospheric oxygen, 215, 219 by formation of vacuum, 215 by reduction of oxygen, 215 218 cultures, soins apparatus for making, ; Buchner’ s mettiod of making, 217, Frinkel’s method of making, 216 Hesse’s method of making, 219 Liborius’ tube for, 216 Nichols and Schmitter’s method of. making, 217 Novy’s jars for, 216 Salamonsen’s method of making, 220 use of hen’s eggs for, 220 Wright’s method of making, 218, 220 Zinsser’s method of making, 218 Anaphylactin, 104 Anaphylaxis, 103 passive, 105 Anesthetic leprosy, 703 Angina, Vincent’s, 433 Animal holder, guinea-pig, 225 Latapie’s, 225 mouse, 225 inoculation with malarial parasites, 486 Ainaleule 26 Animals, experimentation upon, 222 method of making injections into, 224 of securing blood from, 226 post-mortems on, 228 _ typhoid fever in, 599 Anjeszky’s method of staining spores, 157 ane nes maculipennis, 487, 488 larva of, 492 pupa of, 492 Anthracin, 357 Anthrax, 352 bacillus of, 352. anthracis bacteriologic diagnosis, 361 lesions, 359 malignant pustule of, 359 prodigiosus powder for, 361, 362 sanitation in, 362 serum treatment, 361 See also Bacillus Index Antianaphylactin, 105 : Fa Antibiosis, influences on growth of ~" bacteria, 54 Antibody, 97 Antiferments, 116 Antiformin as disinfectant, 176 ul for isolation of tubercle bacillus, 663 Antigen, 97 syphilitic, 279 titration of, in Wassermann reac- tion, 288 Anti-immune bodies, 138 Antikérper, 426 Antiphthisin, 680 ‘Antipneumococcus serum, 456 Antirabic serum, 380 Antisepsis, 23 Antiseptics, 167 action of, results, 251 determination of value, 251 inhibition strengths of, 180 _Antistreptococcus, serum, 316 Antistreptokolysin, 315 Antitoxin, diphtheria, 128, 426. also Diphtheria antitoxin hypersensitivity to, 127 tetanus, 131, 349 Antitoxins, 125 Antitubercle serums, 683 Antivenene, 100, 132 Anti-venomous serum, 132 Argas miniatus, 494 Army-fever, 540 Arnold’s steam sterilizer, 171 Aromatics, production of, by bacteria, 62 Arthrospores, 33 See _Ascococcus, 35 Ascomycetes, 40 Asiatic cholera, 568 discovery of specific Or paniam, 569 distribution, 568 history, 568 prophylaxis, 579 sanitation, 580 serum treatment, 579 Aspergillus, 42 flavus, 43 fumigatus, 43 malignum, 43 nidulans, 43 niger, 44 subfuscus, 44 Association, influences of, on growth _ of bacteria, 54 Atrophic spinal paralysis, 381 Auditory meatus, external bacteria in, 69 ; Autoclave, modern, 172 sterilization in, 171 Autogenous vaccines, 265 Bases and Cornil’s method of staining Spirillum cholere asiatice, 572 Babes-Ernst granules, 31 Index Babes, tubercles of, 372 Bacillary dysentery, 647 diagnosis, 651 lesions, 651 serum treatment, 652 emulsion, 682 Bacilli, coli-typhoid, gram-negative, table of, 650 in Ohio river water, classification of, 240, 241 paratypnoid, 674 resembling tubercle bacillus, 692 typhoid bacillus, 613 meat-poisoning group, 614 pheumonic or psittacosis group, 614 table for differentiation, 615 typhoidal group, 614 Bacillus, 35 aérogenes capsulatus, 332 cultivation, 334 distribution, 333 general characteristics, 332 groups of, 336 metabolic products, 336 morphology, 333 pathogenesis, 336 sources of infection, 337 staining, 334 vital resistance, 336 anthracis, 352 avenues of infection, 357 bacilli resembling, 362 cultivation, 355 general characteristics, 352 isolation, 354 metabolic products, 356 morphology, 353 motility, 354 pathogenesis, 357 sporulation, 353 staining, 354 vaccination, 360 virulence, 360 vital resistance, 356 avicidum, 564 avisepticus, 564 Bordet-Gengou and bacillus in- fluenze, differences between, 443, cultivation, 442 isolation, 442 metabolic products, 443 morphology, 441 pathogenesis, 443 staining, 442 botulinus, 59, 247 butter, 693 butyricus, 693 capsulated canal-water, 457 capsulatus mucosus, 457, 458. See also Pneumococcus - capsule, 458 cholere, 564 gallinarum, 564 5° 785 Bacillus cholere gallinarum, cultiva- tion, 564 general characteristics, 564 immunity, against, 565 lesions, 565 metabolic products, 564 morphology, 564 pathogenesis, 564 staining, 564 vital resistance, 564 coli communior, 618 communis, 616 amount in sewage, 623 cultivation, 617 distribution, 616 general characteristics, 616 immunization against, 621 in drinking water, 239, 622 Wiirtz’s method of detect- ing, 623 in water, MacConkey’s medium for detecting, 612 Smith’s method of detecting, 239. metabolic products, 618 morphology, 616 pathogenesis, 619 presumptive test for, 242 staining, 617 toxic products, 619 typhoid bacillus and, differential diagnosis, 604, 621, 622 cultural, 605 serum, 605 virulence, 620 vital resistance, 618 comma, 570 cuniculicida, 564 diphtheriz, 411 bacilli resembling, 429 bacteria associated with, 420 bacteriologic diagnosis, 425 chief types, 424 contagion from, 424 cultivation, 413 Loffler’s method, 415 general characteristics, 411 habitat, 419, 421 infection, intraperitoneal, 418 intrapleural, 418 metabolic products, 417 morphology, 411 mucous membrane inoculations, 418 occurrence in healthy throats, 425 pathogenesis, 418 seats of infection by, 421 specificity, 423 staining, 413 Neisser’s method, 413 with Loffler’s alkaline methyl- ene blue, 413 subcutaneous inoculation, 418 toxin, 417 vital resistance, 416 786 Bacillus Ducreyi, 403 cultivation, 404 general characteristics, 403 morphology, 403 pathogenesis, 405 staining, 404 vital resistance, 405 dysenteriz, 632, 647 cultivation, 649 general characteristics, 649 Hiss-Russell variety, 648 lesions caused by, 651 metabolic products, 649 morphology, 649 pathogenesis, 651 Shiga-Kruse variety, 648 staining, 649 varieties, 648 vital resistance, 651 enteritidis, 624 cultivation, 624 general characteristics, 624 lesions, 624 morphology, 624 pathogenesis, 624 sporogenes, 332 staining, 624 fecalis alkaligenes, 624 fusiformis, 433 cultivation, 434 morphology, 436 pathogenesis, 437 spirocheta vincenti and, relation, 434 geniculatus, 70 Hofmanii, 429. See also Bacillus pseudodiphtheria icteroides, cultivation, 628, 629 distribution, 627 general characteristics, 627 metabolism, 628 morphology, 627 pathogenesis, 628 staining, 627 vital resistance, 628 influenze, 462 Bordet-Gengou bacillus and, dif- ferences between, 442 cultivation, 463 general characteristics, 462 immunity against, 465 isolation, 463 morphology, 462 pathogenesis, 465 pseudo-, 466 specificity, 464 staining, 462 vital resistance, 464 leprae, 605 cultivation, 696 Clegg’s method, 699 Duval’s method, 700 Rost’s method, 699 etiology, 695 general characteristics, 695 Index Bacillus leprz, lesions produced by, 702 morphology, 695 pathogenesis, 701 staining, 696 mallei, 706 cultivation, 709 distribution, 706 general characteristics, 706 isolation, 708 lesions produced by, 711, 712 metabolic products, 710 mallein, 711 morphology, 706 pathogenesis, 711, 717 staining, 707 Kiihne’s method, 707 Loéffler’s method, 707 virulence, 714 vital resistance, 708 melitensis, 467. See also Micro- coccus melitensis Moeller’s grass, 693 neapolitanus, 616. coli communis cedematis maligni, 329 cultivation, 329 distribution, 329 general characteristics, 329 immunity, 332 lesions, 331 metabolic products, 331 morphology, 329 pathogenesis, 331 staining, 329 vital resistance, 330 of Asiatic cholera, 568. See also Spirillum cholere Asiatice of Bordet-Gengou, 441 of Biiffelseuche, 566 of diphtheria, 411. lus diphtherie of Ducrey, 403. ducreyi of Klebs-Loffler, 411. Bacillus diphtheriae of Koch-Weeks, 406 association, 408 cultivation, 407 general characteristics, 406 morphology, 407 pathogenesis, 408 staining, 407 of Morax-Axenfeld, 408 cultivation, 408 morphology, 408 pathogenesis, 409 staining, 408 of rabbit septicemia, 564 of swine-plague, 566. See Bacillus suisepticus of syphilis, 718. See also Trepon- ema pallidum of typhoid fever, 589. Bacillus typhosus See also Bacillus See also Bacil- See also Bacillus See also also See also Index 987 Bacillus of Weeks, 406. See also Bacillus of Koch-Weeks of Wildseuche, 566 of zur Nedden, 409 Oppler-Boas, 70 paracolon, 614 pestis, 543 cultivation, 546 experimental infection with, 550 general characteristics, 543 mode of infection with, 551 by cutaneous inoculation, 551 by inhalation, 551 by intraperitoneal inocula- tion, 554 by intravenous inoculation, 554 by subcutaneous inocula- tion, 551 metabolism, 550 morphology, 546 staining, 546 thermal death-point, 550 virulence, 556 vital resistance, 549 phlegmone emphysematose, 332 piscicidus, 248 proteus vulgaris, 325 cultivation, 325 distribution, 325. general characteristics, 325 metabolic products, 327 morphology, 325 pathogenesis, 327 staining, 325 pseudodiphtheria, chemistry, 431 cultivation, 430 differentiation from Bacillus diph- theriz, 423, 429 morphology, 430 pathogenesis, 431 staining, 430 pseudodysentery, 648 pseudoglanders, 714 pseudo-influenza, 466 pseudotetanus, 351 pseudotuberculosis, 694 cultivation, 6904 morphology, 694 pathogenesis, 694 psittacosis, 625 cultivation, 625 differen tiation, 625 general characteristics, 625 isolation, 625 metabolic products, 625 morphology, 625 pathogenesis, 625 pyocyaneus, 321 distribution, 321 general characteristics, 321 isolation, 322 metabolic products, 323 morphology, 321 staining, 322 Bacillus rhinoscleromatis, 715 septicus sputigenus, 445 smegmatis, 692 ‘cultivation, 692 morphology, 692 pathogenesis, 692 staining, 692 suipestifer, 625 agglutination, 627 cultivation, 626 general characteristics, 625 metabolic products, 626 morphology, 626 pathogenesis, 627 vital resistance, 626 suisepticus, 566 cultivation, 566 general characteristics, 566 lesions from, 566 morphology, 566 staining, 566 vital resistance, 566 tetani, 340 bacilli resembling, 351 cultivation, 342 distribution, 340 general characteristics, 340 immunity against, 349 isolation, 340 metabolic products, 344. staining, 340 vital resistance, 343 tuberculosis, 656 agglutination, 683 | appearance of cultures, 668 avium, 690 cultivation, 690 morphology, 690 pathogenesis, 691 staining, 690 thermic sensitivity, 691 bacilli resembling, 61 bovis, 685 , lesions produced by, 686 metabolic products, 685 morphology, 685 pathogenesis, 685 staining, 685 vegetation, 685 channels of infection for, 669 gastro-intestinal tract, 670 placenta, 669 respiratory tract, 669 sexual apparatus, 670 wounds, 671 - chemistry, 675 cultivation, 665 : Koch’s method, 665° Nocard and Roux’s method, 66 Prosaiien and Beck’s method, 667 , distribution, 657 effect of tuberculin on, 677 general characteristics, 656 788 tuberculosis in sections of tissue, Ehrlich’s method of staining, 663 Gram’s method of staining, 663 Unna’s method of staining, 663 isolation, antiformin for, 663 culture tube for, 666 Dorset’s method, 666 Frugoni’s method, 667 Pawlowski’s method, 666 Smith’s (T.) method, 666 lesions caused by, 671 morphology, 657 pathogenesis, 669 reaction, 668 relation to oxygen, 669 staining, 658 Ehrlich’s method, 661 for sections, 663 Gabbett’s method, 661 Gram’s method for sections, 663 in feces, 663 in sputum, 659, 660 in urine,662 Koch-Ehrlich method, 661 Unna’s method for sections, 663 Ziehl’s method, 661 temperature sensitivity, 669 toxic products, 676 virulence, 674 typhi murium, 628 destruction of mice by, 630 general characteristics, 628 isolation, 629 morphology, 629 pathogenesis, 629 staining, 629 typhosus, 589 bacilli resembling, 613 meat-poisoning group, 614 pneumonic or _ psittacosis group, 614 table for differentiation, 615 typhoidal group, 614 colon bacillus and differential diagnosis, 604, 621, 622 cultural, 605 serum, 605 cultivation, 591 Elsner’s method, 605 Piorkowski’s method, 608 Rémy’s method, 606 Rothberger’s method, 607 Wiirtz and Kashida’s method, 606 distribution, 589 effect of chemic agents on, 503 of cold on, 593 general characteristics, 589 Hiss’ method of cultivation, 607 in blood, 598 in feces, 604 in milk, 594 Bacillus Index Bacillus typhosus in oysters, 595 in sputum, 598 in urine, 598 in vegetables, 595 invisible growth, 592 isolation, 591 Adami and Chapin’s method, 608 Beckman’s method, 608 Buxton and Coleman’s method, 611 Drigalski-Conradi’s method, 608 Endo’s method, 610 Jackson’s method, 612 Loffler’s method, 611 MacConkey’s method, 612 Peabody and Pratt’s method, 611 Petkowitsch’s method, 608 Starkey’s method, 609 metabolic products, 593 mode of infection with, 594 morphology, 590 . pathogenesis, 595 plating, Capaldi’s medium for, 610 Hesse’s medium, 610 staining, 590 Ziehl’s method, 590 toxic products, 593 vital resistance, 592 welchii, 332 ; xerosis, 431 chemistry, 432 cultivation, 432 morphology, 432 pathogenesis, 432 Y, 648 Bacteremia, 79 Bacteria, 26 aérobic, 51 anaérobic, 51 cultivation of, 215. See also Anaérobic bacteria, cultivation of associated with diphtheria bacillus, 420 with suppuration, 299 Brownian movement, 32 capsule of, 31 Chester’s synopsis of groups of, 231- 233 chromogenic, 61 colonies of, 204, 208 combination of nitrogen by, 64 counting of, by Willcomb’s