THE 
 
 Chemistry of the C^^^ J^ernel 
 
 PRESENTED TO THE 
 
 FACULTY OF CORNELL UNIVERSITY, 
 
 ITHACA, NEW YORK. U. S. A., 
 
 Thesis for the Degree of Doctor of Philosophy, 
 
 JUNE, t898, 
 
 CYRIL GEORGE HOPKINS, M. S. 
 
 4297:^0 
 
 PUBLISHED 
 
 BY THE UNIVERSITY OF ILLINOIS 
 
 AGRICULTURAL EXPERIMENT STATION, 
 
 AS BULLETIN No. 53 
 
UNIVERSITY OF ILLINOIS 
 
 Ap^ricultural Experiment Station, 
 
 URBANA. JULY, 1898. 
 
 BULLETIN NO. ^3. 
 
 THE CHEMISTRY OE THE CORN KERNEL'. 
 
 By C. G. Hopkins. 
 
 Introduction. — The object of these siudies on the chemisty of corn'- 
 is to trace its historical development, to bring together from many 
 sources the existing knowledge of the subject, and, if possible, to add 
 thereto in certain lines where our present knowledge seems most defi- 
 cient, omitting fields wherein other investigators are known to be 
 engaged. With the single purpose of being faithful to the history of 
 the subject, I have felt equally free to point out misconceptions, erron- 
 eous conclusions, or real advances of past investigations. The subject 
 has naturally divided itself into two parts: 
 
 1st. The proximate composition of corn, which has a very prac- 
 tical significance as indicating its value as food for man and domestic 
 animals and as raw material for various manufacturing purposes. 
 
 2nd. The complete and exact composition of the different groups 
 of substances found by proximate analysis, a matter of more purely 
 scientific interest, though not without phases of economic importance. 
 
 Acknowledgments. — I acknowledge with pleasure and gratitude 
 my indebtedness to the Department of Chemistry of Cornell University for 
 the opportunities and privileges which have been freely accorded to me. 
 I am especially grateful to Professor G. C. Caldwell, under whose direc- 
 tion these studies have been carried on, and who has been to me a con- 
 stant source of counsel and encourasfement. 
 
 1 Presented to the Faculty of Cornell University as a thesis for the degree of 
 Doctor of Philosophy, June, 189S. 
 
 -Indian corn, maize; Ger. Iffilschkoru, Mm's; Fr, mens: Sp. tnai:: from Hay- 
 tian ma/ii's. (Zea Mays L.) 
 
130 BULLETIN NO. 53. \^J>'hy 
 
 I am also indebted to the University of Illinois Agricultural Experi- 
 ment Station for the privilege of selecting samples from corn which had 
 been carefully grown under known conditions upon the Station plots, 
 and for some experimental data. 
 
 PART I.— THE PROXIMATE COMPOSITION OF CORN. 
 
 HISTORICAL. 
 
 The earliest record known to the writer of work on the proximate 
 composition of corn was published' in 1821; and, because of the interest 
 and importance which attach to it, the article is here quoted in full: 
 
 " Analysis of Indian Corn. — Indian corn, either alone or mixed with the flour 
 of wheat or of rye, constitutes a considerable article in the food of the inhabitants of 
 the United States. In consequence of the importance which thus belonged to it. Dr. 
 John Gorham of Harvard University, Cambridge, U. S., was induced to examine it 
 chemically, with great attention. His experiments were made upon two varieties of 
 maize, that producing small, yellow grain, and the large, flat and white kind, com- 
 monly known by the name of Virginia corn; but the results were so similar, that only 
 those belonging to the former kind have been given. One hundred grains [weight] 
 powdered, when macerated and triturated with great precaution in water, gave a clear 
 filtered solution, which, on evaporation, afforded four grains of greyish semi-trans- 
 parent substance, disposed in laminae. Of this, when acted upon by alcohol, i 75 
 grains were insoluble, and resembled gum; the 2.25 grains that were soluble, were 
 separated from the alcohol by evaporation, and dissolved in water, then being acted 
 on by acetate of lead and sulphuretted hydrogen, .8 of a grain of extractive matter 
 was obtained, and 1.45 grains of a saccharine matter remained. 
 
 Another portion of the mixed gummy and saccharine matter was obtained; a 
 drop of sulphuric acid was added to a part of it, and liberated acetic acid, and quick- 
 lime being added to another part, a small quantity of ammonia was liberated. Hence 
 it appears to contain acetate of ammonia. It also afforded a portion of phosphate of 
 lime 
 
 The portion unacted on by water, and left on the filter, was digested for twenty- 
 four hours in alcohol, and the clear solution evaporated; a yellow substance was then 
 obtained, resembling bees-wax in appearance. It was soft, ductile, tenacious, elastic, 
 insipid, nearly inodorous, and heavier than water. When heated, it swelled, became 
 brown, exhaled the odor of burning bread, melted with the smell of animal matter, 
 and left a voluminous charcoal. It burnt in the flame of a lamp, but not rapidly. 
 When distilled, no ammonia seemed formed. It was insoluble in water, but soluble 
 in alcohol, oil of turpentine, and sulphuric ether, and sparingly in mineral acids and 
 caustic alkalies. It was insoluble in fixed oils, but mixed with resin. The quantity 
 obtained from 100 grains was three grains. 
 
 This substance appears to differ from all known vegetable bodies, and has been 
 called zeine by Dr. Gorham. It resembles gluten in some circumstances, but differs 
 from it in containing no azote, in its great solubility in alcohol, and in its perma- 
 nency, not undergoing any obvious change in six weeks. On the other hand, it is 
 analogous to the resins in its solubility in alcohol, essential oils, alkalies, and partial 
 solubilities in acids. It is inflammable, and probably composed of oxygen, hydrogen, 
 and carbon. It may easily be obtained by digesting a few ounces of the meal from 
 
 ' (London) Quarterly Journal of Science, Literature, and the Arts (1821) 11, 
 206, This Journal was published from 1817 to 1828 only. 
 
1898.] CHEMISTRY Ob THE CORN KERNEL. 131 
 
 the yellow corn in a flask with warm alcohol, allowing it to rest for some hours, then 
 filtering and evaporating. 
 
 After the action of alcohol on the 100 grains, it was boiled in successive portions 
 of water, a large quantity of starch was thus dissolved, leaving 14.25 grains of a sub- 
 stance, which, when boiled with weak sulphuric acid, was reduced to 3.75 grains. 
 The acid solution, when concentrated, deposited 2.25 grains of what was considered 
 albumen, and it appeared that about 8 grains of starch had also been taken up by the 
 acid. The 3.75 grains of solid matter were then heated with potassa, and reduced to 
 3 grains of ligneous matter and cuticle containing a little phosphate of lime; the 
 portion dissolved appeared to be albumen According to this analysis the constit- 
 uents of yellow Indian corn, in the common and the dry state, will be as follows; 
 
 Common state. Dry state. 
 
 Water g . 00 
 
 Starch 77.00 84.599 
 
 Zeine 3.00 3.296 
 
 Albumen 2.50 2.747 
 
 Gummy matter 1.75 1.922 
 
 Saccharine matter 1.45 i-593 
 
 Extractic matter 80 . 879 
 
 Cuticle and ligneous fibre 3 . 00 3 . 296 
 
 Phos. Carb. Sul. of lime, and loss i .50 i .648 
 
 100. 99.980 
 
 The powder of the corn is hygrometric, and the quantity of water in it varies 
 with the state of the atmosphere. Sometimes it would lose 12 per cent, on drying, at 
 other times not more than half that quantity. 
 
 In some experiments on the coloring matter of the different colored varieties of 
 Indian corn, it was found to be soluble in both water and alcohol, and to become 
 green by alkalies, and red by acids. 
 
 A spiritous liquor may be obtained from Indian corn, in consequence of the 
 changes which take place in its saccharine matter." 
 
 Although the analysis does not approach exactness except as to the 
 mineral matter, it possesses some features of peculiar interest, among 
 which may be mentioned the date at which it was made, and the dis- 
 covery and isolation of the proteid body peculiar to the corn kernel, 
 namely, zei'n, obtained by extracting with alcohol the residue of pow- 
 dered corn insoluble in water, and evaporating the alcoholic extract to 
 dryness. 
 
 In 1823 the Italian chemist Bizio, reported' the following analysis: 
 
 Salts, acids, etc 07 
 
 Zein 5.76 
 
 Zymom. . . 95 
 
 Sugar go 
 
 Gum 2 . 29 
 
 Hordein 7-7i 
 
 Extractive matter i .09 
 
 Oil 32 
 
 Starch 80 . 91 
 
 * Journal [Schweigger] fiir Chemie und Physik (1S23) 37, 377. 
 
132 
 
 BULLETIN NO. 53. [.J"h'y 
 
 Bizio found corn to contain oil, which had not been discovered 
 byGorham. The substance, hordein, was so called by Bizio because 
 of its similarity to the substance which had been obtained from 
 barley by Proust' and so named by him; which, however, was after- 
 ward shown by Guibourt'^ to be merely a mixture of hulls and cellular 
 tissue; and the hordein as found by Bizio was doubtless a mixture of 
 these fibrous substances with considerable amounts of adhering starch 
 and protein. 
 
 Probably the first work from the record of which the total amount 
 of nitrogenous matter can be very approximately calculated was that 
 of Bousingault, published'' in 1836 upon the total nitrogen content of 
 corn. By combustion with copper oxid .617 grammes of corn (con- 
 taining 18 per cent, of water) were found to yield 10.3 cubic centi- 
 meters of nitrogen gas measured at 9 degrees and 738 millimeters. By 
 computation I find this to be ecjuivalent to 2.39 per cent, of nitrogen in 
 the dry matter, and by using the factor 6.25, this gives 14.9 per cent, of 
 protein. 
 
 In i846Horsford reported* a complete ultimate organic analysis of 
 corn and then by an ingenious use of the formula which had been 
 worked' out for the average composition of several proteid bodies, as egg- 
 albumen, gluten {Kleber) of wheat, rye, etc., he calculated the ultimate 
 composition not only of the nitrogenous matter, but also of the nitro- 
 gen-free organic matter. Using the factor 6.375 ^^^' converting nitrogen 
 into protein, and having determined the percentage of mineral matter 
 he gives corn the following composition: 
 
 Carbon : 8.07 
 
 Hydrogen i . 00 
 
 Nitrogenous matter 14.66 Nitrogen 2.30 
 
 Sulfur .16 
 
 Oxygen 3.13 
 
 Carbon 37.38 
 
 Non-nitrogenous organic matter. 84. 52 Hydrogen 5.61 
 
 O.xygen 41.53 
 
 Mineral matter 1.92 1.92 
 
 »Annales de Chimie at de Physique (1817), [il 5, 337. 
 
 '■'Jahresbericht [Berzelius] Tiber die Fortschritte der physischen Wissenschaften 
 .(1831) 10, 202. 
 
 ■•* Annales de Chimie et de Physique (1836) [2] 63, 239. 
 
 'Annalen der Chemie und Pharmacie (1846) 58, 182. 
 
 •"■Scherer, ibid. (1S41) 40, i ; Jones, ibid. (1S41) 40, 65; Heldt, ibid. (1S43) 45, 19S. 
 
1898.] CHEMISTRY OF THE CORN KERNEL. I33,. 
 
 A very extended article by J. H. Salisbury on the general subject 
 of corn was published' in 1848. It included a report of considerable 
 chemical work, done by such imperfect methods as nearly to deprive it 
 of permanent value, as will appear from the following analysis of two 
 samples of corn kernels : 
 
 I. 2. 
 
 Albumen 9.29 4.64 
 
 Zein 6.73 3.98 
 
 Casein i . 44 .09 
 
 Dextrine or gum 5-94 3-53 
 
 Fiber 12.09 .96 
 
 Matter separated from fiber by weak potash solution, 7.80 6.48 
 
 Sugar and extract 13.27 14-42 
 
 Starch 38.28 60.92 
 
 Oil 5.18 4.98 
 
 The methods employed by Salisbury were in the main similar to 
 those of the earlier investigators and are briefly indicated as follows : 
 
 The powdered corn was washed with water which was decanted. 
 The residue extracted with alcohol and dilute potash water gave the 
 fiber. The matter held in suspension in the water was collected, washed 
 with alcohol and noted as starch, the residue from the evaporation of 
 the alcohol became a portion of the "sugar and extract." The turbid 
 water from the starch determination was heated and the coagulated 
 matter called albumen. In one portion of the filtrate the "casein" was 
 precipitated by acetic acid, and the "dextrine or gum" by alcohol after 
 partial evaporation. In a second portion the "casein" and "dextrine 
 or gum" were together removed by alcohol and another portion of 
 "sugar and extract" obtained by evaporating the filtrate to dryness. 
 
 The zein and oil were extracted from the corn by alcohol and 
 separated by ether after evaporation of the alcohol. 
 
 Following Salisbury's work proximate analyses were reported by 
 Poison'-, Poggiale', Stepf^ Payen\ and also by the renowned and but re- 
 cently deceased R. Fresenius'. 
 
 'Transactions of the New York State Agricultural Society (1S4S) 8, 67S; Ameri- 
 can Journal of Science and Arts (1849) [2] 8, 307. 
 
 -'Chimic. Gazette (1S55) 211 ; Journal fiir praktische Chemie (1855) 66, 320. 
 
 ^Jahresbericht [Leibig und Kopp] iiber die Fortschritte der Chemie (1856) 809. 
 
 ^Journal fiir praktische Chemie (1859) 76, 88, 
 
 ^Landwirtschaftliche Versuchs-Stationen (1859) 1, 179; Jahresbericht [Hofi- 
 maan] uber die Fortschritte auf dem Gesammtgebiete der Agricultur-Chemie (li^sg) 
 2, 76. 
 
134 BULLETIN NO. 53. [,/"h'> 
 
 Tlie following will serve as illustrations of the results : 
 
 Poison. Poggiale. Fresenius. 
 
 Water 11. 8 dry 13.5 dry 13 •4'^ dry 
 
 Ash 1.8 2.04 1.4 1.62 1. 58 1.83 
 
 Protein 8.9 10.09 9-9 ii-44 10.04 11.60 
 
 Oil 4.4 4.99 6.7 7.75 5. II 5.90 
 
 Fiber 15.9 18.03 4-o''' 4.62 1.58 1.83 
 
 Sugar a.g"- 3.29 2.33=* 2.69 
 
 Starch 54.3 61.56 64.5 74.57 65.90 76.15 
 
 In 1069, Atwater reported' the following results from a study'" of the 
 proximate composition of corn : 
 
 Early Dutton. Common yellow. King Philip. 
 
 Ash 1.66 1.46 1.77 
 
 Protein 10.46 10.86 13.16 
 
 Fat , 6.16 4.94 4.93 
 
 Fiber 2.74 2.68 2.45 
 
 Sugar 3.26 5.34 3-38 
 
 Gum 4.59 2.64 5.32 
 
 Starch 71.13 72.08 68.99 
 
 The protein was estimated by multiplying the total nitrogen by the 
 factor 6.25, a method which had come into general use, and which has 
 already been referred to under Horsford's work. Sugar was estimated 
 by Fehling's method from the aqueous extract, and the gum is the 
 difference between the sugar and the dried aqueous extract. The oil is 
 the ether extract. Fiber was determined by extracting with dilute acid 
 and alkali, essentially the method employed by Gorham nearly eighty 
 years ago, and in general use among agricultural chemists of to-day, 
 having been known under various names, as Peligot's'", Henneberg's, or 
 the Weende' method, the last being common at the present time. Starch 
 •was estimated by difference. 
 
 Closely following Atwater's work numerous analyses were reported 
 by European chemists. In the group of carbohydrates only the fiber 
 was determined, the remainder being estimated by difference and re- 
 ported under the negative and indefinite heading ''nitrogen-free extract" 
 for which I have recently proposed** to substitute the more definite and 
 logical term cariwhydrate extract. 
 
 *and gum. 
 
 ■^ and loss. 
 
 ^dextrine. 
 
 •W. O. Atwater — The proximate composition of several varieties of American 
 maize — Thesis for the degree of Doctor of Philosophy, Yale College (1869) ; Ameri- 
 can Journal of Science and Arts (1869) [2] 48, 352. 
 
 ''The analysis of a sample of sweet corn also reported is omitted. 
 
 ^Journal fiir praktische Chemie(i85o) 50, 261, 
 
 ^Landwirtschaftliche Versuchs-Stationen (1864) 6, 497. 
 
 "University of Illinois Agr. Exp. Station Bulletin (1896) 43. 
 
1898.] CHEMISTRY OF THE CORN KERNEL. I35 
 
 The following table gives a number of the results obtained, all 
 being reduced to the basis of dry matter : 
 
 Carbohydrate 
 
 Analyst'. Ash. Protein. Fat. Fiber. extract. 
 