method, 238 by Winslow’s method, 238 by Wright’s method, 238 Frost’s plate counter for, 239 Wolfhiigel’s apparatus for, 237 cultivation of, 187 determination of thermal death- point of, 249 discovery of, 18 distribution ‘of, 50 effect on foods of, 57 Index Bacteria, fission of, 32 flagella of, 31 higher, 36 identification of species of, 230 in air, 50, 234 quantitative estimation by Hesse’s method, 234 by Petri’s method, 235 in bladder, 71 in butter, 246 in conjunctiva, 69 in dental caries, 70 in external auditory meatus, 69 in foods, 245 in intestine, 70 in larynx, 72 in lungs, 72 in meat, 246 in milk, 245 in mouth, 69 in nose, 71 in oysters, 246 in sections of tissue, observation of, 149 in skin and adjacent mucous mem- branes, 68 in soil, 243 Frinkel’s method of estimation, 243 in stomach, 70 in trachea, 72 in urethra, 71 in uterus, 71 in vagina, 71 in vegetables, 243 in water, 50, 237 number of, 238 method of determining, 237 influences of antibiosis on growth of, 54 . of association on growth of, 54 of chemic agents on growth of, 56 of electricity on growth of, 53 of food on growth of, 51 of light on growth of, 52 of metabolism on growth of, 57 of moisture on growth of, 52 of movement on growth of, 54 of oxygen on growth of, 50 of reaction on growth of, 52 of symbiosis on growth of, 54 of temperature on growth of, 55 of x-ray on growth of, 53 invasion of body by, 78 invasive power of, 75 isolation of, 204 liquefaction of gelatin by, 60 measurement of, 166 morphology of, 34 motility of, 32 non-chromogenic, 61 non-pathogenic, 64 nucleus of, 31 number causing infection, 81 pathogenic, 64 789 Bacteria, peptonization of milk by, 64 photographing, 166 polar granules of, 31 preparations for general examina- tion of, 146 production of acids by, 60 of alkalies by, 60 of aromatics by, 62 of disease by, 64 of enzymes by, 65 of nitrates by, 63 of odors by, 62 quantitative estimation of, by Sedg- wick’s method, 235 reduction of nitrates by, 63 reproduction of, 32 saprophytic, 66 size of, 27 sporulation of, 32 staining of, 146. structure of, 30 study of living, 144 thermophilic, 55 transplantation of, from culture- tubeto culture-tube, technic of, 203 units of measurement, 27 Bacterial suspension, 270 standardization of, 271 Bacterination, 95 Bacteriology, evolution of, 17] of air, 234 of foods, 245 of soil, 243 of water, 237 Bacteriolysis, 135 technic of, 136 Bacteriolytic serums, therapeutic uses of, 138 Bacterio-vaccination, conditions neces- sary to success in, 264 Bacterio-vaccines, 263 Bacterium, 35 coli dysenteriz, 647 pneumonie, 445, 457. Pneumococcus termo, 325 Bagdad boil, 531 Bain fixateur, 159 . reducteur et reinforgateur, 160 sensibilisateur, 160 Balantidium coli, 652 . cultivation, 654 habitat, 654 inoculation of animals with, 654 lesions caused by, 654 morphology, 652 motility, 653 pathogenesis, 654 staining, 653 diarrhea, 652 lesions, 654 transmission, 655 Barber’s itch, 754 Bass and Johns’ method of cultivating malarial parasites, 484 . See also Staining See also 79° Bazillenemulsion, 682 Beck and Proskauer’s method of cul- tivation of tubercle bacillus, 667 Beckman’s method of isolation of Bacillus typhosus, 608 Behring’s method of determining po- tency of diphtheria serum, 128 Berkefeld filter, 174 Bichlorid of mercury as disinfectant, 176 Biologic contributions, 17 Biology of bacteria, 50 Biondi-Heidenhain stain for protozoa, 165 Biscra boil, 531 button, 531 Black death, 543. molds, 41 plague, 543- See also Plague sickness, 525. See also Kala-azar Block for subculture tubes, 257 Bladder, bacteria in, 71 Blastomyces dermatitidis, 747 cultivation, 749 lesions caused by, 751 pathogenesis, 751 staining, 749 Blastomycetes, 38 : Blastomycetic dermatitis, 747 Blastomycosis, 747 specific organism, 749 lesions, 751 transmission, 751 Blood agar-agar, 195 Keidel tube for collecting, 281 method of ‘obtaining for Wasser- . mann reaction, 282 from animals, 226 phagocytic power of, 270 pipet, special, 2 7 4, typhoid bacilli in, 598 Blood-corpuscles for Wassermann re- action, 283 Blood-culture in typhoid fever, 603 Blood-serum, alkaline, 197 as culture- -medium, 195, 211 Koch’s apparatus for coagulating and sterilizing .of, 196 mixture, Léffler’s, 197 therapy, 24, 222 Bodies of Negri, 363. rhyctes hydrophobie Body, invasion of, by bacteria, 78 Leishman-Donovan, 525. See also Leishmania donovani lice, 503 Boil, Aleppo, 531 Bagdad, 531 Biscra, 531 Delhi, 531 Jericho, 531, 532 Bordet-Gengou bacillus, 441 phenomenon, 139 Botkin’s apparatus for making an- aérobic cultures, 217 See also Plague See also Neuror- Index Botulism, 247 Botulismus, 59 Bouillon as culture-medium, 190 preparation from fresh meat, 190 from meat extract, 191 sugar, 192 Bovine tuberculosis, 685 tuberculin test for, 689 Broncho-pneumonia, 461 Broth nitrate, 63 Brownian movement of bacteria, 32 Buboes in plague, 544 Bubonic plagte, 543. See also Plague Buchner’s method of making anaérobic cultures, 217, 219 Buerger’s method of isolation of Dip- lococcus pneumonia, 447 Biiffelseuche, bacillus of, 566 Bulbs, Sternberg’s, 250 Buret for titrating media, 188 Burri’s India ink method of identi- fying Treponema pallidum, 721 ' Buton d’Orient, 531 Butter bacillus, 693 bacteria in, 246 Button, Biscra, 531 Butyric acid fermentation, 58 Buxton and Coleman’s method of iso- lation of Bacillus typhosus, 611 Catcium carbide as disinfectant, 182 Calmette’s ophthalmo- tuberculin reac- tion, 679 Canal-water bacillus, capsulated, 457 Canned goods, poisoning from, 248 Capaldi’s medium for plating bacillus typhosus, 610 Capillary glass tubes, 202 Capsulated canal-water bacillus, 457 Capsule bacillus, 458 of bacteria, 31 Capsules, collodion, 228 Carbolic acid as disinfectant, 178 Cardinal conditions of infection, 79 Caries, dental, bacteria in, 70 Carrasquilla’ s "leprosy serum, 704 Carriers, typhoid, 595 Catarrhal inflammation, 400 pneumonia, 461 Celloidin embedding, 150 Cells, lepra, 702 specific affinity of, for toxins, 78 Ceratophyllus fasciatus, 554, 560 Cercomonas intestinalis, 655 Cerebro- spinal fever, 386 meningitis, 386 bacteriological diagnosis, 393 lumbar puncture in, 388 Chamberland filter, 174 Chancre, 725 sporotrichotic, 764 Chancroid, .403 specific organism of, 403 Chantemesse’s conjunctival reaction in typhoid, 604 Index Chapin and Adami’s method of isola- tion of Bacillus typhosus, 608 Charbon, 352 Cheese-poisoning, 247 Chemic agents, effect on Bacillus typhosus, 593 influences on growth of bacteria, 56 contributions, 19 Chester’s synopsis of groups of bac- teria, 231-233 Chicken-cholera, 564° Chlamydophrys stercorea, 633 Chlorin as disinfectant, 178 Cholera, asiatic, 568: See also Asiatic cholera changes in intestines, 575 immunity against 578 tice-water discharges in, 576 chicken-, 564 de poule, 564 hog-, 625 Chromogenesis, 61 Chromogenic bacteria, 61 Chromogens, 57 Cimex boneti, 521 lectularius, 521 rotundatus, 529 Cladothrix, 37 Classification of protozoa, 44, 45 Clegg’s method of cultivation of Bacillus leprae, 699 Clostridium, 33 Clothing, disinfection of, 184 Coagulins, 116,120 Cobralysin, 102 Cocci, 34 Coccidioidal granuloma, 748 Cold, effect of, on Bacillus typhosus 593 Coleman and Buxton’s method of isolation of Bacillus typhosus, 611 Coley’s mixture, 316 Coli-typhoid bacilli, Gram-negative, table of, 650 Collodion capsules, 228 sacs, increase of virulence by use of, 81 preparation of, 229 Colon bacillus, 616. See also Bacillus colt communis Colonies of bacteria, 204, 208 counting, Frost plate counter for, 239 in Esmarch tubes, Esmarch’s apparatus for, 238 Wolthiigel’s apparatus for, 237 Comma bacillus, 570 Complement, 101, 118 fixation, 139 ; test in diagnosis of glands, 709 of sporotrichosis, 764 for Wassermann reaction, 282 Concentrated tuberculin, 671 Conjunctiva, bacteria in, 69 Conjunctival reaction, Chantemesse’s in typhoid, 604 791 Conjunctivitis, acute contagious, 406 miscellaneous organisms in, 410 Conorhinus megistis, 521, 523. See also Lamus megistis Contagion from Bacillus diphtheriz, 424 Coplin’s staining jar, 151 Copper sulphate as disinfectant, 177 Coqueleuch, 441 Corks, sterilization of, 169 Cover-glass forceps, Stewart, 162 Crab lice, 504 Craigia hominis, 655 migrans, 655 Creolin, 179 Croupous pneumonia, 444 Crude tuberculin, 677 Cryptobia borreli, 508 _Ctenocephalus canis, 561 felis, 561 Culex pipiens, 488 Cultivation of anaérobic bacteria, by absorption of atmospheric oxygen, 217 by displacement of air by inert gases, 215 by exclusion of atmospheric air, 219 by formation of vacuum, 215 by reduction of oxygen, 218 of micro-organisms, 187 Culture preparations, museum, 214 Culture-media, 187 agar-agar, 193 alkaline blood-serum, 197 blood agar-agar, 195 blood-serum, 195 bouillon, 190 buret for titrating, 188 Dunham’s solution, 199 gelatin, 192 glycerin agar-agar, 195 litmus milk, 199 Loffler’s blood-serum mixture, 197 milk, 199 Parietti’s, 609 Petruschkey’s whey, 199 potatoes, 197 potato-juice, 198 standard reaction of, 189 sterilization and protection of, 170 sugar bouillon, 192 Cultures, adhesion, 212 agar-agar, 211 freshly isolated, standardizing, 214 gelatin puncture, 209 in fluid media, 212 inoculation of, 203 manipulation of, technic, 202 on blood serum, 211 on potato, 211 ‘plate, 201, 204 pure, 201, 208 special methods of procuring, 212 - shake, 219 792 Cultures, stab, 209 study of, 201 microscopic, 213 Cutituberculin reaction, Ligniéres, 679 Cytase, 118 Cytolysis, 134 technic of, 135 Cytoplasm, 46 Cytotoxins, 133 Czenzynke’s stain for Bacillus influ- enze, 463 - Deap, disinfection of, 185 Decrease of virulence, 80 Defensive ferments, 140 proteins, 108 Dejecta, disinfection of, 175, 183 Delhi boil, 531 Dental caries, bacteria in, 70 Denys’ tuberculin, 680 Dermatitis, blastomycetic, 747 Dermatomycosis, 752 Dermotuberculin reaction, von Pir- quet’s, 679 Desmon, 118 Deycke’s alkali-albuminate, 197 Diarrhea, balantidium, 652 Digestive apparatus, infection through, 72 Diphtheria, 411 antitoxin, 127, 426 determining potency of serum, 128 dosage, 427 effect on death-rate, 429 ' globulin precipitation for concen- tration of, 130 immunization of animals, 128 obtaining blood for, 128 paralysis from, 427 preparation of serum, 128 prophylaxis, 427 treatment with, 427 bacillus of, 411. See also Bacillus diphtherie bacteriologic appearance of throat, 420 characteristics, 419 course, 420 lesions, 422 postmortem appearance of liver, 419 Schick’s reaction in, 428 with mixed infection, 422 Diplobacillen conjunctivitis, 408 Diplococcus, 34 intracellularis meningitidis, 386 agglutination, 391 cultivation, 389 distribution, 387 general characteristics, 386 identification, 387 isolation, 388 metabolic products, 391 mode of infection with, 392 morphology, 387 pathogenesis, 391 Index Diplococcus intracellularis meningi- tidis, specific therapy with, 393 staining, 388 vital resistance, 390 pneumonie, 444 animals susceptible to, 452 cultivation, 447 distribution, 444 general characteristics, 444 identification, 454 immune serum against, 455 immunity against, 455 isolation, 446 Buerger’s method, 447 lesions produced by, 451 metabolic products, 448 morphology, 445 pathogenesis, 449 specificity of, 452 staining, 445 Hiss’ method, 446 Welch’s method, 445 toxic products, 448 virulence, 453 vital resistance, 448 Disease, germ theory.of, 22 production of, 64 tsetse-fly, 512 Diseases, infectious, 299 early classification of, 21 study of, 20 Disinfectants, 176 common, bactericidal strength of, 181 determination of value of, 251 inorganic, 177 organic, 178 Dish forceps, Petri, 206 Dishes, Petri, 206 Disinfection, 167 Evans and Russell’s method, 182 Frankforter’s method, 182 gaseous, 262 of air of sick-room, 176 of clothing, 184 of dead, 185 of dejecta, 175, 183 of furniture, 184 of hands, 172, 174 Lock wood’s method, 174 of instruments, 172 of ligatures, 172 of patient, 185 of room, 182 of sick-chambers, 175 of sutures, 172 of wound, 175 Robinson's method, 182 Distribution of bacteria, 50 Dorset’s method of isolation of tubercle Bacillus, 666 Dourine, 514 ~ Drigalski-Conradi’s method of isola- tion of bacillus typhosus, 608 Drop infection, 67 Index Ducrey’s bacillus, 403. See also Bacil- lus ducreyt Dumdum fever, 525. azar Dunham’s peptone solution, 199 Duval’s method of cultivation of Bacillus leprae, 700 Dyscrasia, 84 Dysentery, 631 amebic, 633 bacillary, 647 distribution, 631 history, 631 See also Kala- EpEMA, gaseous, 332 malignant, 329 Ehrlich’s lateral-chain theory of im- munity, 110 his explanation of, 112-117 method of determining potency of diphtheria serum, 129 of staining tubercle bacillus, 661 Electricity, influences of, on growth of bacteria, 53 Electrozone, 178 Elephantiasis greecorum, 702 . Elsner’s method of cultivation of Bacillus typhosus, 605 Embedding, 150 celloidin, 150 glycerin-gelatin, 151 paraffin, 150 Emulsion, bacillary, 682 Encystment of protozoa, 49 Endogenous infections, 68 Endo’s method of isolation of Bacillus typhosus, 610 Endospores, 32 Endotoxins, 264 Entameeba coli, 634 table of differential features, 643 histolytica, 633, 634 morphology, 634 relationship to Entameeba tetra- gena, 636 reproduction, 634 staining, 634 table of differential features, 643 Mallory’s differential stain for, 647 tetragena, 633, 635 cultivation, 636 isolation, 636 lesions, 644 metabolic products, 642 pathogenesis, 644 relationship to Entameeba tetra- gena, 636 table of differential features. 643 vital resistance, 637 Enteric fever, 589. See also Typhoid fever : Enzymes, production of, 65 Eosin and methylene-blue Mallory’s, 155 stain, 793 BB onle cerebro-spinal meningitis, 3 Epitheliolysins, 102 Erythrasma, 752 Esmarch’s instrument for counting colonies of bacteria in Esmarch tubes, 238 tubes, 207 Eurotium, 42 Evans and Russell’s method of disin- fection, 182 Exhaustion theory of immunity, 105 Exogenous infections, 67 Experimentation upon animals, 222 Extracellular toxins, 76 Farcin du beeuf, 37 Farcy, 711 Farcy-buds, 711 Favus, 755 sculutum formation, 755 specific organism, 755 Febrile tropical splenomegaly, 525. See also Kala-azar Feces, isolation of typhoid bacillus from, 604 staining tubercle bacillus in, 663 Ferment, inflammatory, 23 putrefactive, 23 Fermentation, 19, 57 alcoholic, 57 acetic, 58 butyric acid, 58 lactic acid, 58 Fermentation-tube, Smith’s, 59 Ferments, defensive, 140 Fever, army-, 540 enteric, 589. See also Typhoid fever jail-, 54° malta, 467 Mediterranean, 467 non-malarial remittent, 525. also Kala-azar relapsing, 494 ship-, 540 splenic, 352 spotted, 386 typhoid, 589 yellow, 536 Filter, Berkefeld, 174 Chamberland, 174 Kitasato, 174 Reichel, 174 Filterable viruses, 28 Filtration, sterilization by, 172 Finkler and Prior spirillum, 580 Fiocca’s method of staining spores, 157 Fish tuberculosis, 691 Fishing, 209 Fish-poisoning, 248 Fission of bacteria, 32 Fixateur, 118 Fixation of complement, 139 test of Wassermann. reaction, 291 See 794 Flagella of bacteria, 31 Flagellation, 472 Flagellates, harmless, of human in- testines, 655 Fleas, plague, 559 transmission of plague by, 554 Fleischvergiftung, 59 Flexner variety of dysentery bacillus, 648 Fluid media, cultures in, 212 Fly, tsetse, 517 Fomites, foods as, 245 Food, influences on growth of bacteria, 51 . poisons, 247 Foods as fomites, 245 bacteria in, 245 bacteriology of, 245 effect of bacteria on, 57 Forceps, sterilization of, 169 Formaldehyd, 180 Formalin, 179, 181 Fowl tuberculosis, 690 Frambesia tropica, 729 diagnosis, 731 distribution, 729 history, 729 specific organism, 730 Frankel’s instrument for obtaining earth for bacteriologic study, 244 method of estimating bacteria in soil, 243 of making anaérobic cultures, 216 Frankforter’s method of disinfection, 182 Friedlander, pneumococcus of, 457. See also Pneumococcus Frost’s plate counter for counting colonies of bacteria, 239 Frothy organs, 338 Frugoni’s method of isolation of tu- bercle bacillus, 667 Fungi, imperfect, 40 Fungus, ray-, 732 Furniture, disinfection of, 184 GaBBET?’s method of staining tubercle bacillus, 661 Galactotoxism, 247 Gamaléia, spirillum of, 584, 586 - Gangrene, hospital, 329 Gaseous disinfection, 262 edema, 332 Gases, production of, 59 Smith’s method for nature of, 59 Gastro-intestinal tract, infection with tubercle bacillus through, 670 Gelatin as culture-medium, 192 liquefaction of, by bacteria, 59 puncture culture, 209 Generation, spontaneous, doctrine of, determining 17 Genital apparatus, infection through, 74 : Index Germ theory of disease, 22 Germicides, 167 determination of value of, 251, 252 apparatus for, 253 culture media for, 256 determining phenol coefficient in, 258-261 dilution of phenol and test solu- tions for, 256. inoculating loops for, 254 Koch’s method, 253 modern method of testing, 253 racks for holding tubes in, 256 reagents for, 253 solution to be tested, 254 Sternberg’s method, 253 test organism for, 254 tubes for, 256 water-bath for, 254 Germination of spores, 34 Ghoreyeb’s method of staining Tre- ponema pallidum, 719 Giant-cells in tubercles, 672 Glanders, 706 bacillus, 706. See also Bacillus mallet diagnosis, 708 complement-fixation test, 709 McFadyen’s method, 709 Straus’ method, 708 immunity against, 714 in human beings, 713 lesions, 711, 712 specific organism, 706 Glass tubes, capillary, 202 Glassware, protection of, 167 sterilization of, 167, 169 Globulin precipitation for contentra- tion of diphtheria antitoxin, 130 Glossina bocagei, 518 fusca, 518 longipalpis, 518 longipennis, 518 morsitans, 513, 518 pallicera, 518 pallidipes, 518 palpalis, 512, 513, 518 tachinoides, 518 Glycerin agar-agar, 195 Glycerin-gelatin, embedding, 151 Golden staphylococcus, 302 Goldhorn’s method of staining Tre- ponema pallidum, 719 Gonococcus, 394 Gonorrhea, 394 Gonotoxin, 397 Gordon’s method for detection of Spirillum cholere Asiatice, 577 Gram’s method of staining bacteria in tissue, 152, 153 solution, 152 Gram-Weigert stain, 154 Granuloma coccidioidal, 748 Grass bacillus, Moeller’s, 693 Guinea-pig holder, 225 Index Guinea-pig serum, titration of, for Wassermann reaction, 283 HaFFKINE prophylactic in plague, 557 Halogens as disinfectants, 178 Hands, disinfection of, 172, 174 Lock wood’s method, 174 Hanging block, Hill’s, 145 drop, 145 Hardening, 149 Harris’ method of staining Negri bodies, 368 Harris and Shackell’s treatment of hydrophobia, 378 Head lice, 503 : Heidenhain’s iron hematoxylin stain for protozoa, 165 Heiman’s method of. cultivation of Micrococcus gonorrheee, 396 Helcosoma tropicum, 532, 533 Hemolysis, 1roz, 133 technic of, 134 Hemolytic amboceptor, for Wasser-. mann reaction, 284 serum for Wassermann reaction, titration of, 285 system, 286 test of Wassermann reaction, 291 unit, 286 Hemorrhagin, 132 Hen’s eggs, use of, for anaérobic cul- tures, 220 Herpes circinatus, 752 desquamans, 752 tonsurans, 752 Hesse’s medium for plating Bacillus typhosus, 610 method of making anaérobic cul- tures, 219 of quantitative estimation of bacteria in air, 234 Higher bacteria, 36 Hill’s hanging block, 145 Hiss’ inulin-serum-water test for de- termining pneumococcus, 455 method of cultivation of Bacillus typhosus, 607 of staining Diplococcus pneu- monie, 446 Hiss-Russell variety of, Bacillus dys- enteriz, 648 Histologic lesions in typhoid fever, 597 Histoplasma capsulatum, 534, 535 Histoplasmosis, 534 Historical introduction, 17 Hofmann, bacillus of, 429. Bacillus, pseudo-diphtheria Hog-cholera, 625 : . Hégyes’ treatment of hydrophobia, 374; 378 Hospital gangrene, 329 Host, 66 susceptibility of, 84. ce ptibility Hot-air sterilizer, 169 See also See also Sus- 795 Hiihnercholera, 564 Human malarial parasites, 478 human inoculation with, 486 Hydrophobia, 363 diagnosis, 370 dumb, 372 examination for Negri bodies, 371 histologic changes in nervous sys- tem, 372 immunization against, 374 inoculation of rabbits, 371 pathology, 369 prophylaxis, 373 specific organism, 363 street virus, 372 treatment, 374 Harris and Shackell’s inspissation method, 378 Hégyes attenuation method, 374 dilution method, 378 intensive, scheme for, 378 mild, scheme for, 377 Pasteur’s method, 96, 374, 377 specific, 380 tubercles of Babes in, 372 virulence, 372 Hypnococcus, 508 IcE-CREAM poisoning, 247 Ichthyotoxism, 248 Identification of species of bacteria, 230 Immune bodies, ro1, 118 Immunity, 88 active, 89 acquired, 91 acquired, gi through infection, 91 accidental, 91 experimental, 92 through intoxication, 97 against tetanus, 349 Ehrlich’s lateral-chain theory of, 110 exhaustion theory of, 105 experimental investigation of prob- lems of, 100 explanation of, 105 natural, 89 passive, 89 acquired, 98 relative, 89 retention theory of, 105 special phenomena of, 120 Imperfect fungi, 40 Increase of virulence, 80 Incubating oven, 213 Incubator for opsonic work, 276 Index, opsonic, 270 Indol, production of, 62 Salkowski’s test for, 62 Infantile kala-azar, 530 palsy, 381 Infection, avenues of, 72, 82 cardinal conditions of, 79 definition of, 66 796 Infection, drop, 67 immunity acquired through, 91 number of bacteria causing, 81 sources of, 67 special phenomena of, 120 through digestive apparatus, 72 through genital apparatus, 74 through placenta, 74 through respiratory apparatus, 74 through skin, 72 Infections, endogenous, 68 exogenous, 67 mixed, 86 terminal, 312 Infectious diseases, 299 study of, 20 Inflammation, catarrhal, 400 Inflammatory ferment, 23 Influenza, 462 bacillus of, 462. influenze diagnosis, 466 Infusoria, 46 Infusorial life, 19 Injections, animal, methods of making, 224 $8 : Inoculating loops, 254 device for flaming of, 257 Inoculation, 92 early, for smallpox, 92 of cultures, 203 Inorganic disinfectants, 177 Instruments, disinfection of, 172 sterilization and protection of, 167 Intermediate body, 101 Intermittent sterilization, 170 Intestines, bacteria in, 70 human, harmless flagellates of, 655 Intoxication, immunity acquired bv. See also Bacillus 97 Intracellular toxins, 75 Invasive power of bacteria, 75 Invisible viruses, 28 Todin terchlorid as disinfectant, 178 Isolation of bacteria, 204 Itch, barbers’, 754 Jacxson’s method of isolation. of Bacillus typhosus, 612 Jactationstetanus, 347 Jail-fever, 540 Javelle water, 664 Jaw, lumpy, 732 Jennerian vaccination, 93 Jericho boil, 531, 532 Kata-AzAr, 525 diagnosis, 530 infantile, 530 lesions, 528 transmission, 529 treatment, 530 Kashida and Wiirtz’s method of cul- tivation of Bacillus typhosus, 606 Keidel tube for collecting blood, 281 Index Keuchhusten, 441 Kitasato filter, 174 Klatschpraparat, 212 Klebs-Léffler, bacillus of, 411. also Bacillus diphtherie Knives, sterilization of, 169 Koch-Ehrlich method of staining tu- bercle bacillus, 661 See. Koch-Weeks bacillus, 406. See also Bacillus of Koch-Weeks Koch’s apparatus for coagulating blood-serum, 196 law, 22 method of determining germicidal value, 253 of cultivation of tubercle bacillus, 665 plate cultures, 201 syringe, 222 tuberculin, 676 Kral’s| method of cultivation of Achorion schénleinii, 757 Kreotoxism, 247 Kiihne’s method of staining Bacillus mallei, 707 LaByrINnTH, Starkey’s, Somers’ modi- fication, 609 Lacmoid, 199 Lactic acid fermentation, 58 La fievre typhique, 589. Typhoid fever Laitinen’s method of cultivation of Micrococcus gonorrhcee, 396 Lamblia intestinalis, 655 Lamus megistis, 521, 523. appearance, 523 breeding habits, 524 habitat, 523 habits, 523 Larynx, bacteria in, 72 : Latapie’s animal holder, 225 Latent tuberculosis, 674 Lateral-chain theory of Ehrlich’s, 110 Leishman-Donovan body, 525. also Leishmania donovant — Leishmania donovani, 525 cultivation, 527 distribution, 528 evolution, 526 morphology, 525 furunculosa, 531 cultivation, 533 pathogenesis, 533 infantum, 529, 530 Lepra anesthetica, 702 cells, 702 nodosa, 702 Leprolin, 704 Leprosy, 695 anesthetic, 703 Carrasquilla’s serum for, 704 distribution, 695 history, 695 See also immunity, See i Index 707 Leprosy, lesions, 702 sanitation, 704 specific therapy, 704 Leptopsylla musculi, 560 Leptothrix, 36 ; Leuconostoc, 35 Leukocidin, 305 Leukocytes, washed, in opsonic value of blood, 272 Levaditi’s method of staining Trepo- nema pallidum, 721 Leveling apparatus for making plate cultures, 205 Liborius’ tube for anaérobic cultures, 216 Lice, 505 body, 503 crab, 504 head, 503 réle in transmission of typhus fever, 542 transmission of plague by, 553 Ligatures, disinfection of, 172 sterilization of, 175 Light, influences on growth of bacteria, 52 Ligniéres cutituberculin reaction, 679 Liquefaction of gelatin by, 60 Listerism, 23 Litmus, preparation of, 199 Litmus-lactose-agar-agar, 606 Litmus-milk, 199 Lobar pneumonia, 444 Lock-jaw, 340, 347 Lockwood’s method of disinfection of hands, 174 Léffler’s alkaline methylene-blue, 151 blood-serum mixture, 197 method for detection of Spirillum : cholere Asiatice, 577 of isolation of Bacillus typhosus, 611 of staining Bacillus mallei, 707 bacteria, 151 flagella, 158 Loops, inoculating, 254 Luetin, 724 reaction, Noguchi’s, in diagnosis of syphilis, 727 Lumbar puncture, technic in, 388, 389 Lumpy jaw, 732 Lungs, bacteria in, 72 Luzzani’s method of staining Negri bodies, 369 Lysin, ror Lysol, 179 Lyssa, 363. See also Hydrophobia MacConxeEy’s method of isolation of Bacillus typhosus, 612 Macrocytase, 107 Macrophages, 106 Madura-foot, 741 Makrogametes, 477 Makrogametocyte, 477 Maladie du coit, 514 Maladie du sommeil, 506. See also Sleeping sickness Malaria, 471 fever in, 471 geographic distribution, 471 history of, 471 parasites of, 472 animal inoculation, 486 cultivation, 484 Bass and Johns’ method, 484 human, 478 inoculation with, 486 paroxysms of, 471 pathogenesis, 486 prophylaxis, 486 human beings, 486 mosquitoes, 486 relation of mosquitoes to, 473, 488 Malignant edema, 329 polyadenitis, 543. See also Plague pustule, 359 Mallein, 711 Mallory’s differential stain for en- tameeba, 