 Dietrich 3.19 13. 88 5.59 2.86 74.48 
 
 Nessler 4.53 8.81 5.87 6.24 74-55 
 
 Nessler 3.20 6.41 6.17 6.54 77.68 
 
 Nessler 3.98 10.01 6.25 5-35 74-41 
 
 Kreuzhage 1.70 13-03 4-79 r-74 7^-74 
 
 Honig und Brimmer 1.50 9.00 4.16 1.58 83.76 
 
 Honig and Brimmer 1.42 10.35 4-36 i-55 82.32 
 
 In 1883 Richardson' made a compilation of analyses of corn grown 
 in various parts of the United States during the years 1877 to 1882. 
 The following table shows the number of samples analyzed and the aver- 
 ages of the analyses from each state represented. All dry matter other 
 than ash, protein, and oil I have grouped under the general term 
 i-arbohydrates. This is done for several reasons, i. We are consider- 
 ing not complete but proximate analysis. 2. Ash, protein, fat, and 
 carbohydrates constitute distinctly different groups with well known in- 
 dividual properties or characteristics as to use, value, etc. 3. The 
 amount of fiber in corn is too small to warrant its determination ordi- 
 narily, even if it were known that its value differs slightly from that of 
 other carbonydrates, the pentosans, for example. 4. The limit of error 
 in fiber determination is wide and not only appears in the fiber itself 
 but also in the carbohydrate extract (so called nitrogen-free extract.) 
 5. These data become more readily comparable with my own analyses 
 ■which are herein reported without fiber determinations. 
 
 Samples. Ash. Protein. Fat. Carbohydrates. 
 
 New Hampshire 11 1.76 12.98 6.10 79-i6 
 
 Vermont i 1.59 11. 10 6.16 81.15 
 
 Connecticut 13 1.73 ii-75 5-27 81.25 
 
 Pennsylvania 5 1.55 9-65 5.67 83.13 
 
 North Carolina 2 1.50 12.03 5-43 81.04 
 
 Kentucky i 1.62 10.62 5.77 Si. 99 
 
 Tennessee i 1.33 10.05 5.51 83.11 
 
 Indiana i 1.44 11. 84 5-49 81.23 
 
 Michigan 12 i .67 12.83 5-7° 79 80 
 
 Missouri 26 1.83 11.48 5.75 So. 94 
 
 Kansas 5 1.69 ii-53 5-53 81.25 
 
 Colorado i 1.68 10.95 6.32 81.05 
 
 Texas 20 i-59 11. 61 6.09 80.71 
 
 Oregon i 1.61 8.68 7. So 81.91 
 
 Washington i 1.67 9.36 6.39 82.58 
 
 Mexico 3 1.75 11-44 6.06 80.75 
 
 General average 1.69 11-63 5-78 80.90 
 
 ijahresbericht [Hoffmann] iiber die Agricultur-Chemie (1S72) 15, 10; (1876) 
 19. 7. 
 
 ^U. S. Dept. of Agr., Division of Chemistry Bulletin (iSS^) 1. 
 
136 BULLETIN NO. 53. [/^/^. 
 
 The following are some of the conclusions which Richardson draws 
 from his data : 
 
 "There is apparently the same average amount of ash, oil, and albuminoids 
 [protein] in a corn wherever it grows, with the exception of the Pacific Slope, where, 
 as with wheat, there seems to be no facility for obtaining or assimilating nitrogen. 
 
 "Corn is, then, an entirely different grain from wheat. It maintains about the 
 same percentage of albuminoids under all circumstances, and is not affected by its 
 surroundings in this respect. 
 
 "Only two analyses have been made from the Pacific Slope and more are 
 needed for confirmation, but as the two analyses, like those of the wheats grown 
 there, are low in albuminoids, it may safely be assumed to be a characteristic of that 
 portion of the country." 
 
 These conclusions scarcely appear to be warranted from the data. 
 By computation from the 114 analyses of corn, I find the total varia- 
 tion in protein to be 63.6 per cent, of the average amount determined; 
 while from the 260 analyses of wheat referred^ to by him it is only neces- 
 sary to exclude 5 analyses to bring the total variation in protein to 60. i 
 per cent, of the average amount determined. Or if we take the averages 
 of tlie 10 highest and the 10 lowest results on the protein of 114 samples- 
 of corn, 12.34 per cent, and 8.19 per cent., respectively, we find the 
 difference, 4.15 per cent., to be 40 per cent, of the general average; 
 while with the averages of the 25 highest and the 25 lowest results on 
 the protein of 260 samples of wheat, 14.97 per cent., and 9.28 per 
 cent., respectively, the difference is 5.69 per cent, or 48 per cent, of the 
 general average (11.95 P^'" cent.). In other words the variation in the 
 corn is only one-sixth less than that in the wheat. It may be noted 
 that if we include the analyses of sweet corn (all varieties .of wheat are 
 considered) the variations in the protein content of corn exceed those in 
 wheat. Jenkins and Winton's compilation'-' shows the protein content 
 to vary more in 208 samples of corn than Richardson found in 260' 
 samples of wheat. 
 
 As to the assumption regarding the Pacific Slope it may be pointed 
 out that the table of analyses from the different States shows the average 
 of 5 analyses of Pennsylvania corn to agree well in percentage of pro- 
 tein with the single analyses from Oregon and Washington. The aver- 
 age of 12 analyses of corn from California reported in 1884 by Richard- 
 son'' shows practically the same percentage of protein as the general 
 average for the United States. 
 
 In 1886 Flechig' made analyses of 14 different varieties of corn^ 
 
 'U. S. Dept. of Agr., Division of Chemistry Bulletin (1SS3), 1. 
 '-'U. S Dept. Agr., Exp. Station Bulletin (1892) 11, 100. 
 ='U. S. Dept. Agr., Division of Chemistry Bulletin (1884) 4. 
 •'Landwirtschaftliche Versuchs-Stationen (1886) 32, 17. 
 
I89S.] 
 
 CHEMISTRY OF THE CORN KERNEL. 
 
 37 
 
 sh. 
 
 Protein. 
 
 Oil. 
 
 Carbohyrates 
 
 .29 
 
 12.63 
 
 5.40 
 
 80.68 
 
 •43 
 
 II .06 
 
 5.80 
 
 80.71 
 
 ■51 
 
 10.50 
 
 5^32 
 
 82.67 
 
 .63 
 
 9.88 
 
 6.21 
 
 82. 28 
 
 .48 
 
 9.88 
 
 5^52 
 
 83.12 
 
 •73 
 
 9.69 
 
 5.88 
 
 82.70 
 
 .58 
 
 9.50 
 
 6.00 
 
 82.92 
 
 •44 
 
 ^•50 
 
 5.02 
 
 84.04 
 
 •42 
 
 9.19 
 
 5-75 
 
 83.64 
 
 .46 
 
 g.o6 
 
 5-43 
 
 84. 05 
 
 .60 
 
 9.00 
 
 6.22 
 
 83.18 
 
 •54 
 
 8.95 
 
 5^43 
 
 84.08 
 
 •35 
 
 8.69 
 
 5.88 
 
 84.08 
 
 all grown under uniform conditions of weather, soil, and fertilization. 
 If we omit a variety of sweet corn' the following are his results:' 
 
 Variety. A 
 
 Jaune HJitif d'Antonina i 
 
 Rother Hiihnermais i 
 
 Weisser steirischer i 
 
 Weisser ungarischer i 
 
 Canquatino i 
 
 Tiirkischer vierzigtiigiger i 
 
 Canadischer aus Ungarn i 
 
 Bunter Augustmais i 
 
 Friih. Amerik. Bernsteinmais . i 
 
 Fruher Badischer i 
 
 Blanc hStif des Landes i 
 
 Improved King Philip i 
 
 Papageienmais i 
 
 In view of the fact that reference has already been made to the 
 wide limit of error in fiber determinations, it may be noted here that 
 the total variation on the final results for fiber as reported by Flechig 
 on the 13 samples of corn is from 1.23 per cent, to 1.86 per cent., 
 while the variation in the separate determinations made on a single 
 sample is from 1.26 per cent, to 1.83 per cent. It is also observed that 
 Flechig's results indicate protein as the most variable constituent of 
 corn grown under uniform conditions. 
 
 Since the establishment of the experiment stations in the United 
 States the number of proximate analyses of corn has been greatly 
 increased''', but in the main the analyses have been made for special pur- 
 poses (as in feeding experiments) other than a study of the corn itself, 
 and upon samples whose history was unknown or unnecessary for the 
 object in view. Only one series of these analyses will be discussed in 
 this connection. 
 
 In 1S93 the Connecticut Experiment Station published' the analyses 
 of 90 samples of corn grown in 1892 in various parts of the state from 
 about 75 differently named varieties, and under exceedingly varying 
 conditions of weather, soil, cultivation, fertilization, etc. If we omit 
 one sample of sweet corn, and one sample which was injured by hail 
 before maturing, the following are the five highest and the five lowest 
 results from all determinations of each constituent; also the general 
 average of all analyses: 
 
 ^ Sucre rid(". 
 
 '-'A few errors were found in Flechig's summary which I have corrected from 
 his analytical data. Fiber is included in the column headed carbohyrates. 
 
 •^Especially by U. S. Dept. of Agr. and Stations of Conn , Mass., 111., Vt. and 
 N. J. 
 
 'Conn. Agr. Exp. Station Annual Report (1893). 
 
r.ULLETlN NO. 53. 
 
 [>d% 
 
 Ash. 
 
 ist highest 2.10 
 
 2nd " 1.90 
 
 3rd " 1.86 
 
 4th " 1.80 
 
 5th " 1.79 
 
 ist lowest 91 
 
 2nd " 98 
 
 3rd " 1 .00 
 
 4th " 1 .01 
 
 5th •■ 1.04 
 
 General average i . 39 
 
 Protein . 
 
 Fat. 
 
 Carbohydrates 
 
 14-53 
 
 6.39 
 
 85.93 
 
 14.04 
 
 5-97 
 
 85.14 
 
 13.86 
 
 5-95 
 
 85.07 
 
 13-33 
 
 5-95 
 
 84.67 
 
 13-29 
 
 5-95 
 
 84.63 
 
 8.33 
 
 3-15 
 
 78.56 
 
 8.69 
 
 3.55 
 
 78.85 
 
 8.79 
 
 4.21 
 
 78.99 
 
 8.82 
 
 4.28 
 
 79.26 
 
 8.25 
 
 4-31 
 
 79.85 
 
 II .63 
 
 5.27 
 
 il.71 
 
 Ash 
 
 Protein. 
 
 Fat. 
 
 Carbohydrates 
 
 1-7 
 
 II. 5 
 
 5-6 
 
 81.2 
 
 1-7 
 
 II. 8 
 
 5-6 
 
 80.9 
 
 1-7 
 
 H.6 
 
 5.6 
 
 81. 1 
 
 The compilation' of Jenkins and Winton gives the average compo- 
 sition of dent and flint corn as follows: 
 
 Samples 
 
 Dent 86 
 
 Flint 68 
 
 General average 154 
 
 By mechanical means the 
 corn kernel has been separated 
 into four different parts. These 
 may be designated (fig. i'^) as 
 (a) the coat, or hull, of the 
 kernel, (b) the hard glutenous 
 layer underneath the hull, 
 much thicker at- the sides than 
 at the crown, (c) the chit, or 
 germ, and (d) the starchy 
 matter constituting the chief 
 body of the kernel. It has 
 never been found possible to 
 make such a separation with 
 even approximate accuracy, 
 the separation of the glutenous 
 layer from the starchy portion 
 being especially difficult. On 
 this basis Salisbury-' gives the 
 following percentage composi- 
 P[(j I tion of the kernel with the 
 
 proximate composition of the different parts reduced to the dry basis: 
 
 >U. S. Dept. of Agr., Exp. Station Bulletin (1892) 11. 
 
 ■■'I am indebted to Director Voorhees, N. J. Agr. Exp Station, for the use of 
 this cut. 
 
 •'Trans. N. Y. State Agr. Soc. (1848) 8, 678. 
 
189S.] CHEMISTRY OF THE CORN KERNEL I39 
 
 Glutenous . Starchy 
 
 Hulls. layer. portion. Germs. 
 
 Percent 4.30 66.63 18.04 11.03 
 
 Ash 4.56 .43 .61 14-05 
 
 Protein! 7.65 2.74 21.39 
 
 Oil 2. 87 3.07 30.26 
 
 Carbohydrates'-' 89.05 93-58 34- 30 
 
 In a microscopic study of the corn kernel Haberlandt' observed that 
 the germ contained a large amount of oil while in the remaining por- 
 tions of the kernel no oil was apparent. Acting upon this Lenz' under- 
 took an analytical investigation of these portions. The germs were 
 carefully removed from the kernels by mechanical means and the oil and 
 protein in the two portions determined. His results on a sample of 
 American white flint corn are as follows : 
 
 Kernels less germs. Germs. 
 
 Per cent 88.18 11.82 
 
 PercentOiH 1.57 32.83 
 
 Protein'' 13-09 19 -93 
 
 Lenz expressed the opinion that the small (quantity of oil found in 
 the kernel after the germ had been removed was really due to particles 
 of the germ which had not been removed or to traces of oil deposited 
 on the remainder of the kernel during the mechanical process of remov- 
 ing the germ. 
 
 This was further investigated by Atwater'' who removed the germ 
 together with a considerable portion of the kernel immediately sur- 
 rounding the germ in order to insure the separation of all oil properly 
 belonging to the germ. Following are his results : 
 
 Outer portion Inner portion 
 
 free from germ. including germ. 
 
 Percent 76.43 23.57 
 
 Per cent. Oil^ 1.63 
 
 Recently Voorhees'' and Balland' have published the following re- 
 sults : 
 
 Glutenous layer 
 Hulls. and starchy portion. Germs. 
 
 5.56 84. 27 10.17 Voorhees. 
 
 12.40 74.10 13-50 Balland. 
 
 *This is given here as the sum of the zein, albumen, and casein reported by 
 Salisbury. 
 
 ^By difference. 
 
 ^Allgemeine land- und forstwirtschaftliche Zeitung (1866) 257; Jahresbericht 
 [Hoffmann] i'lber die Agricultur-Chemie (1S66) 9, 106. 
 
 ■*In the dry matter. 
 
 ^Thesis, Yale College (1869) ; American Journal of Science and Arts (1869) [2] 
 48, 352. 
 
 ""'New Jersey Agr. Exp. Station Bulletin (1894) 105. 
 
 ^Comptes rendus des Scc'ances (1896) 122, 1004 
 
140 
 
 BULLETIN NO. 53. 
 
 [>/>'> 
 
 The following table shows the composition' of the separate parts 
 
 (dry). 
 
 Hulls. 
 
 Glutenous layer and 
 starchy portion. 
 
 Germs. 
 
 Ash. 
 \ 1-25 
 "( 1-44 
 j .68 
 ■j .68 
 ( 10.02 
 "I 7-S7 
 
 Protein. 
 
 6.52 
 
 8.20 
 
 12.15 
 
 8.53 
 
 19-54 
 15.32 
 
 Oil. 
 
 1-57 
 '^•33 
 
 1.53 
 1.08 
 
 26.65 
 
 39.85 
 
 Carbohydrate 
 Fiber. extract. 
 
 16.24 
 11.25 
 
 .65 
 .40 
 
 2.59 
 1.99 
 
 74.42 
 76.78 
 84.99 
 89.31 
 41 .20 
 34-97 
 
 Voorhees. 
 
 Balland. 
 
 Voorhees. 
 
 Balland. 
 
 Voorhees. 
 
 Balland. 
 
 These data confirm the earlier results, showing the germ, which 
 constitutes only about 12 per cent, of the kernel, to contain nearly twice 
 as much mineral matter and three or four times as much oil as all of the 
 remaining portions of the kernel. It is also rich in protein. Voorhees 
 states that the portion richest in protein is the glutenous layer. 
 
 In the manufacture of starch and glucose-sugar from corn these 
 different portions of the kernel are separated much more perfectly than 
 it is possible to do by hand although their original composition is some- 
 what altered. Various methods" have been employed, but the following 
 will indicate briefly a common process : 
 
 The corn is steeped in warm water containing a little sulfurous acid 
 and then reduced to a coarse powder. The germs together with a part 
 of the hulls are recovered by floating and separated after drying. The 
 material remaining in the water in suspension is passed through sieves 
 and the remainder of the hulls and some other coarse matter can thus be 
 separated from the starch and the more finely divided gluten. The 
 starch is finally allowed to settle and then the water containing the larger 
 part of the gluten is run off. After further purification the starch is sold 
 as such or is manufactured into other products, as glucose-sugar. The 
 by-products, hulls, "gluten," and germs, separate or mixed, are sold as 
 food stuffs, the larger part of the oil usually having been expressed from 
 the germs. The mineral matter is, of course, largely removed from 
 these products by the solvent action of the water. 
 
 The analyses of corn oil cake was reported'' by Moser as early as 
 
 1867 with the following results : 
 
 Carbohydrate 
 Ash. Protein. Fat. Fiber. extract. 
 
 8.07 17-19 12.58 II. 41 50.75 
 
 The following is believed to fairly represent the composition (dry) of 
 the several individual products, not as usually found on the market but 
 in their purest condition : 
 
 lAs published Voorhees' results are evidently given on the basis of ash-free 
 organic matter. They are here calculated to the basis of total dry matter. 
 
 -'Journal Society Chemical Industry (1887)6, 84. 
 