647 method of staining, 155 Malta fever, 467 bacteriologic diagnosis, 468 treatment, 469 Manouelian’s method of staining Treponema pallidum, 722 Marino’s stain for protozoa, 164 Mastigophora, 45 McFadyen’s method of diagnosis of glanders, 709 Meat, bacteria in, 246 extract, preparation of bouillon from, 191 fresh, preparation of bouillon from, 190 Meat-infusion, 190 Meat-poisoning, 59, 247 Medical contributions, 20 Mediterranean fever, 467 Megastomum intestinalis, 655 Melanoid mycetoma, 741, 744 Meningitis, cerebrospinal, 386 Meningococcus, 386 Mercuric chlorid as disinfectant, 177 Merismopedia, 34 Merozoits, 477 Metabolism, influences on growth of bacteria, 57 Metazoa, 44 Metschnikoff’s theory of phagocytosis, 106 Meyer’s syringe, 222 Mice, destruction of, by Bacillus typhi murium, 630 Micrococci, 34 Micrococcus catarrhalis, 388, 400 cultivation, 401 general characteristics, 400 morphology, 401 pathogenesis, 401 798 Micrococcus catarrhalis, staining, 401 gonorrheee, 394 cultivation, 395 Heiman’s method, 396 Laitinen’s method, 396 Wassermann’s method, 396 Wertheim’s method, 395 Young’s method, 396 _ diagnosis of gonorrhea from, 307 distribution, 394 . general characteristics, 394 immunization against, 399 isolation, 395 morphology, 394 pathogenesis, 398 staining, 395 toxic products, 397 vital resistance, 396 melitensis, 467 cultivation, 467 general characteristics, 467 morphology, 467 pathogenesis, 469 staining, 467 thermal death point, 407 tetragenus, 318 cultivation, 319 / general characteristics, 318 isolation, 319 morphology, 319 pathogenesis, 320 staining, 319 Microcytase, 107 Microgametes, 477 Microgametocyte, 477 Micromillimeter, 26 Micron, 27 Micro-organisms, classification of, 26 cultivation of, 187 measurement of, 166 methods of observing, 144 photographing, 166 specific, 299 structure of, 26 Microphages, 106 Microscopic study of cultures, 213 Microspira, 35 Microsporon, 41 Miliary tubercle, 673 Milk as culture-medium, 198 Bacillus typhosus in, 594 bacteria in, 245 peptonization of, 64 Milk-poisoning, 247 Milzbrand, 352 Mixed infections, 86 pneumonias, 461 Mixture, Coley’s, 316 Moeller’s grass bacillus, 693 Moisture, influences on growth of bac- teria, 52 Moids, 40 black, 41 Méller’s method of staining spores, 157 Index Morax-Axenfeld bacillus, 408. See also Bacillus of Morax-Axenfeld Morphology of bacteria, 34 Morve, 706 Mosquitoes, breeding habits, 490 classification, 489 destruction ‘of, malaria, 487 development of larvaz, 490 of pupz, 490 habits of pup, 491 longevity of female, 491 method of dissection, 493 of infecting with malarial para- sites, 493 of mounting, 492, 493 relation to malaria, 473, 488 yellow fever and, 537 Motility of bacteria, 32 Mouse holder, 225 Mouth, bacteria in, 69 Movement, influences on growth of bacteria, 54 of protozoa, 48 Mucor, 41 conoides, 42 corymbifer, 42 pusillus, 42 ramosus, 42 rhizopodiformis, 42 septatus, 42 Mucous membranes, bacteria in, 68 Muguet, 438 Muir and Ritchie’s method of staining spores, 156 Museum culture preparations, 214 Mussel-poisoning, 248 Mycetoma, 741 characteristics, 741 distribution, 741 melanoma, 741 melanoid form, 744 ochroid, 741 Mycophylaxins, 108 Mycosozins, 108 Mytilotoxism, 248 Myzorrhynchus pseudopictus, 488 in prevention of NAGANA, 512 Natural immunity, 89 Needles, platinum, for transferring bacteria, 202 Negri bodies, 363. See also Neuror- rhyctes hydrophobiea Neisser-Wechsberg phenomenon, 136, 1370 : Nephrolysins, 102 Nephrotoxins, 102 Nessler’s solution, 64 Neurorrhyctes hydrophobiz, ak cultivation, 366 morphology, 364 staining, 367 Harris’ method, 368 Luzzani’s method, 369 Index Neurorrhyctes hydrophobia, staining, Reichel and Engle’s method, ..369 Williams and method, 368 Newman’s method of staining flagella, Smith’s modification, 161 Nichols and Schmitter’s method of making anaérobic cultures, 217 Nicolle, N. N. N. medium of, 527 modification of Gram’s method, 154 Nitrate broth, 63 Nitrates, formation of, 62 reduction of, 63 Nitrobacter, 63 Nitrogen, combination of, 64 Nitrosococcus, 63 Nitrosomonas, 63 N. N. N. medium of Nicolle, 527 Nocard, bacillus of, 625 Nocard and Roux’s method of culti- vating Bacillus tuberculosis, 665 Noguchi’s luetin reaction in diagnosis of syphilis, 727 method of cultivation of Treponema pallidum, 722 modification of Wassermann reac- tion, 204 . Non-chromogenic bacteria, 61 Non-malarial remittent fever, See also Kala-azar Non-pathogenic bacteria, 64 Nose, bacteria in, 71 Novy’s jars for anaérobic cultures, 216 Nucleus of bacteria, 31 of protozoa, 48 Lowden’s 525. OcHRomjmycetoma, 741 * Odors, production of, by bacteria, 62 Oidia, 39 Oidium albicans, 39, 438 cultivation, 439 fermentation, 440 immunity against, 440 metabolic products, 440 morphology, 438 pathogenesis, 440 Onychomycosis, 752 Oscysts, 49, 477 Odkinetes, 49, 477 Ophidiomonas, 36 Ophthalmo-tuberculin reaction, Cal- mette’s, 679 Opilacao, 519 Opsonic index, 270 determination of, 277 negative phase of, 277 positive phase of, 277 theory, 270 value of blood, requirements test of, 270 serum in testing, 273 washed leukocytes in, 272 work, incubator for, 276 Opsonins, 107, 270 for 799 Opsonizing pipet, 274 Optional anaérobes, 51 Organic disinfectants, 178 Oriental sore, 531, 533 Ornithodorus moubata, 499, 502, 521 habitat, 504 savignyi, 499, 501 habitat, 502 Oven, incubating, 213 Oxygen, influences on growth of bac- terla, 50 relation to tubercle bacillus, 669 Oysters, Bacillus typhosus in, 595 bacteria in, 246 PALUDISM, 471 Paracolon bacillus, 614 Paraffin embedding, 150 Parasite, 66 stomatitis, 438 Parasites, malarial, 472 animal inoculation with, 486 cultivation, 484 human, 478 inoculation with, 486 pathogenesis, 486 Parasitic ameba, reproductive cycle of, 635 bacteria, 66 Paratyphoid bacilli, 614 Pariette’s culture fluid, 609 Paroxysms of malaria, 471 Passive anaphylaxis, 105 immunity, 89 acquired, 98 Pasteur-Chamberland filter, 173 Pasteurization, 171 Pasteur treatment of rabies, 96, 378 schemata for, 377 vaccination, 95 Pathogenesis, 75 Pathogenic bacteria, 64 Pathogens, 57 Patient, disinfection of, 185 Pawlowski’s method of isolation of tubercle bacillus, 666 Peabody and Pratt’s method of isola- tion of Bacillus typhosus, 611 Pediculus capitis, 503, 505 pubis, 504 vestimenti, 503, 505 Penicillium, 44 Peptone solution, Dunham’s, 199 Peptonization of milk, 64 Peroxid of hydrogen, 179 Pertussis, 441 Pest, 543. See also Plague Petkowitsch’s method for isolation of Bacillus typhosus, 608 Petri dish, 206 advantages of, 207 forceps, 206 method of quantitative estimation of bacillus in air, 235 sand filter, for air-examination, 236 800 Petruschkey’s whey, 199 Pfeiffer’s method of staining bacteria, ISI phenomenon, ror Phagocytes, 106 Phagocytic power of blood, 270 Phagocytosis, Metschnikoff’s theory of, 106 Phagolysis, 107 Phenol coefficient, technic of deter- mining, 258-261 Phenomenon, Bordet-Gengou, 139 Neisser-Wechsberg’s, 136 ' Pfeiffer’s, ror Theobald Smith’s, 103 Phlogosin, 305 Phosphorescence, bacteria, 62 Photogens, 57 Phthirius inguinalis, 504, 505 Phycomycetes, 40 Phylaxins, 108 Pied de Madure, 741 Pig typhoid, 625 Pink eye, 406 Piorkowski’s method of cultivation of Bacillus typhosus, 608 Pipet, opsonizing, 274 special blood, 274 Pitfield’s method of staining flagella, 159 modification, Smith’s, 159 Pityriasis versicolor, 752 Placenta, infection through, 74 with tubercle bacillus, 669 Plague, 543 buboes in, 544 characteristics, 544 death-rate, 544 diagnosis, 555 experimental infection, 550 fleas, 559 breeding habits, 560 life history, 559 longevity, 560 method of extermination, 560 table for identification, 563 varieties, 560, 561, 562 group of micro-organisms, 563 history, 543 immunity against, 557 active, 557 Haffkine prophylactic, for, 557 passive, 558 pneumonia, 461 postmortem appearance in, 555 prophylaxis, 557 tat extermination in, 557 sanitation in, 556 serum treatment, 559 specific organism, 545 spread of, 543 transmission by fleas, 553, 554 by flies, 552 by lice, 553 production of, by . Index Plague, by rats, 550, 551, 553 varieties, 545 Planococcus, 34 Planosarcina, 34 Plasmodium falciparum, 482 gametocytes of, 483 malariz, 471, 478 gametocytes of, 479 meroblasts of, 479 _ spores of, 477 vivax, 471, 479 developmental cycle of, 476 gametocytes of, 481 Plasmolysis, 31 Plate cultures, 204 disadvantages of, 206 leveling apparatus for making, 205 of Koch, 201 Platinum needles for transferring bac- teria, 202 wires for bacteriologic use, 202 sterilization of, 169, 202 Pneumobacillus, 457. See also Pneu- mococcus Pneumococcus, 444, 457 cultivation, 458 distribution, 457 general characteristics, 457 Hiss’ inulin-serum-water test for de- termining, 455 morphology, 458 pathogenesis, 459 virulence, 461 vital resistance, 459 Pneumonia, 444 bacteriologic diagnosis, 454 broncho-, 461 catarrhal, ‘461 croupous, 444 lobar, 444 mixed, 461 plague, 461 sanitation in, 456 tuberculous, 461 Poisoning, cheese-, 247 fish-, 248 from canned goods, 248 ice-cream, 247 meat-, 247 milk-, 247 mussel-, 248 Poisons, food, 247 Polar granules of bacteria, 31 Poliomyelitis, acute anterior, 381. See also Acute anterior poliomyelitis Polyadenitis, malignant, 543. Seealso Plague Polyvalent vaccines, 317 Ponos, 530 Post-mortems on animals, 228 Potassium permanganate as disinfect- ant, 178 / Potato, cultures on, 211° Potato-cutter, Ravenel, 198 Potato-juice as culture-medium, 198 Index Potatoes as culture-medium, 197 Pratt and Peabody’s method of isola- tion of Bacillus typhosus, 611 Precipitate, specific, 100 Precipitation, specific, 120 Precipitinogen, 122 Precipitins, 120, 122 Predisposition, 84 Prodigiosus powder, 361 Production of phosphorescence by bacteria, 62 Proskauer and Beck’s method of cul- tivation of tubercle bacillus, 667 Protection of culture-media, 170 of instruments and glassware, 167 Proteins, defensive, 108 Protista, 26 Protophyta, 26 Protozoa, 26, 44 classification of, 44, 45 encystment of, 49 living, observation of, 161 movement of, 48 nucleus of, 48 reproduction of, 49 size of, 48 staining, 162. structure of, 46 . Pseudo-diphtheria bacillus, 429. See also Bacillus pseudo-diphtherie Pseudodysentery bacillus, 648 Pseudo-glanders bacillus, 714 Pseudo-influenza bacillus, 466 Pseudomonas, 35 Pseudo-tetanus bacillus, 351 Pseudotuberculosis, 694 Ptomains, 58 Pulex irritans, 553, 562 Pure cultures, 201, 208 Pustule, malignant, 359 Putrefaction, 19, 58 Putrefactive ferment, 23 Pyemia, 79 Pyocyanase, 65, 323 Pyocyanolysin, 323 See also Staining Ragsit septicemia, bacillus of, 564 Rabies, 363. See also Hydrophobia Rats, transmission of plague by, 550, 551, $53 Ravenel’s potato-cutter, 198 Ray-fungus, 732 Reaction, Calmette’s ophthalmo-tuber- culin, 679 influences on growth of bacteria, 52 Ligniéres cutituberculin, 679 von Pirquet’s dermotuberculin, 679 Wassermann, 139 Widal, 123 Receptors, 112, 125 ‘Refined tuberculin, 677 Regressive schizogony, 478 Reichel filter, 174 Reichel and Engle’s method of stain- ing Negri bodies, 369 51 801 Relapsing fever, 494 bacteriologic diagnosis, so1 course, 500 immunity against, sor lesions, 501 transmitted by ticks, 499 vectors of, sor Relative immunity, 89 Rémy’s method of cultivation of Bacillus typhosus, 606 Reproduction of bacteria, 32 of protozoa, 49 Respiratory apparatus, through, 74 tract, infection with tubercle bacillus through, 669 infection * Retention theory of immunity, 105 Rhinoscleroma, 715 Rhipicephalus decoloratus, 494 Rhizopoda, 45 Rice-water discharges in cholera, 576 Ringworm, 752 Robinson’s method of disinfection, 182 Romanowsky’s method of staining protozoa, 163 Room, disinfection of, 182 Ross’ method of staining protozoa, 166 Rossi’s method of staining flagella, 160 Rost’s method of cultivation of Bacil- lus lepre, 699 Rothberger’s method of cultivation of Bacillus typhosus, 607 Rotz, 706 Roux’s bacteriologic syringe, 222 Roux and Nocard’s method of culti- vating tubercle bacillus, 665 Rubber stoppers, sterilization of, 169 Asiatic SACCHAROMYCES cerevisiz, 39 hominis, 39, 747 Saccharomycosis hominis, 747 Sacs, collodion, preparation of, 229 Salamonsen’s method of making anaérobic cultures, 220 Salkowski’s test for indol, 62 Salts as disinfectants, 177 Sand filter, Petri’s, for air-examina- tion, 236 Sanitation in Asiatic cholera, 580 in plague, 556 in pneumonia, 456 Sapremia, 79 Saprogens, 57 Saprophytic bacteria, 66 Sarcina, 34 : Sarcopsylla penetrans, 561 Scarlatina, streptococcus in blood in, 313 Schaumorgane, 338 Schering’s method of embedding, 150 Schick’s reaction in diphtheria, 428 Schizogony, regressive, 478 Schizonts, 475 . Schizotrypanum cruzi, 518 802 Schizotrypanum cruzi, cultivation, 521 morphology, 520 pathogenesis, 521 reproduction, 520 transmission, 521 Schlaffkrankheit, 506. ing sickness Schottelius method of making pure cultures of Spirillum cholerze Asiat- ice, 572 Schuffner’s granulations, 482 