 3Jahresbericht (Hoffmann) iiber die Agricultur-Chemie {1S67) 10, 259. Cf. ibid. 
 (1872) 15, 21 ; (1874) 17, 15 ; (1S76) 19, 15 
 
1898.] CHEMISTRY OF THE CORN KERNEL. T41 
 
 Carbohydrate 
 Ash. Protein. Fat. Fiber. e.xtract. 
 
 Hulls' 1.02 11.18 4-13 11.98 71.69 
 
 Gluten- 1. 14 44.03 7.69 2.26 44.88 
 
 Germ cakei 2.58 27.23 14-84 7.41 47-94 
 
 Starch^ 0.30 .... 99.70* 
 
 The correctness of Voorhees' statement that the portion of the corn 
 kernel richest in protein is the glutenous layer is plainly apparent. 
 
 Richards'^ has recently made proximate analyses to determine the 
 heating value of the corn kernel. Calorimetric determinations were also 
 made, being reported in terms of the British thermal unit*'. Following 
 are the results : 
 
 Volatile Fixed Fuel 
 
 Moisture matter. carbon. Ash. value. 
 
 Yellow dent '"^-45 78.10 12.18 1.27 8202. 
 
 White dent 8.88 77.22 12.90 i.oo 8338. 
 
 EXPERIMENTAL. 
 
 In the following work on the pro.ximate composition of corn the 
 total dry matter, the ash, the nitrogen, and the fat were determined 
 directly. The protein was estimated by multiplying the total nitrogen 
 by 6.25 and the carbohydrates by subtracting the sum of the ash, pro- 
 tein, and fat from the total dry matter. In each single determination 
 of the several constituents 2 gms. of air-dry substance were regularly 
 taken. 
 
 Prepar-ation of Sample. — All samples were air-dried, ground to 
 pass through a sieve with circular perforations i millimeter in diameter, 
 and then preserved in air-tight vessels, being thoroughly mixed just 
 before being analyzed. 
 
 Determination of Dry Matter. — The airdry substance was placed 
 in a glass tube 10 cm. long and 2 cm. in diameter over one end of which 
 a piece of hardened filter paper had been firmly tied with nickel wire, 
 the tube with paper bottom having been dried and weighed in weighing 
 tubes before being charged with the substance. The substance was 
 dried with the tube lying in a horizontal position in a current of dry 
 hydrogen at a temperature of 105°, maintained by a boiling aqueous 
 solution of glycerol in a double-wall bath provided with a return con- 
 denser. The gas entered the bath at one end near the top and passed 
 out at the bottom near the opposite end. 
 
 >N. J. Agr. E.xp.. Station Bui. (1894) 105. 
 
 *Conn. Agr. E.xp. Station Report (1895)231. 
 
 ^Journal Society Chemical Industry (1887) 6, 84. 
 
 ^Starch. 
 
 ^'U. S. Dept. of Agr., Exp. Station Bulletin (1898)49, 95. 
 
 "Heat required to raise one pound of water from 50° to 51° F. 
 
142 BULLETIN NO. 53. VJ"^y> 
 
 To determine the error in obtaining the weight of the empty tubes 
 
 with the i)aper bottoms, lo tubes were dried for one hour, cooled in 
 desiccators and weighed in weighing tubes, then dried again for two 
 hours and again weighed, with the following results : 
 
 First weight. Second weight. Decrease. 
 
 1 47-7552 47-7550 .0002 
 
 2 49-0332 49-0328 .0004 
 
 3 ,46.1074 46.1074 .0000 
 
 ^ 48.9842 48.9843 — .0001 
 
 5 48.6642 48.6641 .0001 
 
 6 45-4501 45-4500 .0001 
 
 7 4S.54G1 48-5455 -0006 
 
 8 47.8516 47.8518 — .0002 
 
 9 44-8934 44-8930 -0004 
 
 10 46.2726 46.2727 — .0001 
 
 To determine the length of time required under the conditions 
 mentioned to reduce the substance practically to a constant weight the 
 following data were obtained, 2 gms. of air-dry substance being taken 
 
 from 12 different samples : 
 
 Difference in weight 
 Weight of substance after drying between drying 
 
 4 or S 8 or 16 
 4 hours. 8 hours. 16 hours. hours. hours. 
 
 1 1.7759 1.7639 1.7600 .0120 .0039 
 
 2 1.7662 1.7545 I-7512 .0117 .0033 
 
 3 1-7569 1-7454 1-7413 -0115 -0041 
 
 4 1.7638 1-7525 1-7489 0113 .0036 
 
 5 1.7662 1.7550 Jt-7513 -0112 .0037 
 
 6 1.7635 1-7520 1-7483 -0115 -0037 
 
 7 1-7589 1-7476 1-7435 .0113' .0041 
 
 8 1-7651 1.7541 1-7503 .0110 .0038 
 
 9 1.7738 1.7625 1.7580 .0113 .0045 
 
 lo 1-7536 1.742-.! 1.7387 .0114 .0035 
 
 II 1.7623 I -7505 1-7457 .0118 .0048 
 
 12 1 -7556 1.7450 1.7411 .0106 .0039 
 
 After drying 4 hours the average decrease in weight for four hours 
 more is 0.0114 gms. or 0.6 per cent, of the amount determined, and 
 then for 8 hours more it is 0.0039 g"i^- ^'' °-2 per cent, of the amount 
 determined. This is a much narrower limit of error than can be main- 
 tained in the determination of the constituent groups of the dry matter, 
 and all dry matter determinations which follow were made by drying 
 the substance 8 hours. It is noteworthy that during the second and 
 third periods of drying all of the samples lost weight and in very nearly 
 ecjual amounts, showing that for comparative results a very high degree 
 of accuracy is attained. 
 
 The following work was done to test the agreement of duplicate 
 determinations on the same sample. Twelve different samples were 
 selected, and the 24 portions of 2 gms. each were all dried together: 
 
5] 
 
 CHEMISTRY Ol" IHE CORN KERNEL. 
 
 143 
 
 
 Weight 
 
 of dry 
 
 
 
 matter. 
 
 Variation 
 
 1 . 
 
 . . .1.8276 
 
 1.8273 
 
 .0003 
 
 2. 
 
 . . . I .8230 
 
 1.8238 
 
 .0008 
 
 3- 
 
 . ..1.8218 
 
 1.8222 
 
 .0004 
 
 4- 
 
 .. .1.8319 
 
 1. 8314 
 
 .0005 
 
 5- 
 
 . . .1 .8244 
 
 1 .8249 
 
 .0005 
 
 6. 
 
 . ..I. 8198 
 
 I .8194 
 
 .0004 
 
 7- 
 
 . . .1 .8264 
 
 1.8267 
 
 .0003 
 
 9- 
 
 Weight 
 
 of dry 
 
 
 matter. 
 
 Variation 
 
 . . I .S240 
 
 I .8242 
 
 .0002 
 
 ..1.8243 
 
 1 .8240 
 
 .0003 
 
 . . I . 8202 
 
 1.8209 
 
 .0007 
 
 . . I .8176 
 
 I. 8186 
 
 .0010 
 
 . . 1 .8150 
 
 1. 8155 
 
 .0005 
 
 Average. . 
 
 .000=; 
 
 From these results and those preceding it is seen that determina- 
 tions made in the same bath and at the same time show a remarkable 
 degree of accuracy when compared only with themselves, arid among 
 themselves they are strictly comparable. 
 
 To determine the variation which might be caused by unavoidable 
 differences in temperature, hydrogen current, etc., the following 36 
 duplicate determinations of dry matter were made, in every case the 
 duplicate determinations being made at different times, /. e., the first 
 determination on each sample was made one or more days previous to 
 the second, or duplicate, determination: 
 
 Weight of dry 
 
 
 matter. 
 
 Variation 
 
 I 
 
 •.■1.7456 
 
 1.7489 
 
 •0033 
 
 2 
 
 •■•1-7493 
 
 1.7527 
 
 .0034 
 
 3 
 
 ...1.7444 
 
 I. 7441 
 
 .0003 
 
 4 
 
 ..•1.7362 
 
 I .7360 
 
 .0002 
 
 5 
 
 ... 1 .7200 
 
 1.7238 
 
 .0038 
 
 6 
 
 ••■i^75i4 
 
 I-754I 
 
 .0027 
 
 7 
 
 ...1.7675 
 
 1.76S9 
 
 .0014 
 
 8 
 
 ...1.7628 
 
 1.7637 
 
 .0009 
 
 9 
 
 . ..1.7659 
 
 1^7673 
 
 .0014 
 
 10 
 
 ...1.7540 
 
 1.7588 
 
 .0048 
 
 II 
 
 .•.I^7522 
 
 1^7547 
 
 .0025 
 
 12 
 
 ...1.7554 
 
 1.7592 
 
 .0038 
 
 13 
 
 . . . I . 7698 
 
 I • 7739 
 
 .0041 
 
 14 
 
 ...1.7546 
 
 1.75S6 
 
 .0040 
 
 15 
 
 .. .1 7691 
 
 I. 7741 
 
 .0050 
 
 16 
 
 ...1.7552 
 
 ^■7573 
 
 .0021 
 
 17 
 
 ...1.7723 
 
 1.7689 
 
 .0034 
 
 18 
 
 .••1.7736 
 
 I .7696 
 
 .0040 
 
 19 
 
 . . .1.7760 
 
 1.7742 
 
 .0018 
 
 We 
 
 ght of 
 
 dry 
 
 
 
 matter 
 
 Variation. 
 
 20. . . 1 
 
 7566 
 
 1.7520 
 
 .0046 
 
 21 .... I 
 
 7730 
 
 1. 7719 
 
 .0011 
 
 22 .... I 
 
 ■7795 
 
 1-7734 
 
 .0061 
 
 23. ...I 
 
 7668 
 
 1-7593 
 
 .0075 
 
 24. ...I 
 
 7584 
 
 1.7502 
 
 .0082 
 
 25^^^.i 
 
 7560 
 
 I • 7534 
 
 .0026 
 
 26... I 
 
 7431 
 
 ^•7435 
 
 .0004 
 
 27 ...I 
 
 7526 
 
 I • 7540 
 
 .0014 
 
 28.... I 
 
 7540 
 
 1-7539 
 
 .0001 
 
 29 1 
 
 7590 
 
 1^7599 
 
 .0009 
 
 30. .. I 
 
 7494 
 
 1. 7512 
 
 .0018 
 
 31 ...I 
 
 7489 
 
 1.7465 
 
 .0024 
 
 32.^..i 
 
 7498 
 
 1-7497 
 
 .0001 
 
 33--^^i- 
 
 7552 
 
 1-7559 
 
 .0007 
 
 34-^^^i 
 
 7925 
 
 1.7928 
 
 .0003 
 
 35^^^i 
 
 7515 
 
 I. 7481 
 
 .0034 
 
 36 .. I 
 
 7451 
 rage . . 
 
 I .7408 
 
 .of^43 
 
 Ave 
 
 .0027 
 
 The maximum variation 0.0082 is 0.5 per cent, of the average 
 amount determined; and is very much greater than when the duplicates 
 were made at the same time. However, the agreement still appears 
 very satisfactory. In all subsequent work herein reported the duplicate 
 determinations of dry matter were made at different times in order that 
 the results may show the widest variations possible with the method 
 employed. 
 
 Determin.ation of Ash. — The air-dry substance was placed in a 
 
144 
 
 BULLETIN NO. 53. \^/ll/y, 
 
 poTcelain crucible and burned to constant weight in a muffle at a low red 
 heat, at a temperature below that at which portions of the ash would 
 become fused and attached to the crucible. 
 
 Determination of Nitrogen. — This was made by the ordinary Kjel- 
 dahl method. The metallic mercury used in the digestion was measured 
 in a capillary tube, one end of which is doubly bent so as to form a 
 loop, the short arm of which is turned back upon itself near the end 
 while the long arm serves as a handle. The loop is made sufficiently 
 narrow to pass into the mercury bottle, and of sufficient length to retain 
 when raised above the licjuid the exact (]uantity of mercury required for 
 a single determination. By blowing in the longer arm the mercury is 
 emptied into the digestion flask. 
 
 Heavy copper flasks were used in the distillation with much satis- 
 faction, the sodium hydroxid solution (containing the necessary amount 
 of potassium sulfid) being added in sufficient excess to "bump" before 
 the contents may become dry, thus serving as a signal that the distilla- 
 tion has gone far enough. 
 
 Two common sources of error in the nitrogen determination were 
 found and investigated. In titrating an acid solution in an open vessel 
 with standard ammonia solution a very appreciable error is introduced 
 by the volatility^ of the ammonia, although the only possible loss is 
 from the tip of the burette and from the falling drops. 
 
 In the following work ammonia of about one-sixth normal strength 
 was used, the hydrochloric acid being of such strength that 3 cc. were 
 equivalent to approximately 4 cc. of ammonia. The hydrochloric 
 acid was measured from an automatic overflow pipette of 15 cc. capac- 
 ity, and the ammonia from an automatic overflow burette graduated to 
 0.05 cc. and drawn to a fine tip at the outlet. The pipette and burette 
 were each provided with three way stopcocks through which the 
 standard solutions were drawn from the stock bottles by means of 
 syphons. Perfectly neutral water free from ammonia and carbon dioxid 
 was used for diluting. Lacmoid served as the indicator and gave an 
 exceedingly sharp end reaction. 
 
 By titrating in beaker flasks with the tip of the ammonia burette 
 well below the top of the flask the following results were obtained, the 
 length of time taken in making the titration being also given: 
 
 I 15 cc. HCl required 20. 10 cc. NH3, — time = i minute. 
 
 2 15 cc. HCl " 20.08 cc. NH3, — '• ^ I 
 
 3 15 cc. HCl " 20.12 cc. NH3, — " = I 
 
 4 15 cc. HCl " 20.30 cc. NH 3, — " ^2 
 
 5 15 cc. HCl " 20.25CC. NH3, — " = 2 
 
 G 15 CC. HCl " 20.40CC. NH3, — " = 3 
 
 'Rempel has already shown that dilute ammonia solution drawn into beakers or 
 evaporating dishes and then titrated suSers marked loss. — Zeitschrift f iir angewandte 
 Chemie (1889) 331, 
 
1898.] CHEMISTRY OF THE CORN KERNEL. 1 45 
 
 By titrating in an Erlenmeyer flask attached to the burette by means 
 of a rubber stopper', provided with a capillary tube for relieving the 
 pressure, the following results were obtained : 
 
 1 15 cc. HCl required 19.82 cc. NH3, — time = i minute. 
 
 2 15 cc. HCl " 19.83 cc. NH3, — " := I 
 
 3 15 cc. HCl " 19.81 cc. NH3, — " ^ 3 
 
 4 15 cc. HCl " 19.81 CC.NH3, — " :=5 
 
 As from 3 to 5 minutes are taken to make a titration when the 
 amount of ammonia required is not known, as in ordinary nitrogen de- 
 terminations, the error- from titrating in open vessels becomes an im- 
 portant factor, the total variation in the two series of experiments above 
 noted amounting to 0.6 cc. or 3 per cent, of the ammonia required. The 
 fact that the density of ammonia gas is but little more than half that of 
 air explains its rapid upward diffusion from an open vessel. 
 
 Another error in nitrogen determinations may occur in the distilla- 
 tion by loss of ammonia from the receiving flask in case there is not 
 sufficient acid above the end of the delivei-y tube to neutralize all of the 
 ammonia distilled over. 
 
 In the following work a quantity of a very dilute solution of am- 
 monium chlorid was prepared by exactly neutralizing standard hydro- 
 chloric acid with standard ammonia and diluting with ammonia-free 
 water. A quantity of this solution equivalent to 12 cc. of standard am- 
 monia was placed in a distillation flask with an excess of sodium 
 hydroxid and distilled into 15CC. of standard hydrochloric acid diluted 
 to about 40 cc, the end of the delivery tube from the condenser dipping 
 well into the acid solution. The relation of the standard acid and am- 
 monia solutions was such that 15 cc. HCl were equivalent to 19.82 cc. 
 NH.j. Six distillations were made, in each case ammonium chlorid 
 equivalent to i2cc. of standard ammonia solution being taken. Fol- 
 lowing are the amounts of standard ammonia solution required to 
 neutralize the excess of acid : 
 
 Required. Calculated. Error. 
 
 I 8 . 20 cc. 7 . S2 cc. o . 38 cc. 
 
 2 7.85CC. 7.82 cc. 0.03 cc. 
 
 3 7 . 93 cc. 7 . 82 cc. o . 1 1 cc. 
 
 4 8.60CC. 7.82 cc. 0.78 cc. 
 
 5 7.84 cc, 7.82 cc. 0.02 cc. 
 
 6 7.95 cc. 7.82CC. 0.13CC. 
 
 Two of these are practically exact, the other four showing errors 
 varying from o. 1 1 cc. to 0.78 cc. of standard ammonia. 
 
 This work was repeated with the distillation from quantities of am- 
 monium chlorid equivalent to 15 cc. of standard ammonia solution, the 
 
 ^By using a stopper which has been bored nearly through from the small end 
 by a large borer, the flask may easily be given a free rotary motion. 
 
 ■^Confirmed by recent (unpublished) work of Dr. F. L. Kortright. 
 