Scissors, sterilization of, 169 Scutulum, 755 Sedgwick’s expanded tube for air- examination, 236 method of quantitative estimation ; of bacteria, 235 Seeding, 256 tubes, 256 Seitenkettentheorie of Ehrlich, 110 Semmelformig, 394 Sensitization of vaccines, 269 Septic tank method of sewage dis - posal, 57 Septicemia, 79 rabbit, bacillus of, 564 Serum, antipneumococcus, 456 antirabic, 380 -antistreptococcus, 316 antitubercle, 683 antivenomous, 132 bacteriolytic, therapeutic uses of, 138 Coley’s, 316 disease, 103 in testing opsonic value of blood, 273 in Wassermann reaction, 281 guinea-pig, titration of, 285 hemolytic, titration of, 285 . treatment of Asiatic cholera, 579 Sewage, colon bacillus in, 623 disposal by septic tank method, 57 Sexual apparatus, infection with tuber- cle bacillus through, 670 Shake culture, 219 Sheep corpuscles, titration of, for Wassermann reaction, 285 Shiga’s bacillus, 647. See also Bacillus dysenteria Shiga-Kruse bacillus, 648 Ship-fever, 540 Siberian pest, 352 Sick-chambers, disinfection of, 175 Sick-room, disinfection of air ‘of, 176 Silver nitrate as disinfectant, 178 Size of bacteria, 27 of protozoa, 48 Skin, bacteria in, 68 infection through, 72 Sleeping sickness, 506 clinical picture, 506 lesions in, 516 prophylaxis, 517 specific organism, 507 See also Sleep- variety of dysentery Index Sleeping sickness, transmission to lower animals, 514 Smallpox, early inoculation for, 92 Smith fermentation-tube, 59 method of determining Bacillus coli in water, 249 for determining nature of gases, 59 modification of Newman’s method of staining flagella, 161 of Pitfield’s method of staining flagella, 159 Smith’s (T.) method of isolation of tubercle bacillus, 666 Soil, bacteria in, 243 Frinkel’s method of estimating, 243 bacteriology of, 243 Solution, Nessler’s, 64 Soor, 438 Sore, Oriental, 531, 533 Sources of infection, 67 Sozins, 108 Species of bacteria, identification of, 230 Specific action of toxins, 77 affinity of cells for toxins, 78 micro-organisms, 299 Spermatoxin, 102 Spermatozoits, 477 Spinale Kinderlihmung, 381 Spirilla resembling cholera spirillum, 580 table for differentiating, 588 Spirillum, 35 cholere Asiatice, 568 cultivation, 572 detection, 577 Gordon’s method, 577 Léffler’s method, 577 distribution, 569 general characteristics, 568 immunity against, 578 isolation, 572 metabolic products, 575 morphology, 570 pathogenesis, 575 Schottelius’ method of making pure cultures, 572 specificity, 577 staining, 571 toxic products, 575 metchnikovi, 584. See also Spiril- lum of Gamaléia obermeieri, 494. See also Spiro- cheta obermeieri of Finkler and Prior, 580 cultivation, 580, 584 metabolic products, 582, 584 morphology, 580, 583 pathogenesis, 582, 584 staining, 580 of Gamaléia, 584 cultivation, 584 immunity against, 586 metabolic products, 585 Index 803 Spurllan of Gamaléia, morphology, 584 pathogenesis, 585 staining, 584 vital resistance, 585 schuylkiliensis, 586 cultivation, 586 immunity against, 587 metabolic products, 586 morphology, 586 pathogenesis, 587 vital resistance, 587 Spirocheta, 36 anserinum, 494 berbera, 405 carteri, 495 duttoni, 494 gallinarum, 494 Kochi, 495 novyi, 495 obermeieri, 494 cultivation, 497 general characteristics, 496 mode of infection, 498 morphology, 496 pathogenesis, 500 staining, 497 pallidum, 718. See also Treponema pallidum persica, 495 recurrentis, 494. See also Spiro- cheta obermeieri refringens, 718, 728 theileri, 494 vincenti, 433, 437 Bacillus fusiformis and, relation, 434 | cultivation, 434 morphology, 436 Spiromonas, 36 Spirosoma, 35 Spirulina, 36 Splenic fever, 352 Splenomegaly, febrile tropical, 525. See also Kala-azar : Sporangia, 41 Spores, germination of, 34 staining, 156 Sporocysts, 49 Sporotrichosis, 750 clinical varieties, 764 ” diagnosis, agglutination test, 764 bacteriologic, 764 complement-fixation test, 764 disseminated gummatous, 764 subcutaneous, with ulceration, _ 764 lesions, 763 localized, 764 mixed forms, 764 specific organism, 759 Sporotrichotic chancre, 764 Sporotrichum, 759 beurmanni, 759 asteroides, 759 Sporotrichum beurmanni,indicum,759 gougerati, 759 - jeanselmei, 759 schencki, 759 cultivation, 761 distribution in nature, 762 lesions caused by, 763 metabolic products, 762 morphology, 761 pathogenesis, 762 staining, 761 vital resistance, 762 Sporozoa, 45 furunculosa, 533 Sporozoits, 475, 477 Sporulation of bacteria, 32 Spotted fever, 386 Sputum, staining tubercle bacillus in, 659 typhoid bacilli in, 598 Stab culture, 209 Stain, Mallory’s eosin-methylene blue, 155 Staining bacteria, 146 aqueous solutions for, 148 Gram’s method, 152, 153 Nicolle’s modification, 154 Gram-Weigert method, 154 Léffler’s method, 151 Pfeiffer’s method, 151 simple method, 147, 150 stock solutions for, 148 Zieler’s method, 155 flagella, Léffler’s method, 158 Newman’s method, Smith’s modi- fication, 161 Pitfield’s method, 159 Smith’s modification, 159 Rossi’s method, 160 Van Ermengem’s method, 159 jar, Coplin’s, 151 protozoa, Biondi-Heidenhain meth- od, 165 cover-glasses for, 162 Heidenhain’s method, 165 Marino’s method, 164 Romanowsky’s method, 163 Ross’ method, 166 slides for, 162 tissue, 165 Wright’s method, 163 spores, 156 Abbott’s method, 156 Anjeszky’s method, 157 Fiocca’s method, 157 Moller’s method, 157 Muir and Ritchie’s method, 156 Standard reaction of culture-media, 189 Standardizing freshly isolated cultures, 214 Staphylococci of man, chief types, 301 Staphylococcus, 35 citreus, 308 epidermidis albus, 300 golden, 301 804 Staphylococcus pyogenes albus, 300 aureus et albus, 302 agglutination, 307 bacterio-vaccination, 307 colonies of, 303 cultivation, 303 distribution, 302 isolation, 303 metabolic products, 304 morphology, 303 pathogenesis, 306 serum therapy, 307 staining, 303 thermal death point, 304 toxic products, 305 _ virulence, 307 Staphylolysin, 305 Starkey’s labyrinth, Somers’ modifica- tion, 609 method of isolation of Bacillus typhosus, 609 Stegomyia calopus, 537 fasciata, 537 Sterilization, 167 by filtration, 172 in autoclave, 171 intermittent, 170 methods of, 169 of corks, 169 of culture-media, 170 of forceps, 169 of glassware, 167, 169 of instruments, 167 of knives, 169 of ligatures, 175 of platinum wires, 169 of rubber stoppers, 160 of scissors, 169 of surgical instruments, 175 of wooden apparatus, 169 Sterilizer, Arnold’s steam, 171 hot-air, 169 Sternberg’s bulbs, 250 ‘ method of determining germicidal value, 253 Stern’s method of staining Treponema pallidum, 720 Stewart cover-glass forceps, 149 Stock vaccines, 265 Stomach, bacteria in, 70 Stomatitis, parasite, 438 Straus’ method of diagnosis of glanders, 709 Streptobacillus, 403 Streptococcus, 35 brevis, 310. conglomeratus, 311 diffusus, 311 erysipelatis, 318 in blood in scarlatina, 313 mucosus, 317 pyogenes, 308 cultivation, 310 differential features, 311 general characteristics, 308 Index Streptococcus pyogenes, isolation, 310 metabolic products, 314 morphology, 309 pathogenesis, 312 staining, 310 toxic products, 315 virulence of, 313 vital resistance of, 311 vaccine, 317 viridans, 312 Streptokolysin, 315 Streptothrix, 37 actinomyces, 37 farcinica, 37 madure, 37 Structure of bacteria, 30 of protozoa, 46 Subculture tubes, block for, 257 Subinfection, 66 Substance-sensibilisatrice, 118 Sucholotoxin, 627 Sugar bouillon, 192 Sulphur grain, 734 Suppuration, 299 bacteria associated with, 299 Surgical contributions, 20 instruments, sterilization of, 175 Susceptibility from diet, 85 from exposure, 85 from fatigue, 85 from inhalation of noxious vapors, 84 from intoxication, 85 from morbid conditions in general, 86 from mutilation of body, 86 from traumatic injury, 86 of host, 84 : Susotoxin, 627 Suspension, bacterial, 270 Sutures, disinfection of, 172 Swarmers, 655 Swine-plague, bacillus of, 566 Symbiosis, influences on growth of bacteria, 54 Synopsis of groups of Chester’s, 231-233 Syphilis, 718 bacillus of, 718. pallidum diagnosis, 726 by Noguchi’s luetin reaction, 727 by serum, 726 by von Pirquet tuberculin reac- tion, 726 ; by Wassermann reaction, 279, 726 lesions, 726 Syphilitic antigen, 279 Syringe, Altmann’s, 223 Koch’s, 222 Meyer’s, 222 Roux’s bacteriologic, 222 System hemolytic, 286 bacteria, See also Treponema TABARDILLO, 540 Temperature, influences on growth of bacteria, 55 Index Temperature, sensitivity of tubercle bacillus to, 669 Terminal infections, 312 Test, tuberculin, for bovine tuber- culosis, 689 Tetanolysin, 76, 102, 131, 345, 347 Tetanospasmin, 76, 131, 345 Tetanus, 340 antitoxin, 131 ascendens, 346 bacillus of, 340. tetant clonic convulsions in, 346 descendens, 346 dolorosus, 347 lockjaw of, 347 opisthotonos of, 347 pathogenesis, 347 prophylactic treatment, 351 tonic convulsions in, 346 trismus of, 347 Tetracoccus, 34 Theobald Smith phenomenon, 103 Therapy, blood-serum, 24, 222 Thermal death-point of bacteria, de- termination of, 249 Thermophilic bacteria, 55 Thrush, 438 Tick fever, 494 Ticks, 501 in transmission of relapsing fever, 500 . Tinea circinata, 752 favosa, 755 imbricata, 752 trichophytina, 752 unguium, 752 versicolor, 752 Toxemia, 79 Toxins, extracellular, 76 intracellular, 75 specific action of, 77 affinity of cells for, 78 Toxoids, 111 Toxophylaxins, 108 Toxosozins, 108 Trachea, bacteria in, 72 Treponema, 36 pallidulum, 729 pallidum, 718 cultivation, 722 Noguchi’s method, 722 distribution, 722 film staining, 719 : Ghoreyeb’s method, 719 Goldhorn’s method, 719 Stern’s method, 720 general characteristics, 718 identifying by Burri’s India ink method, 721 morphology, 718 pathogenesis, 725 section staining, 721 Levaditi’s method, 721 Manouelian’s method, 722 See also Bacillus 805 Treponema pallidum, specificity, 725 pertenue, 729 cultivation, 730 morphology, 730 pathogenesis, 730 staining, 730 Trichomonas intestinalis, 655 ’ Trichophyton, 41 acuminatum, 752 ~circonvulatum, 752 crateriforme, 752 effractum, 752 exsiccatum, 752 flavum, 752 fulmatum, 752 glabrum, 752 megalosporon, 752 microsporon, 752 pilosum, 752 plicatili, 752 polygonum, 752 regulare, 752 sulphureum, 752 tonsurans, 752 cultivation, 753 morphology, 753 pathogenesis, 754 umbilicatum, 752 violaceum, 752 Trikresol, 179 Trismus, 347 Tropical ulcer, 531 organism, 533 preventive inoculation, 534 transmission, 534 treatment, 534 Trypanosoma avium, 508 brucei, 508 castellani, 509 cruzi, 520. See panum crust equinum, 508 equiperdum, 514 gambiense, 506, 508 cultivation, 510 distribution in body, 515 morphology, 509 pathogenesis, 514 reproduction, 510 staining, 510 transmission, 511 granulosum, 508 lewisi, 508 raje, 508 rhodesiensi, 506. soma gambiense rotatorium, 508 solee, 508 theileri, 503 transvaliense, 508 ugandense, 509 various species, 508 Trypanosomiasis, American, 518 human, 506. See also Sleeping sickness also Schizotry- See also Trypano- 806 Tsetse fly, 517 appearance, 517 breeding habits, 518 disease, 512 habitat, 517 habits, 517 larva of, 518 table for identification of, 518 Tube, expanded, Sedgwick and Tuck- er’s, for air-examination, 236 Keidel, 281 Tubercle bacillus, 656. lus tuberculosis Tubercles, 673 crude, 674 giant-cells in, 672 healed, 675 miliary, 673 of Babes, 372 Tuberculin, concentrated, 677 crude, 677 dangers from, 678 Denys’, 680 effect on tubercle bacillus, 678 Koch’s, 676 preparation, 678 refined, 677 test for bovine tuberculosis, 689 Tuberculin-R, 680 Tuberculin-TR, 680 Tuberculinic acid, 676 Tuberculocidin, 680 Tuberculosamin, 676 Tuberculosis, 656 bacillus of, 656. tuberculosis bovine, 685 communicability to man, 686 lesions, 686 prophylaxis, 683 tuberculin test for, 689 ‘diagnosis, Calmette’s ophthalmo- tuberculin reaction, 679 Morro’s method, 679 von Pirquet’s cutaneous method, See also Bacil- See also Bacillus 679 eos Ligniére’s modification, _ 679 Wolff-Eisner ophthalmo-tubercu- lin method, 680 distribution, 656 fish, 691 fowl, 690 latent, 674 lesions, 671 prophylaxis against, 684 pseudo-, 604 specific organism, 6 56 Tuberculous pneumonia, 461 Tubes, Esmarch, 207 seeding, 256 Tucker’s expanded examination, 236 Typhoid carriers, 595 fever, 589 tube for air- Tndex Typhoid fever, bacillus of, 589 bacteriologic diagnosis, 603 blood-culture in, 603 conjunctival reaction in, 604 histologic lesions, 597 in lower animals, 599 isolation of bacillus from feces, 604 pathogenesis, 597 prophylactic vaccination againet, 600 prophylaxis, 599 specific therapy, 601 _ Widal reaction in, 603 pig, 625 Typhus abdominalis, 540, 580. also Typhoid fever exanthematicus, 540 fever, 540 inoculation into animals, 541 transmission by lice, 542 See _ Tyrotoxicon, 58, 247 Tyrotoxism, 247 Utcer, tropical, 532 Umstimmung, 727 Unit, amboceptor, in Wassermann re- action, 286 hemolytic, 286 Urethra, bacteria in, 71 Urine, staining smegma bacillus in, 66 3 tubercle bacillus i in, 662 typhoid bacilli in, 598 Uterus, bacteria in, 71 VACCINATION against typhoid, 600 efficient, 94 inefficient, 94 Jennerian, 93 Pasteur, 95 Vaccines, 93 