146 BULLETIN NO. 53. \.J"h'> 
 
 Other conditions being as before. Following are the amounts of stand- 
 ard ammonia solution recjuired to neutralize the excess of acid : 
 
 Required. Calculated. Error. 
 
 I 6.10CC. 4.82 cc. 1.28 cc. 
 
 2 5.40CC. 4.82 cc. 0.58 cc. 
 
 3 5.95 CO. 4.82 cc. 1.13CC. 
 
 4 6.20CC. 4.82 cc. 1.38 cc. 
 
 5 5.65CC. 4.82 cc. 0.83 cc. 
 
 f) 5.18CC. 4.82 cc. 0.36 cc. 
 
 Diluting the residues in the distillation flasks with ammonia-free 
 water, and distilling, gave no further addition of ammonia in any case. 
 It was observed that in both trials the greatest errors occurred with 
 Nos. I and 4. A careful inspection of the apparatus showed all con- 
 nections to be perfect. It was observed, however, that the delivery 
 tubes from Nos. i and 4 did not reach as far into the acid solution as 
 most of the others. 
 
 With the thought that possibly ammonia escaped from the receiving 
 flasks, the following six distillations were made, in each the quantity of 
 ammonium chlorid employed being equivalent to 19.32 cc. of standard 
 ammonia solution; thus, exactly 0.50 cc. of standard ammonia should 
 have been recjuired to neutralize the excess of acid. Some lacmoid in- 
 dicator was added to the acid solutions in receiving flasks Nos. i, 3, 
 and 5; strips of moistened red litmus paper were also hung in the necks 
 of these flasks. During the process of distillation, receiving flasks 2, 4, 
 and 6 were agitated to keep their contents thoroughly mixed. 
 
 It was observed that, during the process of distillation, in receiv- 
 ing flasks I, 3, and 5 the liquid above the end of the delivery tube turned 
 blue, while a layer of licpiid below this remained red; also that the 
 moistened red litmus pa])er hung in the necks of these flasks turned 
 blue. 
 
 In titrating the excess of acid the amounts of standard ammonia 
 re(|uired were as follows : 
 
 Required. Calculated. Error. 
 
 I 2.60CC. 0.50 cc. 2.10 cc, 
 
 2 0.50CC. 0.50 cc. 0.00 cc. 
 
 3 2.27CC. 0.50 cc. 1.77 cc. 
 
 4 0.53 cc. 0.50 cc. 0.03 cc. 
 
 5 1.99CC. 0.50 cc. 1.49 cc. 
 
 6 0.50 cc. 0.50 cc. 0.00 cc. 
 
 The explanation for the separation of the liquid in the receiving 
 flasks into two layers as described is to be found in the difterent 
 densities of acjueous solutions of ammonia and hydrochloric acid. 
 
 In subsequent work I have used delivery tubes reaching to the very 
 bottom of the receiving flasks, and contracted at the end to an aperture 
 of but 4 or 5 mm. diameter. This insures considerable agitation of the 
 
1898.] 
 
 CHEMISTRY OV THE CORN KERNEL. 
 
 147 
 
 content of the receiving flask produced by irregularities in the boiling 
 of the liquid in the distillation flask. 
 
 This loss of ammonia shown to have taken place from the very 
 dilute solution in the receiving flask after cooling by an efficient con- 
 denser emphasizes the results of the preceding work on titration and 
 the importance of avoiding a common error in that process. 
 
 Determination of Fat. — The glass tube with the bottom of hardened- 
 filter paper (previously described) containing the dry matter from 2 gms. 
 of air-dry substance was placed in a Soxhlet tube and the fat extracted, 
 the solvent passing through the substance and being filtered by the paper 
 bottom. This arrangement is for several reasons preferred to the use 
 of tubes made entirely of filter paper, i. The determination of dry 
 matter and the extraction of fat are done in the same tube without 
 transferring the substance. 2. The solvent //lus^ pass through the sub- 
 stance. 3. The hardened paper can be removed from the tube (after 
 taking off the wire ligature), spread out in the side of a funnel and the 
 fat-free substance easily and completely removed from both paper and 
 tube, by washing with the hot dilute sulfuric acid to be used in case a 
 fiber determination is desired. 
 
 The ether used in the extraction was kept over metallic sodium in 
 the form of wire, and redistilled before being used. The upper end of 
 the condenser was protected by a calcium chlorid tube. 
 
 Mainly to avoid the constant trouble of having 
 atmospheric moisture condense upon the outer sur- 
 face of a Liebig or Allihn condenser and run down 
 3 over the extraction apparatus, the following form 
 of condenser (fig. 2) was designed : 
 
 This condenser is made entirely of glass, and 
 consists of a ////;/ glass tube (a) 25 mm. outside 
 diameter and 25 cm. long, provided with two glass 
 tubes about 6 mm. in diameter, one reaching to 
 near the bottom of (a), sealed in for water inlet 
 and outlet. The tube (a) is surrounded by a 
 stronger glass tube (b) of 30 mm. inside diameter 
 sealed on at the top and narrowed at the lower 
 end to a 10 mm. tube which extends 8 mm. below 
 and is ground off obliquely at the end. About 3 
 cm. from the top of tube (b) a side tube (c) is 
 provided; it is 5 cm. long and 12 mm. inner 
 diameter, and is widened, as indicated in the 
 figure, where it is sealed into (b). The water 
 tubes are cut off at a length -of 5 cm., being blown as indicated to hold 
 a rubber tube. 
 
 The outer tube of this- condenser is not cooled to a temperature at 
 
 CD 
 
I4S BULLETIN NO. 53. \.J"hi 
 
 which atmosplieric moisture will condense upon it. This is its chief 
 advantage over the ordinary form in fat extraction with anhydrous 
 ether. The side tube serves to connect with a drying tube.' 
 
 In making the proximate analyses which are reported herein the fat 
 was always heated in a current of dry hydrogen for 3 hours at 105 -; 
 the flask allowed to cool in the air and then to stand in the balance case 
 until the weight became constant. The flasks used in the work were of 
 Erlenmeyer's pattern with about 100 cc. capacity and weighed 25 to 30 
 gms. each. Differences of barometric pressure and of humidity of the 
 atmosphere of the laboratory may easily produce slight changes in 
 weight. 
 
 To cool the flasks in desiccators before weighing was found unsatis- 
 factory on account of the fact that the perfectly dry air of the desic- 
 cator is considerably heavier than the moist air of the laboratory, and 
 after the flask is removed from the desiccator its weight does not become 
 constant until the dry air is replaced by that of the laboratory and the 
 ■condensation of moisture upon the surface of the glass ceases. 
 
 In all of my analyses herein reported to determine the proximate 
 composition of corn, two complete single analyses were made; the 
 computations were made separately with no averages, and the results 
 are reported separately. Furthermore the two analyses were made at 
 different times, and the differences between the duplicates certainly 
 fairly represent the experimental error. The computations were made 
 by logarithms and directly to the percentage composition of the dry matter 
 The logarithm of 6.25 was included in the proper factor logarithm for 
 calculating the protein equivalent from cubic centimeters of standard 
 ammonia solution. In no case has the percentage of nitrogen or the 
 percentage composition of the air-dry substance been calculated. If 
 desired the former can be determined exactly by dividing the percentage 
 
 1 A few other important points may be noted. The condenser may be used in 
 ordinary distillation by passing the vapor in through the side tube. The ordinary 
 condenser frequently breaks in consequence of the extreme differences in the temper- 
 ature of the inner tube just above and below the surface of the surrounding water. 
 The new form is free from this objection. The water tubes are both at the top and 
 very convenient for joining up a series of condensers. These condensers are more 
 compact and yet much more effective than the ordinary form, the vapor being dis- 
 tributed in a thin layer over a very large condensing surface, the outer tube also 
 acting as an "air condenser." 
 
 These condensers have been in almost constant use during the past year in the 
 chemical laboratories of the University of Illinois and have given excellent satis- 
 faction. 
 
 There are several condensers which have the water tube inside, but I have 
 found none suited to the purpose for which this was especially designed except that 
 recently described by Sudborough and Feilmann (Jour. Soc. Chem. Ind. (iSgy) 16, 
 979), which is certainly to be preferred to the ordinary form as a return condenser, 
 though it cannot be used safely in distillation. 
 
1898. 
 
 CHEMISTRY OF THE CORN KERNEL. 
 
 149 
 
 of protein by 6.25. The fact that the moisture content of air-dry corn 
 merely depends upon the weather and is just as changeable is deemed 
 sufficient reason for ignoring the percentage composition of the air-dry 
 substance in this study. 
 
 Collecting Samples of Corn. — To determine the accuracy of taking 
 samples of corn a bushel or more of shelled corn from each of ten 
 different lots was thoroughly mixed, and then two samples of one pint 
 each were taken for analysis, a single analysis being made of each 
 sample. Following are the results obtained: 
 
 
 Ash. 
 
 42 
 
 Protein. Fat. 
 
 3-1; 
 = 1; 
 
 10.07 
 10. ig 
 
 10.85 
 10. 78 
 
 10.72 
 10.66 
 
 II .40 
 II .42 
 
 II .24 
 II .04 
 
 Carbohy- 
 drates. 
 83.80 
 83.66 
 
 83-31 
 83.41 
 
 83.61 
 83.66 
 
 82.66 
 82.56 
 
 82.55 
 
 82.76 
 
 6- 
 
 8- 
 
 9- 
 
 Ash. 
 
 Protein. 
 
 Fat. 
 
 Carbohy 
 drates. 
 
 
 48 
 45 
 
 II .04 
 10.81 
 
 4 
 
 4 
 
 66 
 63 
 
 82.82 
 83.11 
 
 
 50 
 49 
 
 11-33 
 11-43 
 
 4 
 
 4 
 
 79 
 77 
 
 82.38 
 82.31 
 
 
 51 
 54 
 
 11-35 
 II .42 
 
 5 
 5 
 
 14 
 15 
 
 82.00 
 81.89 
 
 
 43 
 43 
 
 II. II 
 II .og 
 
 4 
 
 4 
 
 76 
 81 
 
 82.70 
 82. 67 
 
 
 49 
 
 48 
 
 . 1 1 . 09 
 II .02 
 
 4 
 4 
 
 73 
 73 
 
 82.69 
 
 82.77 
 
 These results show the method of sampling to be satisfactory. The 
 variations between results on duplicate samples are scarcely greater than 
 the experimental error in making duplicate analyses of a single sample', 
 although variations among the different lots amount to very much more. 
 This is especially marked in the fat column where, although the average 
 amount determined is less than 5 per cent., there is a difference among 
 the lots of from 4.25 to 5.15 or 0.90 per cent, and between duplicate 
 samples of only 0.05 per cent. 
 
 Analyses of one Variety.*^ — The following ten duplicate analyses 
 
 were made to determine the possible variation in a single variety of corn 
 
 which had been grown under conditions as nearly uniform as possible. 
 
 From each of ten different tenth-acre plots lying in the same field several 
 
 bushels of corn were taken. The corn was shelled, thoroughly mixed, 
 
 and a pint sample taken from each lot for anaylsis. Following are the 
 
 results obtained: 
 
 Carbohy- 
 
 Ash. 
 
 \ 1-39 
 I 1. 41 
 
 \ 1-42 
 I 1-43 
 
 Protein. Fat. 
 
 IX .24 
 II . 17 
 
 11.54 
 II .50 
 
 4-43 
 4.41 
 
 4-45 
 4-47 
 
 drates. 
 
 82.94 
 
 83.01 
 
 82.59 
 82.60 
 
 Ash. 
 
 -, U.33 
 ^ ( 1.36 
 
 J 1-49 
 "*( 1-50 
 
 
 
 
 Carbohy 
 
 Pre 
 
 )tein. 
 
 Fat. 
 
 drates. 
 
 II 
 
 19 
 
 4.27 
 
 83.21 
 
 II 
 
 08 
 
 4.27 
 
 83.29 
 
 II 
 
 • 47 
 
 4-38 
 
 82.66 
 
 II 
 
 41 
 
 4.30 
 
 82.79 
 
 iSee the following table. 
 
 *A variety of white dent corn well known in Illinois as Burr's White. This 
 corn has been grown in large quantities for several years upon the- University of Illi- 
 nois Agricultural Experiment Station fields, and special precautions have been taker* 
 to keep it pure and distinct. 
 
 / 
 
.150 
 
 BULLETIN NO. 53. 
 
 U»h', 
 
 Ash. 
 
 ii.34 
 ^\ 1-34 
 
 6-! '-38 
 { 1.42 
 
 7- 
 
 S 1. 41 
 
 / 1..3S 
 
 Protein. 
 II .26 
 II .24 
 
 II .62 
 II .70 
 
 II .42 
 11.33 
 
 Fat. 
 
 4-49 
 
 4-47 
 
 4-44 
 4.41 
 
 4-36 
 4-39 
 
 Carbohy- 
 drates. 
 82.91 
 82.95 
 
 82.56 
 82.47 
 
 82.81 
 82.90 
 
 Ash. 
 
 si ^-42 
 \ I-4I 
 
 9i/-39 
 / 1-39 
 
 ( 1 .42 
 10 - ^ 
 \ 1-42 
 
 Protein. 
 
 11.49 
 11.44 
 
 11.56 
 II. 51 
 
 11.47 
 11-45 
 
 Fat. 
 
 4.26 
 30 
 
 Carbohy- 
 drates. 
 
 82.83 
 82.85 
 
 82.58 
 82.55 
 
 82.69 
 82.65 
 
 These results show a marked degree of uniformity, seen more 
 •clearly from the following maxima and minima of all determinations: 
 
 Ash. 
 
 Maximum i .50 
 
 Minimum 1-33 
 
 Difference o. 17 
 
 Protein. 
 
 Fat. 
 
 Carbohydrates. 
 
 11.70 
 
 4-55 
 
 83.29 
 
 11.08 
 
 4.26 
 
 82.47 
 
 0.62 
 
 0.82 
 
 By referring to Flechig's experiment (page 137) it is seen that with 
 thirteen different varieties of corn grown under uniform conditions he 
 obtained results showing the following variations : 
 
 Ash. 
 
 Maximum i • 73 
 
 Minimum i .29 
 
 Difference 0.44 
 
 Analyses of Different Ears. 
 
 Protein. 
 
 Fat. 
 
 Carbohydrates 
 
 12.63 
 
 6.22 
 
 84.08 
 
 9.00 
 
 5.02 
 
 80.68 
 
 4-63 
 
 3-40 
 
 -In order to investigate more fully 
 the question of variation or uniformity in a single variety 50 separate ears 
 of Burr's White corn from the same field as that used in the preceding 
 ■experiment were carefully selected from a number of bushels which had 
 been especially picked out for seed corn. The 50 ears were all well 
 formed and well matured, and had been grown in a field which had been 
 •selected because of its uniform soil conditions. Duplicate analyses were 
 -made of the corn from each ear. Following are the results obtained : 
 
 3" 
 
 Ash. 
 
 Protein. 
 
 Fat. 
 
 • Carbohy- 
 drates. 
 
 Ash. 
 
 Protein. 
 
 Fat- 
 
 Carbohy 
 drates. 
 
 1.44 
 1 .46 
 
 10.79 
 10.86 
 
 5.66 
 5.65 
 
 82.11 
 82.03 
 
 «]: 
 
 II 
 10 
 
 8.41 
 8.35 
 
 4. 86 
 4.90 
 
 85.62 
 85. 65 
 
 1 .60 
 1 .60 
 
 12.77 
 12.84 
 
 5-19 
 5.22 
 
 So. 44 
 80.34 
 
 9- \ 
 
 41 
 42 
 
 9.91 
 10.00 
 
 4.22 
 4.24 
 
 84 . 46 
 84.34 
 
 1.32 
 1.29 
 
 10.77 
 10.76 
 
 4. 16 
 4. II 
 
 83.75 
 83.84 
 
 10 -! 
 
 44 
 43 
 
 II .46 
 11.35 
 
 5.01 
 5.02 
 
 82 . 09 
 82.20 
 
 1 .26 
 1 .26 
 
 10.49 
 10.46 
 
 4-53 
 4-54 
 
 83.72 
 83.74 
 
 II -j 
 
 54 
 56 
 
 12.40 
 12.36 
 
 4.61 
 4.62 
 
 81.45 
 81.46 
 
 1 .og 
 1. 10 
 
 9-33 
 9.27 
 
 4-35 
 4.41 
 
 85.23 
 85.22 
 
 12 -] 
 
 39 
 
 38 
 
 9.99 
 9.96 
 
 4.41 
 4.42 
 
 84.21 
 84.24 
 
 1-34 
 1.32 
 
 9. II 
 9.13 
 
 4.06 
 4-13 
 
 85.49 
 85.42 
 
 A\ 
 
 37 
 36 
 
 10. 12 
 10.05 
 
 4.80 
 4.85 
 
 83.71 
 83.74 
 
 1-30 
 
 1.28 
 
 10.41 
 10.41 
 
 4.19 
 4-15 
 
 84. 10 
 84. 16 
 
 -n 
 
 36 
 36 
 
 10.31 
 10.31 
 
 5.24 
 5.26 
 
 83.09 
 83.07 
 
IS98.] 
 
 CHEMISTRY OF THE CORN KERNEL. 
 
 Ash. Protein. 
 
 15 
 
 16 
 
 17 
 
 19 
 
 =1-! 
 
 23 
 
 24 
 
 25 
 
 26 
 
 34 
 33 
 
 45 
 44 
 
 35 
 34 
 
 48 
 50 
 
 43 
 43 
 
 32 
 33 
 
 36 
 
 37 
 
 35 
 34 
 
 40 
 40 
 
 48 
 46 
 
 61 
 59 
 
 .70 
 ( 1.70 
 
 U 1.46 
 
 28.p-55 
 / 1-54 
 
 \ 1.62 
 "9 1.62 
 
 \ 1.63 
 30 - t 
 -^ / 1 .62 
 
 ,1 3 1-45 
 ^'1 1.48 
 
 32- 
 
 1.38 
 / 1.40 
 
 9.70 
 9-65 
 
 1. 88 
 1. 86 
 
 0.79 
 0.67 
 
 3.88 
 3.85 
 
 1-55 
 1.52 
 
 1.63 
 1 .64 
 
 1.30 
 1. 19 
 
 I. Si 
 1. 91 
 
 0.22 
 0.13 
 
 1. 14 
 1. 16 
 
 1.46 
 1.38 
 
 10.03 
 
 10.07 
 
 10. 3S 
 10.44 
 
 10.95 
 II .06 
 
 10.82 
 10.95 
 
 11.45 
 11-54 
 
 1 1 . 49 
 II .48 
 
 II. 78 
 11.77 
 
 Fat. 
 4 .01 
 4.01 
 
 4.62 
 4 .60 
 
 4-52 
 4-54 
 
 5-71 
 5-73 
 
 33 
 
 ,29 
 
 .56 
 .57 
 
 15 
 
 17 
 
 4-97 
 5-03 
 
 6.02 
 6.02 
 
 5-19 
 5.20 
 
 Carbohy- 
 drates. 
 
 84-95 
 S5.01 
 
 82.05 
 
 83-34 
 83-45 
 
 78.93 
 78.92 
 
 82.69 
 82.76 
 
 82.49 
 82.46 
 
 S3. 19 
 83 27 
 
 Si. 87 
 81.72 
 
 82.36 
 
 82. 45 
 
 82. 27 
 82.23 
 
 81.74 
 81.83 
 
 83.50 
 83.47 
 
 82.97 
 82.85 
 
 82.64 
 
 82.48 
 
 82.70 
 82.54 
 
 82.36 
 82.25 
 
 82.80 
 82.79 
 
 82.00 
 82.01 
 
 ii 
 
 34- 
 
 35 
 
 36 j 
 
 37 
 
 38 
 
 39- 
 
 40 
 
 41 
 
 42-, 
 
 43- 
 
 44 
 
 45 
 
 46 
 
 47 
 
 48 
 
 49 
 
 50 
 
 As 
 
 h. 
 
 Protein. 
 
 Fat. 
 
 Carbohy- 
 drates. 
 
 
 16 
 
 17 
 
 9.01 
 9 13 
 
 4.04 
 4.06 
 
 85.79 
 85.64 
 
 
 50 
 52 
 
 12.72 
 12.86 
 
 4.24 
 
 4.26 
 
 81.54 
 81.36 
 
 
 45 
 46 
 
 11.83 
 11-73 
 
 4 
 4. 
 
 93 
 93 
 
 81.79 
 
 81.88 
 
 
 48 
 50 
 
 12.07 
 12.06 
 
 4- 
 4. 
 
 60 
 62 
 
 81. 85 
 81.82 
 
 
 58 
 60 
 
 12.35 
 12.44 
 
 4- 
 4 
 
 76 
 72 
 
 81.31 
 81.24 
 
 
 33 
 36 
 
 9.38 
 9.06 
 
 4- 
 4 
 
 86 
 
 82 
 
 84-43 
 84.76 
 
 
 62 
 60 
 
 10.72 
 10.71 
 
 4 
 4 
 
 69 
 
 71 
 
 82.97 
 82. 9S 
 
 
 54 
 55 
 
 9.85 
 9-95 
 
 4 
 4 
 
 95 
 99 
 
 83.66 
 83-51 
 
 
 55 
 
 57 
 
 10.69 
 10.67 
 
 4 
 4 
 
 92 
 90 
 
 82.84 
 82.86 
 
 
 47 
 45 
 
 12. 98 
 12.94 
 
 3 
 3 
 
 98 
 95 
 
 81.57 
 81.66 
 
 
 47 
 
 48 
 
 11.79 
 II .81 
 
 4 
 4 
 
 So 
 79 
 
 81.94 
 81.92 
 
 
 74 
 73 
 
 II. 91 
 11.88 
 
 4 
 4 
 
 55 
 
 54 
 
 81.80 
 81.85 
 
 
 -55 
 
 •54 
 
 10.53 
 10.46 
 
 5 
 5 
 
 .50 
 -52 
 
 82.42 
 82. 4S 
 
 
 .60 
 .60 
 
 II .06 
 II. 13 
 
 4 
 
 4 
 
 -38 
 -39 
 
 82.96 
 
 82.88 
 
 
 .60 
 
 -58 
 
 II. 85 
 II .82 
 
 4 
 4 
 
 -93 
 .98 
 
 81.62 
 81.62 
 
 
 .38 
 .40 
 
 10.21 
 10.26 
 
 5 
 5 
 
 .47 
 .54 
 
 82.94 
 82.80 
 
 
 .42 
 •42 
 
 8.36 
 8.43 
 
 4 
 4 
 
 •87 
 -94 
 
 85.35 
 85.21 
 
 
 .65 
 .65 
 
 12.28 
 12.28 
 
 4 
 4 
 
 .76 
 -75 
 
 81.31 
 81.32 
 
 __ • C 
 
 It must be admitted that these results are far from being uniform. 
 Indeed, they are quite the opposite, and seem to bring out and clearly 
 to establish the fact that there are extreme variations in the chemical 
 composition of corn grown from the purest seed of a single variety and 
 under markedly uniform field conditions. Then the results given in the 
 experiment preceding this are to be considered merely as averages from 
 3. large number of small samples of widely varying composition. 
 
152 HULLETIN NO. 53. ^Julyy 
 
 Following are the maxima and minima of all constituents as shown 
 by the 50 duplicate analyses : 
 
 Ash. Protein. Fat. Carbohydrates. 
 
 Maximum i.74 i.^-^^^ 6.02 •'^S.yg 
 
 Minimum 1.09 8.35 3.95 78.92 
 
 Difference 0.65 5.53 2.07 6.87 
 
 With every constituent the variation is greater than Flechig found 
 with 13 different varieties, and it is nearly as great as found by the Con- 
 necticut Experiment Station with about 75 different varieties of corn 
 grown under 90 presumably different conditions. 
 
 This comparison is facilitated by the following table which gives 
 the number ot samples containing the different constituents in amounts 
 above and below certain specified percentages; columns I. and II. give 
 the numbers of such samples^ from my results and those of the Con- 
 necticut Station, respectively: 
 
 Percent. I II Percent. I. II. 
 
 Ash above 1.70 i 5 below i.io i 9 
 
 Protein " 13.75 1 3 " 9.00 2 4 
 
 Fat " 6.00 1 I " 4.00 1 2 
 
 Carbohy rates " 85.00 5 3 " 79.00 i 4 
 
 It is observed that the number of samples with percentages of ash 
 outside of these extremes is 2 with my results and 14 with the Connecti- 
 cut experiments. This is in accord with the well known fact that the 
 amount of ash constituents taken up by plants varies largely with the 
 amount of soluble mineral matter in the soil, somewhat regardless of 
 the needs of the plant; and it indicates wide variations in Connecticut 
 soils in this regard, as we should expect to be the case. By reference 
 to page 138 it is seen that the percentages of ash in the 90 samples varied 
 from 0.91 to 2.10. 
 
 If we omit the ash, the number of percentages of all constituents 
 which fall outside the limits given above is 11 with my results from 50 
 samples and 16 with the Connecticut results from 90 samples. 
 
 Analyses of Parts of the Ear. — In studying this question 30 dupli- 
 cate analyses were first made on different parts of ears. Five ears were 
 divided lengthwise into 3 samples each in the following manner: If the 
 ear were 12-rowed, 3 samples of 4 consecutive rows each were made; 
 if i6-rowed, 3 samples of 5 consecutive rows each were made, one 
 row being left, etc., etc. 
 
 Duplicate analyses of 15 samples thus prepared from 5 different 
 ears gave the following results. The different ears are distinguished by 
 the letters (a), (b), (c), (d), and (e): 
 
 'Not single determinations. 
 
1898.] 
 
 CHEMISTR^■ OF THE CORN KERNEL. 
 
 153 
 
 Ash. Protein. Fat. 
 
 Ma)|; 
 
 2 (a) 
 
 3(a) 
 
 4(b) 
 
 5(b) 
 
 6(b) 
 
 7(c) 
 
 Moj; 
 
 42 
 
 43 
 
 10 
 10 
 
 79 
 
 75 
 
 48 
 47 
 
 10 
 10 
 
 97 
 94 
 
 50 
 51 
 
 10 
 
 10 
 
 66 
 
 72 
 
 51 
 52 
 
 12 
 11 
 
 00 
 
 98 
 
 49 
 48 
 
 12 
 12 
 
 01 
 05 
 
 48 
 47 
 
 12 
 
 12 
 
 19 
 08 
 
 10. og 
 10. 10 
 
 10. 14 
 10.18 
 
 Carbohy- 
 drates. 
 83.22 
 83.24 
 
 83.01 
 83.08 
 
 83.31 
 83.22 
 
 81.89 
 81. gi 
 
 81.93 
 Si .90 
 
 81.48 
 81.65 
 
 83.30 
 83.36 
 
 S3. 47 
 83.30 
 
 9 (c) -j ; ; 
 
 10 (d) -j J ; 
 
 ii(d)-j;; 
 
 i2(d)-j \- 
 
 i3(e)-j 5; 
 
 14 (e)j J; 
 
 i5(e)-j ; 
 
 h. 
 
 Protein. 
 
 Fat. 
 
 Carbohy 
 drates. 
 
 3G 
 37 
 
 10. 15 
 10.20 
 
 5 
 5 
 
 20 
 
 17 
 
 83.29 
 83.26 
 
 39 
 38 
 
 10.46 
 10.46 
 
 4 
 4 
 
 28 
 29 
 
 83.87 
 83.87 
 
 43 
 
 42 
 
 10.25 
 10.27 
 
 4 
 4 
 
 22 
 20 
 
 84. 10 
 84.11 
 
 43 
 45 
 
 10.09 
 10.06 
 
 4 
 4 
 
 16 
 15 
 
 84.32 
 84.34 
 
 34 
 
 36 
 
 1 1 . 1 9 
 II .20 
 
 4 
 4 
 
 80 
 
 78 
 
 82.67 
 82 . 66 
 
 30 
 
 28 
 
 10.66 
 10.62 
 
 4 
 4 
 
 91 
 89 
 
 83.13 
 83.21 
 
 36 
 36 
 
 10.81 
 10.92 
 
 4 
 4 
 
 83 
 
 79 
 
 83.00 
 82.93 
 
 These results indicate uniformity in the composition of the different 
 parts of the ear. The following shows the greatest total variation in 
 the 6 single determinations of each constituent in any one ear; and 
 also the total variation between the different ears: 
 
 Ash. Protein. Fat. Carbohydrates. 
 
 In any single ear og .58 ' .28 .55 
 
 In five ears 24 2.13 1.09 2.86 
 
 Another lot of five ears was selectee^ and each of these was divided 
 crosswise into 3 samples of approximately equal amounts, which for 
 convenience are designated "tip," "middle," and "butt," the ears being 
 lettered (f), (g), (h), (i), and (j). 
 
 The duplicate analyses follow: 
 
 
 Ash. 
 
 Protein. 
 
 Fat 
 
 Carbohy- 
 drates. 
 
 Ash 
 
 Protein. 
 
 Carbohy" 
 Fat. drates. 
 
 16 (f) 
 
 Tip 
 
 \ 1.58 
 (1-59 
 
 II .78 
 II .76 
 
 5.og 
 5.10 
 
 81.55 
 81.55 
 
 24 (h) \ I 
 Butt ( I 
 
 51 
 
 49 
 
 10.49 
 10.46 
 
 4.01 
 4.00 
 
 83.99 
 84.05 
 
 17 (f) 
 Middle 
 
 \ 1.58 
 M.57 
 
 12.22 
 12.26 
 
 5.13 
 5.03 
 
 81 .07 
 
 81.14 
 
 25 (i) \ I 
 Tip ■/ I 
 
 47 
 48 
 
 10.58 
 10.61 
 
 4. 58 
 4.60 
 
 83.37 
 83.31 
 
 18 (f) 
 Butt 
 
 \ 1.56 
 } 1.58 
 
 12.36 
 12.42 
 
 5.04 
 5.03 
 
 81 .04 
 80.97 
 
 26 (i) \ I 
 Middle ( i 
 
 45 
 
 44 
 
 II .05 
 II .03 
 
 4.56 
 4.60 
 
 82.96 
 82.93 
 
 19 (g) 
 Tip 
 
 \ 1.49 
 M.49 
 
 II. gg 
 11.97 
 
 4.86 
 4.84 
 
 8r.66 
 
 81 .70 
 
 27 (i) \ I 
 Butt 1 I 
 
 47 
 48 
 
 1 1 .03 
 10.96 
 
 4.48 
 4.4G 
 
 83.02 
 83.10 
 
 20 (g) 
 Middle 
 
 ( I. 51 
 ( I. 51 
 
 12.49 
 12 4g 
 
 4.77 
 4.76 
 
 81.23 
 81.24 
 
 28 (j) ( I 
 
 Tip 1 I 
 
 77 
 74 
 
 10. 87 
 10.78 
 
 4.36 
 4.37 
 
 83.00 
 83.11 
 
 21 (g) 
 Butt 
 
 (1.50 
 1 1.51 
 
 13.02 
 13. 10 
 
 4.57 
 4-59 
 
 80. gi 
 80.80 
 
 2g (j) ( I 
 Middle ( i 
 
 65 
 62 
 
 11.35 
 II. 31 
 
 4.56 
 4.58 
 
 82.44 
 82 49 
 
 22(h) 
 Tip 
 
 U.37 
 ) 1.35 
 
 9.72 
 g.67 
 
 3-90 
 3-93 
 
 85.01 
 85. 05 
 
 30 (j) ( I 
 Butt ( I 
 
 71 
 72 
 
 II . ^2 
 
 11 .28 
 
 4.28 
 4.29 
 
 82. 6g 
 82.71 
 
 23 (h) 
 Middle 
 
 ^ 1.37 
 / 1.35 
 
 10.07 
 10.08 
 
 3 98 
 3.97 
 
 84.58 
 84.60 
 
 
 
 
 
 
154 
 
 BULLETIN NO. 
 
 53- 
 
 U^^iy, 
 
 -'rotein. 
 
 Fat. 
 
 Carbohydrates 
 
 I-I3 
 
 • 30 
 
 1 .06 
 
 3-43 
 
 1.23 
 
 4-25 
 
 These results are similar to those in the preceding experiment. 
 The following shows the total variation: 
 
 Ash. 
 
 In any single ear 16 
 
 In five ears 42 
 
 It is observed that in every case the tip is lowest in protein and that 
 usually the middle is lower than the butt, the average total difference in 
 the ear being 0.73 per cent, and the widest 1.13 per cent, as shown 
 above'. The variation in ash and fat is small and shows no such pecu- 
 liarity. The carbohydrates, being estimated by difference, appear, of 
 course, as the complement to the sum of the other substances and show 
 in the opposite direction approximately the variation of the most 
 variable determinable constituent. 
 
 Partial Analyses of Single Kernels. — From 1009 separate deter- 
 minations Richardson- has found the average weight of 100 kernels of 
 air-dry corn to be 36.7 gms. Allowing 10 per cent, for moisture, gives 
 0.330 gms. as the average weight of the dry kernel. This weight is too 
 small for a very exact single determination of a single constituent, and, 
 of course, no attempt has been made to do more than that. 
 
 The ash determination was made by incinerating the whole kernel 
 without grinding, the weight of the dry matter having been previously 
 taken after drying the kernel for 8 hours in a current of hydrogen at 
 105°; and the nitrogen determination was made on the whole kernel 
 after drying and without grinding, the digestion proceeding as satisfac- 
 torily as with ground corn. No satisfactory method was found for the 
 determination of the fat in a single kernel. 
 
 The ash determinations in 10 single kernels taken from as many 
 different places on an ear gave the following results : 
 
 
 Kernel, 
 
 Ash, 
 
 Ash, 
 
 
 weight. 
 
 weight. 
 
 per cent. 
 
 I . . 
 
 . ..0.3579 
 
 0.0048 
 
 1-34 
 
 ? 
 
 . . .0.2947 
 
 0.0042 
 
 1-43 
 
 3.- 
 
 ...0.3985 
 
 0.0052 
 
 1-30 
 
 4- • 
 
 •.•0.35S5 
 
 0.0046 
 
 1. 28 
 
 5-- 
 
 . ..0.3936 
 
 0.0054 
 
 1-37 
 
 
 Kernel, 
 
 Ash, 
 
 Ash, 
 
 
 weight. 
 
 weight. 
 
 per cent. 
 