autogenous, 265 bacterio-, 263 dosage of, 268 method of making, 265 polyvalent, 317 sensitization of, 269 stock, 265 streptococcus, 317 Vagina, bacteria in, 71 Van Ermengem’s method of staining flagella, 159 Vectors of relapsing fever, 501 Vegetables, bacteria in, 243 Bacillus typhosus i in, 595 Vibrio, 35 lineola, 728 proteus, 580. See also Spirillum, Finkler and Prior Vibrion septique, 329 Vibrionensepticemia, 586 Vincent’s angina, 433 Virulence, 79 decrease of, 80 increase of, 80 Index Virulence, increase of, by addition of animal fluids to culture-media, Tr by passage through animals, 80 by use of collodion sacs, 81 Viruses, filterable, 28 invisible, 28 Von Pirquet cutaneous reaction for diagnosis of syphilis, 726 dermotuberculin reaction, 679 WASSERMANN’S method of cultivation of Micrococcus gonorrheee, 396 reaction, 139, 279, 726 amboceptor dose in, 286 unit in, 286 antigen in, 279 blood-corpuscles for, 283 complement for, 282 fixation test of, 291 hemolytic amboceptor for, 284 titration of, 284 system in, 286 test of, 291 nature of, 294 Noguchi’s modification of, 294 obtaining blood for, 282 reagents employed, 279 serum to be tested in, 281 technic of, 279, 280 theoretic basis of, 280 titration of antigen in, 288 of guinea-pig serum for, 285 of hemolytic serum for, 285 of sheep corpuscles for, 285 validity of, 294 Water, Bacillus coli in, 2390 Smith’s method of determining, (239 bacteria in, 50, 237 number of, 238 method of determining, 237 bacteriology of, 237 drinking, colon bacillus i in, 622 Water-bath, 254, 255 Welch’s method of staining Diplo- coccus pneumonia, 445 Wertheim’s method of cultivation of Micrococcus gonorrheee, 395 Whey, Petruschkey’s, 199 Whooping-cough, 441 Widal reaction, 123 in typhoid fever, 603 807 Wildseuche, bacillus of, 566 Willcomb’s method of counting hac- teria, 238 Williams and Lowden’s method of staining Negri bodies, 368 nn s method of counting bacteria, 23 Wires, platinum, for bacteriologic use, 202 Wolfhiigel apparatus for counting col- onles of bacteria on plates, 237 Wooden apparatus, sterilization of, 169 tongue, 732 Wool-sorters’ disease, 358 ; Wounds, disinfection of, 175 tubercle bacillus, infection through, 671 Wright’s blood-stain for protozoa, 163 method of counting bacteria in sus- pension, 238 of making anaérobic cultures, 218, 220 Wiirtz and Kashida’s method of culti- vation of Bacillus typhosus, 606 XENOPSYLLA cheopis, 552, 554, 561,562 Xerosis, bacillus of, 431 X-rays, influences on growth of bac- teria, 53 Y BACILLUS, 648 Yaws, 729. See tropica Yeasts, 38 Yellow fever, 536 mosquitoes and, 537 prophylaxis, 539 rules for prevention, 538 Young’s method of cultivation of Micrococcus gonorrhcee, 395 also Frambesia ZENKER’S fluid, 149 Ziehl’s method of staining Bacillus typhosus, 590 tubercle bacillus, 661 Zieler’s method of staining, 155 Zinsser’s method of making’ anaérobic cultures, 218 gut Bacterium pneumonia, 457 Zur Nedden’s bacillus, 409 Zygospores, 41 Zygote, 477 Zymogens, 57 : SAUNDERS’ BOOKS ~ on SURGERY and ANATOMY W. B. SAUNDERS COMPANY WEST WASHINGTON SQUARE PHILADELPHIA 9, HENRIETTA STREET COVENT GARDEN, LONDON Crile & Lower’s Anoci-Association Anoci-Association. By GrorcE W. Critz, M.D., F.R.C.S., Pro- fessor of Surgery, and Wixt1am E. Lower, M. D., Assistant Professor of Genito-Urinary Surgery, Western Reserve University. Octavo of 275 pages, illustrated. Cloth, $3.00 net. REPRINTED IN TWO MONTHS Anoci-association robs surgery of its harshness, diminishes postoperative mortality, lessens shock, nausea, vomiting, gas pains, backache, nephritis, pneumonia, and other postoperative complications. You get here, first of all, a monograph on shock—its kinetic theory, its histologic and clinical pathology, and its treatment. Then follow chapters on the principles of axoct-association ; the technic of cts appii- cation in the administration of the anesthetic in abdominal, gynecologic, and genito-urinary work ; in operations for cancer of the breast, rectum, stomach, uterus, larynx, and tongue ; in exophthalmic goiter operations ; in operations on the brain and the extremities. Then come chapters on anoct-assoctation and blood- pressure, and the technic of nitrous-oxid-oxygen anesthesia. Crile on Emotions fidou The papers in this volume give the steps by which Dr. Crile established his Americ theory of shock. They show the phylogenetic origin of the emotions and the pathologic identity of traumatic and emotional shock, and point out most convincingly the clinical application of these premises and their broad, general significance in every phase of life. Octavo of 240 pages, illustrated. By Grorcr W. CRILE, M. D., Professor of Surgery, Western Re- serve University, Cleveland. oth, $3.00 net. 2 SAUNDERS’ BOOKS ON The New Keen’s Surgery _ Surgery: Its PRINcIPLES AND Practice. Written by 81 eminent specialists. Edited by W. W. Keen, M.D., LL.D., Hon. F.R.CS.; Ene. AnD Epin., Emeritus Professor of the Principles of Surgery and of Clinical Surgery at the Jefferson Medical College. Six octavos of 1050 pages each, containing 3100 original illustrations, 157 in colors, Per volume: Cloth, $7.00 net; Half Morocco, $8.00 net. VOLUME VI GIVES YOU THE NEWEST SURGERY ALL THE ADVANTAGES OF A REVISION AT ONE-FIFTH THE COST’ We have issued a Volume VI of ‘‘ Keen ’’—the volume of the newest surgery- In this way you get all the advantages of a complete and thorough revision at but one-fifth the cost. It makes Keen’s Surgery the best, the most up-to-date surgery on the market. In this sixth volume you get the newest surgery—both general and special— from the pens of those same international authorities who have made the success of Keen’s Surgery world-wide. Each man has searched for the new, the really useful, in his particular field, and he gives it to you here. Here you get the ' newest surgery, and fully illustrated. Then, further, you get a complete index to the entire six volumes, covering 125 pages, but so arranged that reference to it is extremely easy. If you want the newest surgery, you must turn to the new “Keen”? for it. Bryan’s Surgery Principles of Surgery. By W. A. Bryan, M. D., Professor of Sur- gery and Clinical Surgery at Vanderbilt University, Nashville. Octavo of 677 pages, with 224 original illustrations. Cloth, $4.00 net. ILLUSTRATED Dr. Bryan here gives you facts, accurately and concisely stated, without which no modern practitioner can do modern work. He discredits many fallacious ideas, giving you facts instead. ,, He shows you in a most practical way the rela- tions between surgical pathology and the resultant symptomatology, and points out the influence such information has on ¢veatment. Dr. A. Vander Veer, Albany Medical College “ Tt comes to us full of new ideas. So much that is clear and concise has been added that it is fascinating to study the work. It is bound to receive a hearty welcome.” SURGERY AND ANATOMY 3 Hornsby and Schmidt’s The Modern Hospital The Modern Hospital. Its Inspiration; Its Construction; Its Equipment; Its Mangement. By Jonn A. Hornssy, M.D., Secre- tary, Hospital Section, American Medical Association; and RicHARD E. Scumipt, Architect. Large octavo of 644 pages, with 207 illus- trations. Cloth, $7.00 net; Half Morocco, $8.50 net. HOSPITAL EFFICIENCY “« Hornsby and Schmidt ’’ tells you just exactly how to plan, construct, equip, and manage a hospital in all its departments, giving you every detail. It gives you exact data regarding heating, ventilating, plumbing, refrigerating, etc.—and the costs. It tells you how to equip a modern hospital with modern appliances. It tells you what you need in the operating room, the wards, the private rooms, the dining room, the kitchen—every division of hospital housekeeping. It gives you the duties of the directors, the superintendent, the various staffs, their relations to each other. It tells you all about nurses’ training-schools —their management, curriculum, rules, regulations, etc. It gives you hundreds of valuable points on the business management of hospitals—large and small. Howell Wright, Superintendent City Hospital, Cleveland “To me the book is invaluable. I have a copy on my desk and scarcely a day passes but what I consult it and find what I want.” Allen’s Local Anesthesia Local Anesthesia. By CarroLt W. A Len, M. D., Instructor in Clinical Surgery at Tulane University of Louisiana. Octavo of 608 pages, illustrated. Cloth, $6.00 net; Half Morocco, $7.50 net. JUST READY This is acomplete work on this subject. You get the history of local anesthesia, a chapter on nerves and sensation, giving particular attention to paz —what it is and its psychic control, Then comes a chapter on osmosis and diffusion. Each local anesthetic is taken up in detail, giving very special atten- tion to cocain and novocain, pointing out the action on the nervous system, the value of adrenalin, paralysis caused by cocain anesthesia, control of toxicity. You get Crile’s method of administering adrenalin and salt solution, the exact way to produce the intradermal wheal, to pinch the flesh for the insertion of the needle—all shown you step by step. You get-full discussions of paraneural, intraneural, and spinal analgesia, intravenous and intra-arterial anesthesia, and Hackenbuck’s regional anesthesia by circumferential injections. You get indica- tions, contraindications, an article on anoci-association, with Crile’s technic for producing anesthesia. Then the production of local anesthesia in the various regions is taken up in detail. Spinal analgesia and epidural injections are con- sidered in a monogragh of 45 pages. There isa large section on dental anesthesia. 4 SAUNDERS’ BOOKS ON | Cotton’s Dislocations and Joint Fractures Dislocations and Joint Fractures. By FrREepERIc Jay Corton, M.D, First Assistant Surgeon to the Boston City Hospital. Octavo of 654 pages, with 1201 original illustrations. Cloth, $6.00 net; Half Morocco, $7.50 net. TWO PRINTINGS IN EIGHT MONTHS Dr. Cotton's clinical and teaching experience in this field has especially fitted him to write a practical work on this subject. He has written a book clear and definite in style, systematic in presentation, and accurate in statement. The illustrations possess the feature of showing just those points the author wishes to emphasize. This is made possible because the author is himself the artist. Boston Medical and Surgical Journal ‘The work is delightful, spirited, scholarly, and original, and is not only a book of refer- ence, but a book for casual reading. It brings the subject up to date, a feat long neglected.” Murphy’s Famous Clinics Clinics of John B. Murphy, M .D., at Mercy Hospital, Chicago. Issued serially, one number every other month (six numbers a year). Each issue about 200 octavo pages, illustrated. Per year: $8.00; Cloth, $12.00. Sold only by the calendar year. DOWN.TO-THE-MINUTE SURGERY This is yust the work you have been waiting for—a permanent record of the teachings of this great surgeon. These are of students’ clinics, but delivered at Mercy Hospital, Chicago, for physicians only, They are postgraduate clinics. These Ciinicsare published just as delivered by Dr. Murphy, an expert stenogra- pher taking down everything Dr. Murphy says and does. In this way these Cuinics retain all that individual force and charm so characteristic of the clinical teaching of this distinguished surgeon. But the most vital point about ¢hese Cuinics is that they are absolutely fresh. They give youacontinuous postgraduate . course right in your own office with John B. Murphy as your teacher. They have been called ‘‘ The Practitioner's Text-book.”’ SURGERY AND ANATOMY 5 Crandon and Ehrenfried’s Surgical After-treatment Surgical After-treatment. A Manual of the Conduct of Surgical Convalescence. By L. R. G. Cranpon, M.D., Assistant in Surgery, and ALBERT EHRENFRIED, M. D., Assistant in Anatomy, Harvard Medi- cal School. Octavo of 831 pages, with 265 original illustrations. Cloth, $6.00 net ; Half Morocco, $7.50 net. THE NEW (2d) EDITION, PRACTICALLY REWRITTEN This work tells how best to manage all problems and emergencies of surgical convalescence from recovery-room to discharge. It gives all’ the details com- pletely, definitely, yet concisely, and does not refer the reader to some other work perhaps not then available. The post-operative conduct of all operations is given, arranged alphabetically by regions. A special feature is the elaborate chapter on Vaccine Therapy, Immunization by Inoculation and Specific Sera, by Dr. George P. Sanborn, a disciple of Sir A. E. Wright. The text is illustrated. The Therapeutic Gazette “The book is one which can be read with much profit by the active surgeon and will be generally commended by him.” Papers from the Mayo Clinic Collected Papers by the Staff of St. Mary’s Hospital, Mayo Clinic, By Wixt1am J. Mayo, M. D., CHartes H. Mayo, M. D.,and their Asso- CIATES at St. Mary’s Hospital, Rochester, Minn. Papers of 1905-1909, 1910, IQII, 1912, 1913, 1914. Each an octavo of about 800 pages, illustrated. Per volume: Cloth, $5.50 net. PAPERS OF 1914 JUST READY These volumes give you all the clinical teachings, all the important papers of W. J. and C. H. Mayo and their associates at St. Mary’s Hospital. They give you the advances in operative technic, in methods of diagnosis as developed at this great clinic. This new volume, although called the z9r4 volume, gives you many papers that did not appear until we// zwfo 1975, quite a few being scheduled for as late as May and June. You should add this volume to your Mayo files. Bulletin Medical and Chirurgical Faculty of Maryland “ Much of the work done at the Mayo Clinic and recorded in these papers has been epoch- making in character, * * * Represents a most substantial block of modern surgical progress.”" A Collection of Papers (published previous to 1909). By Wit1aM J. Mayo, M.D., and Cuartes H. Mayo, M.D. Two octavos of 525 pages each, illustrated. Per set: Cloth, $10.00 net. 6 SAUNDERS’ BOOKS ON Mumford’s Practice of Surgery The Practice of Surgery. By James G. Mumrorp, M. D., In- structor in Surgery, Harvard Medical School. Octavo of 1032 pages, with 682 illustrations. Cloth, $7.00 net; Half Morocco, $8.50 net. JUST OUT—NEW (2d) EDITION This, as its title implies, is a work on the chnical side of surgery—surgery as it is seen at the bedside, in the accident ward, and in the operating room, It ex- presses the matured outgrowth of twenty years of active hospital and private - surgical practice, together with the experience gained from clinical teaching, class- room discussions, and lectures. John B, Murphy, M.D., Professor of Surgery, Northwestern Medical School, Chicago, “ This work truly represents Dr. Mumford’s intellectual capacity and scope, and presents in a terse, forceful, yet pleasing manner, the live surgical topics of the day. It isin every par- ticular up to date, and shows that rare quality of accentuating the essential and omitting the unnecessary.”’ DaCosta’s Modern Surgery Modern Surgery—GENERAL AND OPERATIVE. By JOHN CHALMERS DaCosta, M. D., Samuel D. Gross Professor of Surgery, Jefferson Medical College, Philadelphia. Octavo of 1515 pages, with 1085 illus- trations. Cloth, $6.00 net; Half Morocco, $7.50 net. NEW (7th) EDITION A surgery, to be of the maximum value, must be up to date, must be com- plete, must have behind its statements the sure authority of experience, must be so arranged that it can be consulted quickly; in a word, it must be practical and dependable. Such a surgery is DaCosta’s. Always an excellent work, for this edition it has been very materially improved by the addition of new matter to the extent of over 250 pages and by a most thorough revision of the old matter, Many old cuts have been replaced by new ones, and nearly 150 additional illus- trations have been added. Rudolph Matas, M. D., Professor of Surgery, Tulane University of Louisiana. “This edition is destined to rank as high as its predecessors, which have placed the learned author in the fore of text-book writers. The more I scrutinize its pages the more I admire the marvelous capacity of the author to compress so much knowledge in'so small a space.” sORGERY AND ANATOMY 2 | Scudder’s Treatment of Fractures WITH NOTES ON DISLOCATIONS The Treatment of Fractures: with Notes on a few Common Dislocations. By Cartes L. Scupprr, M.D., Surgeon to the Massa- chusetts General Hospital, Boston. Octavo of 708 pages, with 994 original illustrations. Polished Buckram, $6.00 net; Half Morocco, $7.50 net. THE NEW (7th) EDITION, ENLARGED OVER 33,500 COPIES’ The fact that this work has attained a seventh edition indicates its practical value. In this edition Dr. Scudder has made numerous additions throughout the text, and has added many new illustrations, greatly enhancing the value of the work. In every way this new edition reflects the very latest advances in the treatment of fractures. J. F. Binnie, M.D., University of Kansas ‘‘Scudder’s Fractures is the most successful book on the subject that has ever been pub. lished. I keep it at hand regularly.” Scudder’s Tumors of the Jaws Tumors of the Jaws. By Cuaries L. Scupprr, M.D., Surgeon to the Massachusetts General Hospital, Boston. Octavo of 395 pages, with 353 illustrations, 6 in colors. Cloth, $6.00 net; Half Morocco, $7.50 net. WITH NEW ILLUSTRATIONS Dr. Scudder in this book tells you how to determine in each case the form of new growth present and then points out the best treatment. As the tendency of malignant disease of the jaws is to grow into the accessory sinuses and toward the base of the skull, an intimate knowledge of the anatomy of these sinuses is essential.. Dr. Scudder has included, therefore, sufficient anatomy and a number of illustrations of an anatomic nature. Whether general practitioner or surgeon, you need this new book because it gives you just the information you want. 8 SAUNDERS’ BOOKS ON - Sisson’s Anatomy of Domestic Animals Anatomy of the Domestic Animals. By Seprimus Sisson, S. B., V.S., Professor of Comparative Anatomy in Ohio State University. Octavo volume of 930 pages, with 725 illustrations, mostly original and many in colors. Cloth, $7.00 net; Half Morocco, $8.50 net. JUST OUT—NEW (2d) EDITION, RESET Dr. Sisson’s work has been entirely reset. More than 300 new and original illustrations have been introduced, the book now containing 72s illustrations, zoo of them in colors. This makes Dr. Sisson’s work an atlas of comparative anatomy as well as a descriptive text-book. The xomenclature throughout has been changed to conform to that adopted by the American Veterinary Medical Association. The work takes up the horse, the cow, the ox, the pig, the dog, the sheep—really a comparative anatomy of the domesticated animals. Boston Medical and Surgical Journal ‘It is not amiss to say that the work ranks with the best. A marked advance in English veterinary literature, upon which student and practitioner may well’ congratulate themselves and no medical school can afford to be without.” Gant on Constipation and Intestinal Obstruction Constipation and Intestinal Obstruction. By Samuet G. Gant, M.D., Professor of Diseases of the Rectum and Anus, New York’ Post-Graduate Medical School and Hospital. Octavo of 559 pages, with 250 original illustrations. Cloth, $6.00 net ; Half Morocco, $7.50 net. INCLUDING RECTUM AND ANUS In this work the consideration given to the medical treatment of constipation is unusually extensive, The practitioner will find of great assistance the chapter devoted to formulas. The descriptions of the operative procedures are concise, yet fully explicit. The Proctologist ‘‘Were the profession better posted on the contents of this book there would be less suffering from the ill effects of constipation. We congratulate the author on this most complete book.”’ SURGERY AND ANATOMY 9 Kelly G Noble’s Gynecology and Abdominal Surgery Gynecology and Abdominal Surgery. Edited by Howarp A. ‘Ketty, M.D., Professor of Gynecology in Johns Hopkins University; and Cuarres P. Nosie, M.D., formerly Clinical Professor of Gyne- cology in the Woman’s Medical College, Philadelphia. Two imperial octavo volumes of 950 pages each, containing 880 original illustrations, some in colors. Per volume: Cloth, $8.00 net; Half Morocco, $9.50 net. WITH 880 ILLUSTRATIONS—TRANSLATED INTO SPANISH This work possesses a number of valuable features not to be found in any other publication covering the same fields. It contains a chapter upon the bac- ~ teriology and one upon the pathology of gynecology, and a large chapter devoted entirely to medical gynecology, written especially for the physician engaged in general practice. Abdominal surgery proper, as distinct from gynecology, is fully treated, embracing operations upon the stomach, intestines, liver, bile-ducts, pancreas, spleen, kidneys, ureter, bladder, and peritoneum. American Journal of Medical Sciences “It is needless to say that the work has been thoroughly done; the names of the authors and editors would guarantee this, but much may be said in praise of the method of presentation, and attention may be called to the inclusion of matter not to be found elsewhere.” -Bickham’s Operative Surgery A Text-Book of Operative Surgery. By Warren Stone Bickuaw, M.D., of New York. Octavo of 1200 pages, with 854 original illustra- -~ tions. Cloth, $6.50 net; Half Morocco, $8.00 net. THE NEW (3d) EDITION This work completely covers the surgical anatomy and operative technic in- volved in the operations of general surgery. The practicability of the work is particularly emphasized in the 854 magnificent illustrations, Boston Medical and Surgical Journal “The book is a valuable contribution to the literature of operative surgery. It represents a vast amount of careful work and technical knowledge on the part of the author. For the sur- geon in active practice or the instructor of surgery it is an unusually good review of the subject.” Io SAUNDERS' BOOKS ON Eisendrath’s Surgical Diagnosis A Text-Book of Surgical Diagnosis. By DanreL N. EISENDRATH, M.D., Professor of Surgery in the College of Physicians and Surgeons, Chicago. Octavo of 885 pages, with 574 entirely new and original text-illustrations and some colored plates. Cloth, $6.50 net; Half Morocco, $8.00 net. THE NEW (2d) EDITION Of first importance in every surgical condition is a correct diagnosis, for upon this depends the treatment to be pursued ; and the two—diagnosis and treatment— constitute the most practical part of practical surgery. Dr. Eisendrath takes up each disease and injury amenable to surgical treatment, and sets forth the means of correct diagnosis in a systematic and comprehensive way. Definite directions as to methods of examination are presented clearly and concisely, providing for all contingencies that might arise in any given case. Each illustration indi- cates precisely how to diagnose the condition considered. Surgery, Gynecology, and Obstetrics ‘“The book is one which is well adapted’ to the uses of the practising surgeon who desires information concisely and accurately given. . . . Nothing of diagnostic importance is omitted, yet the author does not run into endless detail.” Fisendrath’s Clinical Anatomy A Text-Book of Clinical Anatomy. By-Daniet N. EIsENDRATH, A.B., M.D., Professor of Surgery in the College of Physicians and Surgeons, Chicago. Octavo of 535 pages, illustrated. Cloth, $5.00 net; Half Morocco, $6.50 net. THE NEW (2d) EDITION This new anatomy discusses the subject from the clinical standpoint. A por- tion of each chapter is devoted to the examination of the living through palpation and marking of surface outlines of landmarks, vessels, nerves, thoracic and abdominal viscera. The illustrations are from new and original drawings and photographs. This edition has been carefully revised. Medical Record, New York ‘“A special recommendation for the figures is that they are mostly original and were made for the purpose in view. The sections of joints and trunks are those of formalinized cadavers and are unimpeachable in accuracy.” SURGERY AND ANATOMY i Fenger Memorial Volumes Fenger Memorial Volumes. Edited by Lupvic Hextorn, M. D., Professor of Pathology, Rush Medical College, Chicago. Two octavos of 525 pages each, Per set : Cloth, $15.00 net ; Half Morocco, $18.00 net. LIMITED EDITION _ These handsome volumes consist of all the important papers written by the late Christian Fenger, for many years professor of surgery at Rush Medical College, Chicago. Not only the papers published in English are included, but also those which originally appeared in Danish, German, and French. The name of Christian Fenger typifies thoroughness, extreme care, deep re- search, and sound judgment. Hiscontributions to the advancement of the world’s surgical knowledge are indeed as valuable and interesting reading to-day as at the time of their original publication. They are pregnant with suggestions. Fenger’s literary prolificacy may be judged from this memorial volume—over 1000 pages. Sobotta and McMurrich’s Human Anatomy Atlas and Text-Book of Human Anatomy. In Three Volumes. By J. Sosorra, M.D., of Wiirzburg. Edited, with additions, by J. PLavrair McMorricy, A. M., Px. D., Professor of Anatomy, University of Toronto, Canada. Three large quartos, each containing about 250 pages of text and over 300 illustrations, mostly in colors. Per volume: Cloth, $6.00 net; Half Morocco, $7.50 net. Edward Martin, M.D., Professor of Clinical Surgery, University of Pennsylvania “This isa piece of bookmaking which is truly admirable, with plates and text so well chosen and so clear that the work is most useful to the practising surgeon.” | Campbell’s Surgical Anatomy A Text-Book of Surgical Anatomy. By WILLIAM FRaAncIs Camp- BELL, M. D., Professor of Anatomy, Long Island College Hospital. Octavo of 675 pages, with 319 original illustrations. Cloth, $5.00 net. SECOND EDITION This is in the fullest sense an applied anatomy—an anatomy that will be of inestimable value to the surgeon because only those facts are discussed and only those structures and regions emphasized that have a peculiar interest to him. Boston Medical and Surgical Journal _ “The author has an excellent command of his subject, and treats it with the freedom and the conviction of the experienced anatomist. He is also an admirable clinician. 