 6.. 
 
 ...0.3953 
 
 0.0053 
 
 1-34 
 
 !■■ 
 
 ...0.4507 
 
 . 0066 
 
 1.46 
 
 8.. 
 
 . . .0.4589 
 
 . 0064 
 
 1-39 
 
 9-- 
 
 . . .0.4211 
 
 0.0062 
 
 1-47 
 
 0. . 
 
 .. .0.5072 
 
 0.0070 
 
 1.3S 
 
 For further work on the ash content several ears of corn were 
 selected, and from each a sample of corn, consisting of a number of 
 rows and believed to fairly represent the ear, was taken and its percent- 
 age of ash in the dry matter determined. Then for the special investiga- 
 tion of the ash content of single kernels four ears from the lot were 
 chosen, of which two were high and two were low, comparatively, in the 
 
 >It will be seen that later work on single kernels tends to confirm and establish 
 this as a characteristic of the ear of corn. 
 
 -U. S. Dept. of Agr., Div. of Chem Bui. (1884) 4, 82. 
 
.] 
 
 CHEMISTRY OF THE CORN KERNEL. 
 
 percentage of ash as previously determined. From each ear lo kernels 
 were selected at approximately equal distances apart throughout the 
 length of the ear, the kernels being numbered from i to lo and the 
 order running from tip to butt. The data from the ash determinations 
 in the single kernels and also the percentage of ash in the large sample 
 from the same ear are given below : 
 
 / 
 
 
 Ear No. i.- 
 
 -Ash = 1.73 per cent. 
 
 Ear No. 2. — Ash 
 
 = 1 .65 per cent. 
 
 
 Kernel, 
 
 Ash, 
 
 Ash, 
 
 
 Kernel, 
 
 Ash, 
 
 Ash, 
 
 
 weight. 
 
 weight. 
 
 per cent. 
 
 
 weight. 
 
 weight. 
 
 per cent. 
 
 T 
 
 . . . . 0. ^ ^^4 
 
 0.0050 
 0.0053 
 
 1.50 
 1.57 
 
 
 ..0.2933 
 . .0.2797 
 
 0.004H 
 0.0046 
 0.0048 
 
 1 .64 
 1 .64 
 
 2, 
 
 . . . .0.3367 
 
 2. . . 
 
 3 
 
 . . . .0.3662 
 
 0.0059 
 
 1. 61 
 
 3-.. 
 
 ..0.2945 
 
 i^63 
 
 4- 
 
 . . . .0.3901 
 
 0.0061 
 
 1.56 
 
 4. . . 
 
 ..0.2551 
 
 0.0042 
 
 1.65 
 
 5- 
 
 ....0.3417 
 
 0.0057 
 
 1.67 
 
 5--- 
 
 . .0.3207 
 
 0.0051 
 
 1.59 
 
 6. 
 
 ... .0.3614 
 
 0.0061 
 
 1 .69 
 
 6... 
 
 . .0.3005 
 
 0.0049 
 
 1.63 
 
 7. 
 
 ... 0.3798 
 
 0.0065 
 
 1. 71 
 
 7... 
 
 ■ -0.3340 
 
 0.0056 
 
 1.68 
 
 8 
 
 . . . .0. 4030 
 
 . 0066 
 
 1.64 
 1 .64 
 
 8. . . 
 
 ..0.3144 
 ..0.3463 
 
 0.0052 
 0.0059 
 
 i^65 
 
 1 .70 
 
 9- 
 
 . . . .0.4446 
 
 0.0073 
 
 9. .. 
 
 10. 
 
 . . . . 4176 
 
 0.0071 
 -Ash = 1 . 10 
 
 1.74 
 1 percent. 
 
 10 
 
 . .0.3627 
 No. 4. — Ash 
 
 0.005S 
 = I . II p 
 
 I 60 
 
 
 Ear No. 3.- 
 
 Ear 
 
 er cent. 
 
 
 Kernel, 
 
 Ash, 
 
 Ash, 
 
 
 Kernel, 
 
 Ash, 
 
 Ash, 
 
 
 weight. 
 
 weight. 
 
 per cent. 
 
 
 weight. 
 
 weight. 
 
 per cent. 
 
 T 
 
 . . . .0. 263Q 
 
 0.0029 
 0.0028 
 
 I lO 
 
 I . . 
 
 . .0. 3080 
 
 0.0035 
 0.0043 
 
 1. 14 
 
 I^23 
 
 2. 
 
 0.2591 
 
 1.08 
 
 2. . . 
 
 ..0.3499 
 
 3- 
 
 ....0.2655 
 
 0.0029 
 
 1 .09 
 
 3... 
 
 ••0.3351 
 
 0.003S 
 
 1^13 
 
 4- 
 
 0.2887 
 
 0.0031 
 
 1 .10 
 
 4. . . 
 
 . .0.3422 
 
 . 0040 
 
 1. 17 
 
 5- 
 
 ....0.3077 
 
 0.0033 
 
 1.07 
 
 5--. 
 
 ..0.3970 
 
 0.0045 
 
 I.I3 
 
 6. 
 
 . . . .0. 3216 
 
 0.0035 
 
 1.09 
 
 6. .. 
 
 ..0.3514 
 
 0.0043 
 
 1.22 
 
 '7- 
 
 ....0.3363 
 
 0.0036 
 
 1.07 
 
 7... 
 
 ••0.3767 
 
 0.0047 
 
 1.25 
 
 8 
 
 . . . .0. ^476 
 
 0.0038 
 0.0042 
 
 1 . 10 
 
 8... 
 
 . .0.4186 
 ••0.4331 
 
 0.0050 
 
 1. 19 
 
 9- 
 
 ....0.3467 
 
 1 .21 
 
 9... 
 
 0.0048 
 
 1 .11 
 
 lO. 
 
 . . . .0.4042 
 
 0.0045 
 
 I . II 
 
 10. . . 
 
 . .0.4638 
 
 0.0051 
 
 1. 10 
 
 These results confirm those of the previous experiments in indicat- 
 ing uniformity in the composition of the ear in all parts, although slight 
 variations are found, of course. It may be noted, however, that the 
 variation from the average percentage is rarely equivalent to more than 
 three-tenths of a milligramme in the weight of the ash. 
 
 In the work on the protein content of single kernels, 5 ears, 3 of 
 which were high and two relatively low, in protein were selected from a 
 number of ears in a manner analogous to that described in the previous 
 experiment. 
 
 As duplicate determinations were not made with single kernels the 
 complete analytical data of this work are reported. 
 
 The water used in making up reagents and standard hydrochloric 
 acid and in the analytical process where needed had been twice distilled, 
 once with sulfuric acid, to free it from ammonia, and once with calcium 
 
156 HULLETIN NO. 53. \^/ulv, 
 
 hydroxid to remove carbon dioxid and volatile acids. In standardizing 
 the hydrochloric acid and ammonia solutions the same automatic 
 pipette and burette were employed as in the subsecpient analyses'. The 
 hydrochloric acid was standardized by means of silver nitrate, a method 
 whose details I have previously investigated'- and found to be exceed- 
 ingly accurate. Lacmoid indicator was used in standardizing the am- 
 monia, and chemically pure cane sugar was employed in making 
 "blank" determinations to find the "correction" for reagents. Follow- 
 ing are these data : 
 
 Standardizing hydrochloric acid. 
 35 cc.3 HCl gave i .4103 and i .4104 gms. AgCl. 
 
 Standardizing ammonia. 
 17.5 cc. HCl required 27.55 ^°d 27.55 cc. NH3. 
 
 Blank determinations with sugar. 
 17.5 cc. of standard hydrochloric acid were taken and to neutralize the excess 
 of acid required 
 
 27.47, 27.45, and 27.47 cc. of standard ammonia solution. 
 The atomic weights^ used are : CI = 35.453; Ag = 107.938; N = 14.041. The 
 factor, 6.25, was used to obtain the protein equivalent. 
 
 These data give 194933 as the logarithm (mantissa) for the weight 
 of protein equivalent to one cubic centimeter of standard ammonia. 
 
 In the following work 17.5 cc. of standard hydrochloric acid were 
 taken in each determination, and the volume of standard ammonia re- 
 quired to neutralize the excess of acid is given in the tables in cubic 
 centimeters : 
 
 Ear No. i. — Protein = 13.06 per cent. Ear No. 2. — Protein ^ 13. 87 percent. 
 
 Kernel, Ammonia to Protein, Kernel, Ammonia to Protein, 
 
 
 weight. 
 
 neutralize. 
 
 per cent 
 
 I . 
 
 . ..0.2945 
 
 25.12 
 
 12.46 
 
 2 . 
 
 . . .0.3127 
 
 24.96 
 
 12.54 
 
 3 
 
 . . .0.2893 
 
 25.16 
 
 12.44 
 
 4 
 
 . . .0.2991 
 
 25.07 
 
 12.50 
 
 5 
 
 ...0.3147 
 
 24.99 
 
 12 .30 
 
 6 
 
 . . .0.3162 
 
 24.94 
 
 12.49 
 
 7 
 
 ...0.3544 
 
 ^4-63 
 
 12.50 
 
 8 
 
 . . .0.3302 
 
 24.90 
 
 12. 14 
 
 9 
 
 . . . .0.3601 
 
 24.67 
 
 12. 14 
 
 10 
 
 ...0.3368 
 
 24-73 
 
 12.71 
 
 
 weight. 
 
 neutralize. 
 
 per cen 
 
 1 . 
 
 . .0.3206 
 
 24.97 
 
 12.17 
 
 2 . 
 
 . .0.3207 
 
 24.81 
 
 12.94 
 
 3 •■ 
 
 ..0.3094 
 
 24.99 
 
 12.51 
 
 4 
 
 . .0.2S41 
 
 24.97 
 
 13-42 
 
 5 • 
 
 ••0.3475 
 
 24-55 
 
 13.12 
 
 6 . 
 
 . .0.2899 
 
 24.76 
 
 14-59 
 
 7 • 
 
 ..0.2835 
 
 25.07 
 
 13.21 
 
 8 . 
 
 •■0.3475 
 
 24. 48 
 
 13-43 
 
 9 . 
 
 ..0.3179 
 
 24.79 
 
 13. 16 
 
 . 
 
 ..0.3301 
 
 24-50 
 
 14-05 
 
 ijf this precaution is observed, if the full measure of acid is always taken, and 
 if the graduation of the automatic ammonia burette is strictly uniform, there is no 
 special necessity for the apparatus to read absolute values. 
 
 ^Methods of Standardizing Reagents. — Master of Science Thesis, Cornell Uni- 
 versity, 1894. • 
 
 ^Twice the volume of the automatic pipette. 
 
 'Ostwald, Grundriss der allgemeinen Chemie (1890) 31. 
 
1898.] 
 
 CHEMISTRY OF THE CORN KERNEL. 
 
 157 
 
 Ear No. 3.— Protein = 12.96 percent. Ear No. 4.— Protein = 7.59 per cent. 
 
 
 Kernel, 
 
 Ammonia to 
 
 Protein, 
 
 
 Kernel. 
 
 Ammonia to 
 
 Protein 
 
 
 weight. 
 
 neutralize. 
 
 per cent. 
 
 
 weight. 
 
 neutralize. 
 
 per cent. 
 
 I . . 
 
 . . .0. 3626 
 
 24.79 
 
 11-53 
 
 I . 
 
 . . .0.2503 
 
 26.27 
 
 
 
 
 
 V-4,^, 
 
 2. . 
 
 ...0.3039 
 
 25.07 
 
 12.32 
 
 2. . 
 
 . .0.2432 
 
 26.29 
 
 
 7. ■54 
 
 3-. 
 
 ..•0.3353 
 
 24^85 
 
 12. 19 
 
 3-. 
 
 ...0.2383 
 
 26.29 
 
 
 7.69 
 
 4- • 
 
 . . .0.3048 
 
 25.02 
 
 12.54 
 
 4-. 
 
 . . .0.2118 
 
 26.45 
 
 
 7-47 
 
 5-- 
 
 •.0.3225 
 
 24.96 
 
 12. 14 
 
 5-- 
 
 . . .0.2752 
 
 26.10 
 
 
 7-74 
 
 (1. . 
 
 . ..0.3013 
 
 24.97 
 
 12.95 
 
 6.. 
 
 . . .0.2719 
 
 25.95 
 
 
 8.70 
 
 1 ■■ 
 
 . . .0.2635 
 
 25.30 
 
 12.84 
 
 7 • 
 
 . , .0.2758 
 
 25.97 
 
 
 8.46 
 
 S. . 
 
 . . .0.3204 
 
 Lost by accident. 
 
 8. . 
 
 . . .0.2703 
 
 25.96 
 
 
 8.69 
 
 9. . 
 
 . . .0 S2S4 
 
 24.96 
 
 12.04 
 
 9. 
 
 . . .0.2809 
 
 25.87 
 
 
 
 
 
 8.86 
 
 0. . 
 
 ..•0.3195 
 
 24. S6 
 
 12.75 
 
 10. . 
 
 .. .0.3133 
 
 25.84 
 
 
 8.10 
 
 
 
 Ear 
 
 No. 5 — Protein 
 
 = 8, 
 
 .40 per cent. 
 
 
 
 
 Kernel, 
 
 Ammonia to 
 
 Protein 
 
 
 Kernel, 
 
 Ammonia to 
 
 Protein 
 
 
 weight. 
 
 neutralize. 
 
 per cent. 
 
 
 weight. 
 
 neutralize. 
 
 per 
 
 cent. 
 
 I . . 
 
 . . .0.2819 
 
 26.07 
 
 7.72 
 
 6.. 
 
 . . .0.3002 
 
 25.78 
 
 
 8.76 
 
 2. . 
 
 . . .0.2682 
 
 26.02 
 
 8.41 
 
 I-- 
 
 . . .0.2730 
 
 25-91 
 
 
 8.89 
 
 3-- 
 
 . . .0.2378 
 
 26.19 
 
 8.37 
 
 8. . 
 
 . . .0.2830 
 
 25-83 
 
 
 9.02 
 
 4- • 
 
 . . .0.2641 
 
 26.06 
 
 8.31 
 
 9.. 
 
 ...0.2973 
 
 25.76 
 
 
 8.96 
 
 5-. 
 
 , . .0.2891 
 
 25. 98 
 
 8.02 
 
 10. . 
 
 . . .0.2821 
 
 25.86 
 
 
 8.89 
 
 The concordant evidence of 30 duplicate analyses of parts of 
 €ars, of 50 ash determinations, and of 50 protein determinations in 
 single kernels would seem to warrant the conclusion and to establish 
 the fact that the composition of the ear is approximately uniform 
 throughout. 
 
 Extended investigations, based upon tlie facts brought out in these 
 studies of the proximate composition of corn, are being continued by 
 the writer. 
 
 PART II.— THE COMPLETE COMPOSITION OF CORN. 
 HISTORICAL. 
 
 The Ash OF THE Corn Kernel. — The earliest analysis on record of 
 the ash of corn is evidently that made by De Saussure' reported in 1S04. 
 Following are his results: 
 
 Potash 14 . 00 
 
 Phosphate of potash 47 . 50 
 
 Chlorid of potash 0.25 
 
 Sulfate of potash 0.25 
 
 Earthy phosphates 36.00 
 
 Silica 1 . 00 
 
 Metallic oxids o. 12 
 
 Loss o . 88 
 
 ^Researches Chimiques sur la Vegetation, by Theod. De Saussure (1S04) 351; 
 Trans. N. Y. State Agr. Soc. (1S4S) 8, 727. 
 
158 HUIXETIN NO. 53. VJ"^y^ 
 
 Subsequently Letellier' reported the following analysis: 
 
 Magnesia 17.00 
 
 Lime i • 3° 
 
 Phosphoric acid 50 . 10 
 
 Silica o-8o 
 
 Sulfuric acid Trace 
 
 Potash, soda, and loss 30.80 
 
 As the later investigations will show, the analysis of Letellier gives 
 
 very approximately the true composition of corn ash. Much less 
 approximate are the analyses of Salisbury, of which he reported*^ several 
 similar to the following: 
 
 Silica 1.45 2.65 
 
 SO.J 0.21 0.13 
 
 P^O,, 50.96 49-31 
 
 Iron phosphate 4-35 0.75 
 
 Lime 0.15 0.45 
 
 Magnesia 16.52 15. 49 
 
 Potash 8.29 5.19 
 
 Soda 10.91 19. iS 
 
 NaCl 0.25 0.90 
 
 CI o.io 
 
 Organic acids 3.10 3.45 
 
 Coal 1.75 
 
 Later analyses by Liebig and Kopp'', Stepf^ Way and Ogston'', and 
 Bibra'' gave the following results: 
 
 Liebig Way and 
 
 and Kopp. Stepf. Ogston. Bibra. Bibra. 
 