12 SAUNDERS’ BOOKS ON Moynihan’s Abdominal Operations Abdominal Operations. By Sir BERKELEY Movyninan, M. S. (Lonpon), F.R.C.5S., of Leeds, England. Two octavos, totaling nearly 1000 pages, with 385 illustrations. Per set: Cloth, $10.00 net; Half Morocco, $13.00 net. JUST OUT—NEW (3d) EDITION, ENLARGED This new ( 7¢) edition was so thoroughly revised that the work had to be reset from cover to cover. Over 150 pages of new matter and some 85 new illustrations were added, making 385 illustrations, 5 of them in colors—really an atlas of abdominal surgery, This work is a personal record of Moynihan’s operative work. You get his own successful methods of diagnosis, You get his own technic, in every case fully illustrated with handsome pic- tures. You get the bacteriology of the stomach and intestines, sterilization and preparation of patient and operator. You get complications, sequels, and after-care. Then the various operations are detailed with forceful clearness, discussing first gastric operations, following with intestinal operations, operations upon the liver, the pancreas, the spleen. Two new chapters added in this edition are excision of gastric ulcer and complete gastrectomy, giving the latest developments in these operative measures, , Moynihan’s Duodenal Ulcer Edition Duodenal Ulcer. By SiR BERKELEY MoyNnIHAN, M.S. (Lonpon), F.R.C.S., Leeds, England. Octavo of 486 pages, illustrated. Cloth, $5.00 net; Half Morocco, $6.50 net. For the fractitioner, who first meets with these cases, Mr. Moynihan fixes the diagnosis with precision, so that the case, if desired, may be referred in the early stage to the sur- geon. The surgeon finds here the newest and best technic as used by one of the leaders in this field. “Easily the best work on the subject; coming, as it does, from the pen of one of the mas- ters of surgery of the upper abdomen, it may be accepted as authoritative." —Zondon Lancet. Moynihan on Gall-stones Eainon Gall-stones and Their Surgical Treatment. By Sir BERKELEY Moyni- HAN, M. S. (Lonpon), F. R. C. S., Leeds, England. Octavo of 458 pages, illustrated. Cloth, $5.00 net; Half Morocco, $6.50 net. This work gives special attention to the early symptoms in cholelithiasis, enabling you to diagnose the case in the early stages. “We can heartily recommend this work as most satisfactory and of the greatest prac- tical value."—American Journal of the Medical Sciences. SURGERY AND ANATOMY 13 Schultze and Stewart’s Topographic Anatomy Atlas and Text-Book of Topographic and Applied Anatomy. By Prop. Dr. O. SCHULTZE, of Wiirzburg. Edited, with additions, by GzorcE D. STEWART, M.D., Professor of Anatomy and Clinical Surgery, University and Bellevue Hospital Medical College, N. Y. Large quarto of 189 pages, with 25 colored figures on 22 colored lithographic plates, and 89 text-cuts, 60 in colors. Cloth, $5,50 net. Griffith’s Hand-Book of Surgery A Manual of Surgery. By FREDERIC R. GRIFFITH, M. D., Surgeon to the Bellevue Dispensary, New York City. 12mo of 579 pages, with 417 illus- trations. Flexible leather, $2.00 net. Keen’s Addresses and Other Papers Addresses and Other Papers. Delivered by WILLIAM W. KEEN, M. b., LL.D., F. R. C.S. (Hon.), Professor of the Principles of Surgery and of Clin- ical Surgery, Jefferson Medical College, Philadelphia. Octavo volume of 441 pages, illustrated. , Cloth, $3.75 net. Keen on the Surgery of Typhoid The Surgical Complications and Sequels of Typhoid Fever. By Wm. W. KEEN, M.D., LL.D., F.R.C.S. (Hon.), Professor of the Principles of Surgery and of Clinical Surgery, Jefferson Medical College, Philadelphia, etc, Octavo volume of 386 pages, illustrated. Cloth, $3.00 net. Dannreuther’s Minor and Emergency Surgery Minor and Emergency Surgery. By WALTER T. DANNREUTHER, M. D., Sur- geon to St. Elizabeth’s Hospital and to St. Bartholomew's Clinic, New York City. 12mo of 225 pages, illustrated. Cloth, $1.25 net. Bier’s Hyperemia Second Edition Bier’s Hyperemic Treatment in Surgery, Medicine, and the Specialties : A Manual of its Practical Application. By Witty Meyer, M. D., Professor of Surgery at the New York Post-Graduate Medical School and Hospital ; and Pror. Dr. VIcTOR SCHMIEDEN, Assistant to Prof. Bier, University of Berlin, Germany. Octavo of 280 pages, with original illustrations. Cloth, $3.00 net. “*« We commend this work to all those who are interested inthetreatment of infections, either acute or chonic, for it isthe only authoritative treatise we have in the English language.””—New York State Journal of Medicine. Morris’ Dawn of the Fourth Era in Surgery Dawn of the Fourth Era in Surgery and Other Articles. By RoBeRT T. Morris, M. D., Professor of Surgery, New York Post-Graduate Medical School and Hospital. 12mo of 145 pages, illustrated. $1.25 net. 14 SAUNDERS* BOOKS ON Haynes’ Anatomy A Manual of Anatomy. By Irvine S. Haynss, M.D., Professor of Prace tical Anatomy, Cornell University Medical College. Octavo, 680 pages, with 42 diagrams and 134 full-page half-tones. Cloth, $2.50 net. American Pocket Dictionary New (8th) Edition The American Pocket Medical Dictionary. Edited by W. A. NEwMAN DorLAND, A. M., M. D., Editor ‘‘ American Illustrated Medical Dictionary.”’ 677 pages. Full leather, limp, with gold edges, $1.00 net; with patent thumb index, $1.25 net. Fowler’s Surgery In wo Volumes A Treatise on Surgery. By Grorce R. Fow er, M. D., Emeritus Pro- fessor of Surgery, New York Polyclinic. Two imperial octavos of 725 pages each, with 888 original text-illustrations and 4 colored plates. Per set: Cloth, $15.00 net ; Half Morocco, $18.00 net. International Text-Book of Surgery Second Edition The International Text-Book of Surgery. In two volumes. By Ameri- can and British authors. Edited by J. CoLLIns WarREN, M. D., LL. D., F. R. C. S. (Hon.), Professor of Surgery, Harvard Medical School; and A. PEARCE GOULD, M. S., F. R. C.S., of London, England. Vol. I.: General and Operative Surgery. Royal octavo, 975 pages, 461 illustrations, 9 full- page colored plates. Vol. II. : Special or Regional Surgery. Royal octavo, 1122 pages, 499 illustrations, and 8 full-page colored plates. Per volume: Cloth, $5.00 net; Half Morocco, $6.50 net. American Text-Book of Surgery Fourth Edition American Text-Book of Surgery. Edited by W. W. Keen, M. D., LL. D., Hon. F. R. C. S., Enc. and Epin., and J. WILLIAM WHITE, M. D., Pu. D. Octavo, 1363 pages, 551 text-cuts and 39 colored and half-tone plates. Cloth, $7.00 net; Half Morocco, $8.50 net. Robson and Cammidge on the Pancreas The Pancreas: Its Surgery and Pathology. By A. W. Mayo Rosson, F. R. C. S., of London, England; and P. J. Cammince, F. R. C. S., of London, England. Octavo of 546 pages, illustrated. Cloth, $5.00 net; Half Morocco, $6.50 net. SURGERY AND ANATOMY, 15 American Illustrated Dictionary The New (7th) Edition The American Illustrated Medical Dictionary. With tables of Arteries, Muscles, Nerves, Veins, etc.; of Bacilli, Bacteria, etc. ; Eponymic Tables of Diseases, Operations, Stains, Tests, etc. By W. A. Newman Dorianp, M.D. Large octavo, 1107 pages. Flexible leather, $4.50 net; with thumb index, $5.00 net. Howard A. Kelly, M.D., Professor of Gynecology, Johns Hopkins University, Baltimore. “Dr. Dorland's dictionary is admirable. It is so well gotten up and of such con- venient size. No errors have been found in my use of it.” Golebiewski and Bailey’s Accident Diseases Atlas and Epitome of Diseases Caused by Accidents. By Dr. Ep. Go.esiewskI, of Berlin. Edited, with additions, by Pearce BaILey, M.D. Consulting Neurologist to St. Luke’s Hospital, New York City. With 71 colored figures on 40 plates, 143 text-cuts, and 549 pages of text. Cloth, $4.00 net. J Saunders’ Hand-Atlas Series. Helferich and Bloodgood on Fractures Atlas and Epitome of Traumatic Fractures and Dislocations By Pror. Dr. H. HELFericu, of Greifswald, Prussia. Edited, with ad- ditions, by JosEpH C. BLoopcoop, M. D., Associate in Surgery, Johns Hopkins University, Baltimore. 216 colored figures on 64 lithographic plates, 190 text-cuts, and 353 pages of text. Cloth, $3.00 net. Juz Saun- ders’ Atlas Series. Sultan and Coley on Abdominal Hernias Atlas and Epitome of Abdominal Hernias. By Pr. Dr. G. SuL-: Tan, of Gottingen. Edited, with additions, by Wm. B. Corry, M. D., Clinical Lecturer and Instructor in Surgery, Columbia University, New York. 119 illustrations, 36 in colors, and 277 pages of text. Cloth, $3.00 net. Jn Saunders’ Hand-Atlas Series. Warren’s Surgical Pathology . Se Surgical Pathology and Therapeutics. By J. CoLtins WARREN, M.D., LL.D., F.R.C.S. (Hon.), Professor of Surgery, Harvard Medical School. Octavo, 873 pages; 136 illustrations, 33 in colors. Cloth, $5.00 net; Half Morocco, $6.50 net. : Zuckerkandl and DaCosta’s Surgery a Atlas and Epitome of Operative Surgery. By Dr. O. ZuckER- KANDL, of Vienna. Edited, with additions, by J. CHarmers DaCosta, M.D., Samuel D. Gross Professor of Surgery, Jefferson Medical Col- lege, Philadelphia. 40 colored plates, 278 text-cuts, and 410 pages of text. Cloth, $3.50 net. J Saunders’ Atlas Series. 16 SURGERY AND ANATOMY Moore’s Orthopedic Surgery A Manual of Orthopedic Surgery. By James E. Moore, M.D., Professor of Clinical Surgery, University of Minnesota, College of Medicine and Surgery. Octavo of 356 pages, handsomely illustrated. Cloth, $2.50 net. “The book is eminently practical. It is a sate guide in the understanding and treatment of orthopedic cases. Should be owned by every surgeon and practitioner.”—Axnals of Surgery. Fowler’s Operating Room New (3d) Edition, Reset The Operating Room and the Patient. By RussELL S. Fow er, M.D., Surgeon to the German Hospital, Brooklyn, New York. Octavo of 611 pages, illustrated. Cloth, $3.50 net, Dr. Fowler has written his book for surgeons, nurses assisting at an operation, internes, and all others whose duties bring them into the operating room. It contains explicit directions for the preparation of material, instruments needed, position of patient, etc., all beautifully illustrated. Nancrede’s Principles of Surgery __ New (2d) Edition Lectures on the Principles of Surgery. By Cuas. B. NANCREDE, M.D., LL.D., Professor of Surgery and of Clinical Surgery, University of Michigan, Ann Arbor. Octavo, 407 pages, illustrated. ~ Cloth, $2.56 net. “We can strongly recommend this book to all students and those who would see something of the scientific foundation upon which the art of surgery is built.”"—Quarterly Medical Journal, Shefield, England. Nancrede’s Essentials of Anatomy. g.,ent, Eaition Essentials of Anatomy, including the Anatomy of the Viscera. By CHas. ' B. NANCREDE, M.D., Professor of Surgery and of Clinical Surgery, University of Michigan, Ann Arbor. Crown octavo, 388 pages; 180 cuts: With an Appendix containing over 60 illustrations of the osteology of the body. Based on Gray's Anatomy. Cloth, $1.00 net. J Saunders’ Question Compends. “ The questions have been wisely selected, and the answers accurately and concisely given.”— University Medical Magazine. Martin’s Essentials of Surgery. S¢venth Edition Essentials of Surgery. Containing also Venereal Diseases, Surgical Land- marks, Minor and Operative Surgery, and a complete description, with illus- trations, of the Handkerchief and Roller Bandages. By EDWARD MARTIN, A.M., M.D., Professor of Clinical Surgery, University of Pennsylvania, etc. Crown octavo, 338 pages, illustrated. With an Appendix on Antiseptic Sur. gery, etc. : Cloth, $1.00 net. /# Saunders’ Question Compends. “Written to assist the student, it will be of undoubted value to the practitioner, containing as it does the essence of surgical work.”—Boston Medical and Surgical Journal, Metheny’s Dissection Methods Just Issued Dissection Methods and Guides. By Davip GrecG METHENY, M. D., L.R.C.P., L. R. C. 5. (Epin.), L. F. P. S. (Guas.), Associate in Anatomy, Jefferson Medical College, Philadelphia. Octavo of 131 pages, illustrated. Cloth, $1.25 net. This work bridges the gap heretofore existing between the descriptive text-book and the dissecting table. In order that it may be used in connection with any text-book or atlas both the old and the new anatomic names are given, Everything the student could be ex- pected to do is carefully explained in detail. ,