 K.^O 30.74 28. 80 28. 37 24.33 26.75 
 
 NajO 3-50 1.74 1-50 3.85 
 
 MgO 14-72 14.90 13.60 16.00 15-24 
 
 CaO 3.06 6.32 0.57 3.16 2.56 
 
 Fe^Og 0.84 1-51^ 0.47 1. 88" 2.00** 
 
 P.Og 44.50 44.97 53.69 49.36 47.47 
 
 SO., 4-13 Trace. i.oo 1.20 
 
 SiOj 1.78 1.55 2.77 T.93 
 
 CI 0.50 .... 
 
 In 1880 Wolff-' gave the following as the average of 15 analyses of 
 the ash of corn: 
 
 ' Annalen der Chemie und Pharmacie (1844) 50, 403. 
 ■-'Trans. N. Y. State Agr. Soc. (1848) 8, 678. 
 ■'Jahresbericht iiber die Fortschritte der Chemie (1S56) 815. 
 'Journal fiir praktische Chemie (1859) 76, 88. 
 
 •"•Liebig's die Chemie in ihre Anwendung auf Agricultur (1865) 1, 384. 
 "Same reference. 
 ^And SO., and loss. 
 "And loss. 
 
 "Wolff's Aschen Analysen (1880); Thorp's Dictionary of Applied Chemistry 
 (1S90) 1, 497. 
 
1^9^-] CHEMISIRV ()|- THE CORN KERNEL. 
 
 159 
 
 K,0. 
 
 Na,0. 
 
 MgO. 
 
 CaO. 
 
 Fe.Og. 
 
 P.O„ 
 
 SO3 
 
 SiO.^ 
 
 CI. 
 
 29.8 
 
 I . I 
 
 15-5 
 
 2.2 
 
 0.8 
 
 45.6 
 
 0.8 
 
 2. 1 
 
 0.9 
 
 Quite recently Scovell and Peter have reported' a somewhat extended 
 investigation of the ash of corn with reference to its content of fertil- 
 izing elements. Following are the percentages of potassium oxid and 
 phosphoric oxid in the pure ash as found in 8 samples: 
 
 K,0. 
 
 P.O.,. 
 
 28.38 
 
 48.52 
 
 28.98 
 
 51. «5 
 
 29.41 
 
 52.45 
 
 29.38 
 
 52.75 
 
 K,0. 
 
 P.O.. 
 
 29.66 
 
 52.14 
 
 29.95 
 
 53.03 
 
 29.27 
 
 53-10 
 
 28.18 
 
 51.42 
 
 It seems evident that as a rule the ash of corn contains at least 95 
 per cent, of the phosphates of potassium and magnesium, about twice 
 as much potash as magnesia being present. 
 
 The Proteids of the Corn Kernel. — Zein, the most important 
 proteid in corn was discovered and named by Gorham in 182 1 (see 
 page 130), although he concluded from his investigations that it was not 
 a nitrogenous body. The zein was obtained by extracting with alcohol 
 the residue of powdered corn insoluble in water, 3.30 per cent, of 
 zein being found. By subsequent extraction of the corn with dilute 
 acid and alkali 2.75 per cent, of what was thought to be albumen were 
 obtained. 
 
 Soon after the publication of Gorham's work Bizio'-' reported an in- 
 vestigation of corn in which he claimed to have discovered the alcohol 
 soluble proteid, and, curiously enough, he states that he had named it 
 zei7i, from the Greek word meaning "nourishing substance" because 
 of the fact that it was a nitrogenous body. He points out several 
 differences between his zein and that which Gorham had found, and 
 mentions especially that in 1820 Configliachi'* had obtained ammonia 
 from zein by dry distillation. By means of ether Bizio extracted oil 
 from zein and then found that the residue was but partially soluble 
 in alcohol. These two portions, the one soluble and the other 
 insoluble in alcohol, he thought to be two different substances and 
 to be identical with the gliadin and zymom which Taddei* had found 
 in the gluten of wheat. He gives the alcoholic extract the following 
 composition: 
 
 Oil, soluble in ether 20.0 per cent. 
 
 Gliadin, soluble in alcohol 43.4 " 
 
 Zymom, insoluble in alcohol 36.0 " 
 
 •Kentucky Agr. Exp. Station Report (1891) 16. 
 'Journal fiir Chemie und Physik (1823) 37, 377. 
 =»Ibid. (1823) 37, 383. 
 'Ibid. (1820) 29, 514. 
 
l6o nULLETIN NO. 53. VJ>'h'-> 
 
 Salisbury' obtained "albumen" from corn by extracting with 
 water and coagulating by heat, and " casein " from the filtrate by 
 precipitating with acetic acid. He extracted zein and oil by means of 
 alcohol and separated them by evaporating the alcohol and extracting 
 the oil with ether. 
 
 Evidently because Berzelius' in commenting on Gorham's results, 
 had expressed the opinion that the zein of corn and the gluten of wheat 
 were identical, Stepf' assumed and stated incorreci/y that Gorham 
 claimed to have obtained zein by kneading corn meal with water, in the 
 same manner as gluten may be obtained from wheat; and he tried 
 repeatedly but in vain to accomplish such result. By extracting corn 
 with alcohol and purifying the extract by treating it with water and with 
 ether to remove sugar and oil, he states that he obtained pure zein very 
 similar to that obtained by Gorham. It was easily soluble in alcohol, 
 but by repeated solution and evaporation of the alcohol the zein was 
 partially changed into a modification insoluble in alcohol. Stepf called 
 the two modifications plant glue ( /^</;/2^;//r/w) and plant casein, sub- 
 stances already known. 
 
 Albumen was also obtained from an aqueous extract of corn by 
 coagulating with heat. The dry matter of corn was found to contain 
 0.7 per cent, of albumen and 7.5 per cent, of zein. Stepf further states 
 that from four closely agreeing determinations he found pure zein to 
 contain 15.6 per cent, of nitrogen. 
 
 In 1869 Ritthausen reported* an investigation of the proteids of the 
 corn kernel. Misled by Stepf's erroneous assumption, Ritthausen 
 vainly endeavored to obtain a cohering glutenous mass by kneading 
 corn meal with water. 
 
 Zein was obtained to the amount of 5 per cent, by extracting 
 ' powdered corn with alcohol and (A) by evaporating the alcohol and 
 extracting the residue with ether, or (B) by precipitating the zein in the 
 alcoholic extract by the addition of much ether. Zein was further puri- 
 fied (C) by repeated treatment with alcohol and ether, and (D) by dis- 
 solving in 0.1 to 0.15 per cent, potassium hydroxid solution, precipitating 
 with dilute acetic acid, redissolving completely'' in alcohol, and 
 precipitating with much water. 
 
 iTrans. N. Y. State Agr. Soc. (1S48) 8, 727. 
 
 '■'Jahresbericht viber die Fortschritte der physischen Wissenschaften (1823) 
 2, 124. 
 
 ^'Journal fiir praktische Chemie (1859) 76, 88. 
 
 'Journal fiir praktische Chemie (1869) 106, 471. 
 
 ■"'Ritthausen points out that this action shows zein to not consist in part of casein, 
 which would have formed an " alkali albuminate " insoluble in alcohol. 
 
1898.] CHEMISTRY OF THE CORN KERNEL. 1 6 1 
 
 Ultimate organic analyses of these four preparations gave the 
 following results: 
 
 A. B. C. D. Average. 
 
 Carbon 54.66 54.71 54.76 54.66 54.69 
 
 Hydrogen 7.45 7.50 7.57 7.51 7.51 
 
 Nitrogen 15.50 15.53 15-45 15-85 15.58 
 
 Sulfur 1 0.69 0.65 0.69' 
 
 Oxygen i 21.70 22.16^ 22.22 21.33 21.53 
 
 The fact may be noted that these results were not corrected for the 
 ash content of the zein, which it is stated was insignificant; and also the 
 more important fact that the nitrogen determinations of both Stepf and 
 Ritthausen were made by the method of Varrentrap and Will-' employing 
 the old atomic weights of platinum (197.2) and nitrogen (14). I have 
 recalculated their results using the revised atomic weights (Pt=i94. 8; 
 N= 14.041)* and find Stepf's average of four determinations to be 15.84 
 per cent, nitrogen and the average of Ritthausen's results'^ to be 15.82 
 per cent, nitrogen, in zein, while preparation (D) alone gives 16.10 per 
 cent, nitrogen. 
 
 By repeated solution in alcohol and evaporation of the solvent, 
 Ritthausen obtained zein which was insoluble in alcohol "dilute or 
 strong, warm or cold." He states positively that zein (or Maisfibrin, as 
 he prefers to call it) is not a mixture of proteid bodies but a single 
 homogeneous substance. 
 
 After the alcoholic extraction of the corn was complete, the residue 
 was extracted with 0.25 per cent, potassium hydroxid solution, and the 
 extracted proteids precipitated by acetic acid. About 0.5 per cent, of 
 substance was thus obtained from corn, which Ritthausen has since 
 referred® to as globulin. He gives the following as the composition of 
 the ash-free substance: 
 
 Carbon 5i-4i 
 
 Hydrogen 7 • ^9 
 
 Nitrogen 17-72 
 
 Oxygen and Sulfur 23.68 
 
 'Sulfur determination in (D) was not considered trustworthy. 
 
 ^Should be 22.26 evidently. 
 
 ^Annalen der Chemie und Pharmacia (1841) 39, 257. 
 
 ^Ostwald, Grundriss der allgemeinen Chemie (1890) 31. 
 
 "I have checked this recalculation from the weight of zein employed and of 
 platinum found as reported in Ritthausen's analytical data, and find that he used 
 atomic weights as stated above. 
 
 "Landwirtschaftliche Versuchs-Stationen (1S96) 47, 391. 
 
1 62 BULLETIN NO. 53 [/«d'> 
 
 In 1877 WeyP pointed out that a lo per cent, solution of sodium 
 chlorid extracted from the powdered corn kernel a globulin proteid 
 which coagulates at 75 . 
 
 The corn proteids soluble in sodium chlorid solution have been 
 very thoroughly investigated by Chittenden and Osborne- and the pre- 
 vious work on zein, the alcohol-soluble proteid, was carefully repeated. 
 
 With 10 per cent, sodium chlorid solution they extracted from 
 powdered corn about 0.5 per cent, of proteid matter from which they 
 were able to separate at least four different bodies now known'' as (i) 
 proteose, (2) very soluble globulin, (3) maysin (globulin), and {^)edesiin 
 (globulin). As the salt is removed from the solution by dialysis, the 
 maysin and edestin precipitate, the other bodies remaining in solution. 
 By long continued dialysis a part of the very soluble globulin is pre- 
 cipitated, the remainder (originally thought to be albumen by Chitten- 
 den and Osborne) being precipitated by hydrochloric acid. Of the 
 proteose, a part (also first called albumen) was obtained by coagulating 
 with heat, and the remainder was precipitated with alcohol. After re- 
 dissolving in salt solution the mixture of the two precipitated globulins, 
 maysin was separated from edestin by coagulating with heat, the 
 edestin being finally precipitated as the salt was removed by dialysis. 
 Other methods were also employed to separate these two globulins, 
 based upon the fact that maysin is readily soluble in extremely dilute 
 salt solutions, while edestin requires greater concentration of salt for 
 solution. 
 
 The averages of all analyses of each of these four proteids follow: 
 
 
 Proteose. 
 
 Very 
 
 soluble 
 obulin. 
 
 Maysin. 
 
 Edestin. 
 
 Carbon . . . 
 
 ...51-30 
 
 
 52.84 
 
 52.68 
 
 51.71 
 
 Hydrogen 
 
 . . 6.71 
 
 
 6.82 
 
 7.02 
 
 6.85 
 
 Nitrogen . 
 
 ...16.35 
 
 
 15.38 
 
 16.78 
 
 18.12 
 
 Sulfur. . . . 
 
 ... 2 . 00 
 
 
 1-37 
 
 1.30 
 
 0-86 
 
 Oxygen. . . 
 
 ...23.64 
 
 
 23-59 
 
 22.22 
 
 22.46 
 
 The different preparations of proteose and of the very soluble 
 globulin show some wide differences in composition which, it is believed, 
 are "simply due to their alteration by the process made use of" in their 
 separation. It was found "that these soluble bodies are exceedingly 
 prone to change." By the long continued action of water and salt 
 solutions an insoluble modification of variable composition was pro- 
 duced from maysin and the very soluble globulin. 
 
 'Zeitschrift fiir physiologische Chemie (1877) 1, 84. 
 ^American Chemical Journal (1891) 13, 453, 529; (1892) 14, 20. 
 ^Osborne, Conn. Agr. Exp. Station Report (1896) 20, 391. To avoid confusion 
 these terms are here used instead of ?nyostn, vitellin, etc. 
 
l8g8.] CHEMISTRY OF THE CORN KERNEL. 1 63 
 
 Following are the maxima and minima of the several constituents 
 determined in all analyses of proteose, very soluble globulin, and the 
 insoluble modification : \ 
 
 Very soluble Insoluble 
 
 Proteose. globulin. modification. 
 
 Carbon 52.06 to 50.07 53-531052.36 53-95 to 51.97 
 
 Hydrogen 6.91 " 6.54 6.90 " 6.74 7.05 " 6.90 
 
 Nitrogen 17.28 " 15.78 15.69 "15.16 16.82 " 15.87 
 
 Sulfur 2.37 '■ 1.62 1.48 " 1.26 1. 16 " 1. 12 
 
 The several analyses of both maysin and edestin agree within nar- 
 row limits. 
 
 After the extraction with salt-solution was completed, zein, the 
 most abundant proteid in the corn kernel, was obtained by extracting 
 with 75 per cent, alcohol at about 50=, and highly purified by repeated 
 solution in alcohol and precipitation with water, the last traces of oil 
 beitig removed by final extraction with ether. 
 
 By warming with water or very dilute alcohol zein was readily 
 changed into the insoluble modification. 
 
 Following is the composition of zein as shown by the averages of 
 several closely agreeing analyses of both the soluble and the insoluble 
 modifications: 
 
 Soluble zein. Insoluble zein. 
 
 Carbon 55.28 55- 15 
 
 Hydrogen 7-27 7-24 
 
 Nitrogen 16.09 16.22 
 
 Sulfur 0.59 o 62 
 
 Oxygen 20 . 77 20 . 77 
 
 The statement is made that "corn meal, after thorough extraction 
 with salt solution and warm dilute alcohol, yields little proteid matter 
 to dilute solutions of potassium hydroxid (0.2 per cent.)." 
 
 Osborne's more recent investigations^ have shown this assumption 
 to be very erroneous; and he now estimates such treatment to yield 
 3.15 percent, of proteid soluble inc. 2 per cent, potassium hydroxid 
 solution. It is noteworthy that this quantity is seven times the total 
 amount of the several proteids extracted by salt-solution. Analyses of 
 the purified preparation gave the following results : 
 
 Carbon 51 .26 
 
 Hydrogen 6.72 
 
 Nitrogen 15.82 
 
 Sulfur o . 90 
 
 Oxygen 25 . 30 
 
 iConn. Agr. Exp. Station Report (1896) 20, 391. 
 
164 BULLETIN NO. 53. \_/>'b'y 
 
 The quantities of the different proteids in the corn kernel are esti- 
 mated as follows : 
 
 1. Proteose, soluble in pure water 0.06 per cent. 
 
 2. Very soluble globulin 0.04 " 
 
 3. Maysin, soluble in extremely dilute salt-solutions 0.25 " " 
 
 4. Edestin, soluble in more concentrated salt-solutions. . .0. 10 " 
 
 5. Zein, soluble in alcohol 5.00 " " 
 
 6. Proteid matter, soluble in dilute alkalies 3-15 " 
 
 7. Proteid matter* insoluble in any of these solvents ....1.03 " 
 
 Osborne has calculateil the mean percentage of nitrogen in corn 
 proteids to be 16,057. 
 
 In a review of the percentages of nitrogen in tlie proteids of various 
 vegetable substances, Ritthausen'- places corn in the class with proteids 
 containing 16.67 per cent, of nitrogen, and uses the factor 6.00 for cal- 
 culating protein from the percentage of total nitrogen. It is observed, 
 however, that Ritthausen has misquoted his own results on the composi- 
 tion of zein, as will be seen from the following : 
 
 Original-'. As quoted. 
 
 Carbon 54.69 54-69 
 
 Hydrogen 7.51 7 . 56 
 
 Nitrogen 15.58 16.33 
 
 Sulfur o . 69 o . 69 
 
 O.xygen 21.53 21.53 
 
 An error of 0.05 appears in the hydrogen and of 0.75 in the nitro- 
 gen, and furthermore the total is 100.80, clearly showing that the 
 analysis is misquoted. His analysis of globulin is quoted correctly. 
 
 In this connection it is interesting to note that, if we take Ritt- 
 hausen's determinations of zein (containing 15.58 per cent, of nitrogen) 
 as 5.00 per cent, of the corn, and globulin (containing 17.72 per cent, 
 of nitrogen) as 0.50 per cent, of the corn, and recalculate the nitrogen 
 according to the revised atomic weights of platinum and nitrogen, 
 which show zein to contain 15.82 per cent, and globulin 17.99 per cent, 
 of nitrogen, we then find the mean percentage of nitrogen in the pro- 
 teids to be 16.02, which is practically identical with Osborne's result, 
 and proves conclusively that with our present knowledge we are to use 
 6.25 as the factor for estimating protein from the total nitrogen content 
 of corn. 
 
 The Carbohydrates of Corn. — Gorham and Bizio, to whose work 
 reference has already been made, separated sugar, gum, fiber, and 
 
 'Nitrogen in residue from 100 parts of corn multiplied by the factor 6.25. 
 '■'Landwirtschaftliche Versuchs-Stationen (i8g6) 47, 391. 
 ^Journal fiir praktische Chemie (1S69) 106, 4S3. 
 
1898.] CHEMISTRY OF THE CORN KERNEL. 1 65 
 
 Starch in the carbohydrate group, with the following results, the starch 
 being estimated by difference : 
 
 Carbohydrates. Gorham. \ Bizio. 
 
 Sugar 1. 59 0.90 
 
 Gum 1.92 2.29 
 
 Fiber 3.30 7.71 
 
 Starch 84.60 So. 91 
 
 In connection with his researches upon the starch content of many 
 vegetable substances including corn, Krocker' showed the absence of 
 appreciable amounts of sugar or dextrine in the ripe seeds of cereals. 
 Mitscherlich is quoted as having reached the same conclusion. 
 Krocker's method for determining starch was by hydrolysis and fer- 
 mentation, the amount of starch being calculated from the weight of 
 carbon dioxid liberated. In modern chemistry the relations are ex- 
 pressed by the following equations, in which the starch first takes up 
 water and is converted into glucose-sugar by the catalytic action of 
 acids: 
 
 C„HjoOg+H,0=C,H^30e 
 
 and then the sugar is decomposed into alcohol and carbon dioxid by 
 yeast, 
 
 C6Hi.,Oe=2C2HsOH+2CO,. 
 
 In case a measurable quantity of hexose-sugars were present it was 
 determined by fermentation previous to the hydrolysis of the starch. 
 
 Duplicate determinations on a sample of corn containing 14.96 per 
 , cent, of water gave the following results: 
 
 Corn taken 3.35 2.98 gms. 
 
 Carbon dioxid found i .02 0.92 
 
 Starch equivalent 1-877 1.693 
 
 Starch in dry matter 65.88 66.80 percent. 
 
 Aside from the determination of fiber as commonly made and reported 
 in proximate analyses and Atwater's estimation of sugar (see page 134), 
 nothing further of importance concerning the chemical composition of 
 the carbohydrates of corn is found until 1887, when Archbold'- gives the 
 following percentages of different carbohydrates in corn, as representing 
 "the average of many samples analyzed in the course of one year's 
 working " in a large starch factory: 
 
 Water 1 1 . 20 Dry 
 
 Starch 54.80 61.71 
 
 Cellulose 16.40 18.47 
 
 Gum and sugar 2 . 90 3.27 
 
 ' Annalen der Chemie und Pharmacie (1S46) 58, 212. 
 ^Journal Society Chemical Industry (1887) 6, 84 
 
l66 HULLETIN NO. 53. [/''^'j 
 
 Archbold's report shows' that 55.6 per cent, of starch are actually 
 obtained from corn (dry basis) in the commercial process of starch 
 manufacture, and that several different by-products still contain traces 
 of starch. 
 
 In 1889 \Vashburn~ reported an investigation of the cane sugar con- 
 tent of corn. By extracting 1400 gms. of ordinary field corn, to which 
 3 gms. of magnesia had been added to prevent possible inversion of 
 sugar, with 72 per cent, alcohol, shaking the solution with ether to 
 separate fat, and purifying the sucrose in the filtered aqueous layer by 
 repeated precipitation as strontium sucrate and decomposition of the 
 precipitate by carbon dioxid (method of Schultze''), 1.105 gms. of pure 
 cane sugar were obtained by crystallization. American sweet corn 
 yielded larger amounts, 10.5 gms. of sugar being obtained from 2000 
 gms. of corn. Washburn states that all of the sugar in the corn is not 
 obtained by this process. 
 
 Marcacci'* has found over i per cent, of sugar in corn. 
 
 Pentosans (CsH^jO^), which are also termed wood gi/i?i and heini- 
 ceilulose, were found in corn by Stone''. These carbohydrate bodies* 
 yield pentoses (CjHioOr,), also caWtd penia glucoses, by hydrolysis with 
 dilute acids (C.HxO^+H^O^C^HioO,), and furfurol (CjH.O,) by dis- 
 tillation with moderately concentrated acids (CjHioOs — 3HoO = C5H40.,), 
 reactions which serve as a basis for their quantitative determination. 
 Either the pentose is determined by Fehling's method'^ for reducing 
 
 'Based upon si.x years' experience as chemist to a starch factory. 
 
 •■'Uber den Rohrzucker des Maiskorns, etc, —Inaugural Dissertation zur 
 Erlangung der Doctorwiirde, — Gottingen (1S89); Journal fiir Landwirtschaft (1889) 
 37, 503. 
 
 ■'Landwirtschaftliche Versuchs-Stationen (1S87) 34, 403. 
 
 ^Le Stazioni Speriment, Agrar. Ital. (i88g) 17, 266; Central-Blatt fiir Agri- 
 cultur-Chemie (i8go) 19, 352. 
 
 'American Chemical Journal (1891) 13, 73. 
 
 •^Tvvo pentosans are well known: Xylan, found quite commonly in grains and 
 grasses; and araban, occurring especially in gums such as arabic, tragacanth, cherry, 
 etc. Xylan and araban have the same empirical molecular formula, but they 
 may be distinguished by the difference in the specific rotation and melting points of 
 the respective pentoses, xylose and arabinose, into which they are converted by 
 hydrolysis. For xylose [a]D = i8° to 19° and M. P. = 144° to 145°; while for 
 arabinose [a]D = io3° to 105° and M. P. ^154° to 157°. C£. Koch, Pharmaceutische 
 Zeitschrift fijr Russland (1886) 25, Gig and other pages; Berichte der deutschen 
 chemischen Gesellschaft {1887) 20, III, 145; Bauer. Landwirtschaftliche Versuchs- 
 Stationen (1889) 36, 304; Stone and Tollens, Annalen der Chemie (1888) 249, 227; 
 Wheeler and Tollens, ibid. (1889) 254, 304; Schulze, Zeitschrift fiir physiologische 
 Chemie (1890) 14, 227; (1892) 16, 387; (1894) 19, 38. 
 
 ^Bauer, Landwirtschaftliche Versuchs-Stationen (i88g) 36, 304; Stone, Ameri- 
 can Chemical Journal (i8gi) 13, 78. 
 
1898.] CHEMISTRY OF THE CORN KERNEL. 1 67 
 
 sugars; or the furfurol is determined, preferably by precipitation with 
 phenyl hydrazine as a hydrazone (CsH^ONaHCgH,,)^ 
 
 Stone found corn bran to contain 1.25 to 2.67 per cent, of pento- 
 sans.- Schuize/ after separating considerable other matter from corn 
 bran, obtained a residue which yielded 43.37 per cent, of a pentosan 
 which he showed to be xylan.* 
 
 In 1896 Stone" reported a somewhat extended study of the carbo- 
 hydrates of corn, in which sucrose, dextrine, starch, pentosans, and 
 fiber were determined quantitatively. The general method employed 
 may be briefly described as follows: 
 
 Sucrose. — Finely ground corn meal was extracted with 95 per cent, 
 alcohol which was then evaporated nearly to dryness, the residue taken up 
 with water, treated with hydrochloric acid, the inverted sugar estimated 
 by Fehling's solution and calculated to sucrose. 
 
 Dextrine. — The residue of meal was extracted with cold water which 
 was then evaporated to a small volume, the dextrine being precipitated 
 by alcohol, inverted by hydrochloric acid, and estimated by Fehling's 
 solution. 
 
 Starch. — A known proportion of the residue of meal was treated 
 with malt extract, the solution hydrolysed and the sugar obtained 
 estimated by Fehling's solution, and calculated to starch. 
 
 Pentosans. — The residue from the starch determination was boiled 
 with I per cent, hydrochloric acid, the pentose formed estimated by 
 Fehling's solution and calculated to xylan. 
 
 Fiber. — The residue still remaining was boiled with 1.25 per cent, 
 sodium hydroxid, and the insoluble matter (less ash) given as fiber. 
 
 A sample of corn which contained 80.69 per cent, of total carbo- 
 hydrates, when estimated "by difference," gave by the above method 
 the following results: 
 
 Sucrose 0.27 per cent. 
 
 Dextrine 0.32 
 
 Starch 42.50 
 
 Pentosans 5.14 
 
 Fiber 1-99 
 
 Total carbohydrates 50 . 22 
 
 iplint and ToUens, Landwirtschaftliche Versuchs-Stationen (1893) 42, 381. Cf. 
 Berichte der deutschen chemischen Gesellschaft (1891) 24, II, 3575; (1892) 25, II, 
 
 2912. 
 
 •^The results were published (American Chemical Journal (1891) 13, 73) in terms 
 of furfuramid, but are here calculated to pentosan. 
 
 •'Zeitschrifl fiir physiologische Chemie (1894) 19, 41. 
 
 •The statement by Stone (U. S. Dept. of Agr., Exp. Station Bui. (iSg6) 34, 16) 
 that Tollens and Flint (Berichte der deutschen chemischen Gesellschaft (1892)25, II, 
 2916) had estimated the amount of pentosans in corn bran to be 38.17 per cent, 
 appears to be erroneous, as the work referred to was with corn cobs (MaiskolbenJ . 
 
 ■"•U. S. Dept. of Agr., Exp. Station Bui. (1896) 34. 
 
1 68 BULLETIN NO. 53. S^July, 
 
 In discussing his results, Dr. Stone says: 
 
 " This method not only permits the separation of the more delicate and easily 
 decomposed carbohydrates from those which offer greater resistance to- reagents, but 
 from the very beginning of the process any carbohydrate not wholly removed at any 
 particular step would hardly fail of being detected at the next succeeding and more 
 searching reaction. It is considered pertinent to the subject under discussion to call 
 attention to the apparent discrepancy between less than 50 percent, of carbohydrates 
 found in our most prominent cereal grains by direct and fairly accurate methods of 
 determination and the 70 to 80 per cent, commonly ascribed to them by the indirect 
 method of estimating ' by difference.' From 20 to 30 per cent, of the grain or flour 
 is not accounted for. Under the conditions this matter cannot be conceived of as 
 possessing a similar nature to the sugars, starches, or even the more easily soluble 
 forms of gum or celluloses " 
 
 Whenweremember that Krocker had shown (see page 165) by a direct 
 and positive method that corn contains over 65 per cent, of ferment- 
 able^ carbohydrates (at least almost entirely starch), and that Archbold, 
 from long experience in the manufacture of corn-starch, reports over 
 60 per cent, of starch present in corn and at least 55 per cent, actually 
 recovered in the commercial process (see page 166), the previously exist- 
 ing evidence of an error in Stone's results is apparent. Dr. Stone has 
 subsequently discovered and reported' a large error in the starch de- 
 termination, due to the use of too dilute hydrochloric acid and 
 consequent imperfect hydrolysis. The percentage of starch is now 
 given as 65.45 instead of 42.50 as first reported. The total carbo- 
 hydrates thus found by determination become 73.17 per cent, as 
 compared with 80.69 per cent, estimated by difference. Dr. Stone 
 concludes that: 
 
 "This discrepancy may arise from one of two sources, cviz. ; i. Error in the 
 determination of the carbohydrates. 2. The existence of a substance which is free 
 of nitrogen and is of a character not usually ascribed to carbohydrates and resistant 
 to the ordinary reactions for such. While the first alternative is not excluded, the 
 writer is inclined to the latter conclusion and expects to continue the investigation 
 along this line." 
 
 In a recent report of extended investigations of methods for the 
 estimation of starch, Wiley and Krug^ refer to their experiments with 
 the conversion of starch into maltose and dextrine by the use of malt 
 extract, as follows: 
 
 " The residues from the diastase digestion were all thoroughly washed with hot 
 water and then examined with iodine under the microscope. In every case a large 
 number of cells was found which contained undigested starch, showing that the 
 sample^ had not been ground to a sufficient degree of fineness. This is, therefore. 
 
 'The pentosans are classed as strictly non-fermentable carbohydrates. Cf. 
 Koch, Pharmaceutische Zeitschrift fiir Russland (1886) 25; Stone and ToUens, 
 Annalen der Chemie (1888) 249, 257; Stone, American Chemical Journal (1891) 13, 82. 
 
 ^Journal American Chemical Society (1897) 19, 183, 347. 
 
 ^Ibid. (i8g8) 20, 255. 
 
 'A sample of wheat previously analyzed by Stone. 
 
1898.] CHEMISTRY OF THE CORN KERNEL. 1 69 
 
 another source of error in Professor Stone's work. The sample was then reground 
 
 and the starch determined The residues were again examined and in every 
 
 case found free from starch, showing that the conversion had been complete. . 
 
 The number for starch thus obtained, added to our per cenfs. of the other con- 
 stituents gives us a total of 99.28." 
 
 In summarizing their results Wiley and Krug express the following 
 opinion: 
 
 "The small quantity of matter unaccounted for in the cereal grains is doubtless 
 of a carbohydrate nature, belonging to that complex class, pentosan-ligno-celluloses, 
 whose chemical and physical properties are so nearly alike as to make their exact 
 separation and determination extremely difficult. The quantity of these undeter- 
 mined bodies in cereal grains is very minute." 
 
 The Oil of Corn. — The presence of oil in the corn kernel was dis- 
 covered by Bizio' in 1823. A partial analysis by Hoppe-Seyler'-' gave 
 the following as the percentage composition'' of the oil: 
 
 Cholesterol 2 . 65 
 
 Protogon 3.95 
 
 Saponifiable fats etc 93 • 40 
 
 The statement is made that the oil contains stearin, palmitin, and 
 much olein, and the melting point of the fatty acids is given as 51° to 
 54° F. [ii°] to 12° C.]. 
 
 Some of the so called physical and chemical " constants," which 
 have been determined by several investigators are given below: 
 
 Specific gravity Unsaponifiable lodin 
 
 of oil. substance. absorption, 
 
 (at i5°C.) (per cent.) (per cent.) 
 
 Spiiller^ 1.35 119. 7 
 
 Smith-^ 0.9244 .... 122. 9 
 
 Hart^ 0.9239 1.55 117. o 
 
 Rokitianski^ 0.8360 .... 75-8 
 
 The oil used by Spiiller was the ordinary ether extract. Rokitianski 
 used a petroleum ether extract. Hart worked with a "dark brown" 
 sample presumably found on the market. Smith's material was obtained 
 on the market, but was of a " bright golden color" and was probably 
 a fair sample of corn oil. 
 
 'Journal fiir Chemie und Physik (1823) 37, 377. 
 
 ^Medicinische-Chemische Untersuchungen, 1, 162; Bulletin Socit'te Chimique 
 de Paris (1866) [2] 6, 342; Jahresbericht iiber die Fortschritte der Chemie (1866) 698. 
 
 ^I have not been able to see Hoppe-Seyler's original paper. Presumably the 
 protogon is the substance now termed lecithin, and the methods employed in esti- 
 mating it and cholesterol were similar to those which are discussed herein. 
 
 ^Polytechnisches Journal (Dingier) (18S7) 264, 626. 
 
 •"'Journal Society Chemical Industry (1892) II, 504. 
 
 eibid. (1894) 13, 257, from Chem. Zeit. 17, 1522. 
 
 ''Inaugural Dissertation, St. Petersburg (1894); Pharmaceutische Zeitschrift fiir 
 Russland (1894) 33, 712; Chemisches Central-Blatt (1895) [4] 7, I, 22. 
 
IJO BULLETIN NO. 53. V/"^}'' 
 
 SpiiUer observed that the oil absorbed no oxygen from the air 
 even after fourteen days' exposure. Smith states that the freezing point 
 of the oil is below — 20^. Hart gives the melting point of the fatty 
 acids as 25-. Rokitianski reports further qualitative chemical work 
 which showed the oil to contain oleic and linolic acids. It is evident 
 from the specific gravity and the iodin absor})tion that the material with 
 which he worked was not ordinary corn oil. 
 
 Willey and Bigelow' have recently found the heat of combustion of 
 oil of corn to be 9280 calories per gramme. 
 
 EXPERIMENTAL. 
 
 In a preliminary study a small amount of oil was obtained by 
 collecting the ether extract from a large number of proximate analyses 
 of corn. In this, advantage was taken of the fact that the oil is moder- 
 ately soluble in alcohol when hot and but slightly so at ordinary temper- 
 atures.'^' 
 
 The oil was transferred from the small flasks, used in its extraction, 
 by means of hot alcohol to a single vessel. On cooling the oil precipi- 
 tated and settled to the bottom, the alcohol being each time decanted 
 from the collected oil and used in transferring the next lot. Finally 
 the alcohol was evaporated and the oil dried to constant weight in a 
 water oven. When freshly obtained from white dent corn the oil is 
 nearly colorless, but on standing a pale yellow and finally a deep golden 
 color develops, plainly indicating a gradual change in its condition, 
 presumably due to absorption of oxygen. This was confirmed by deter- 
 mining the iodin absorption which was found to be 115. 5- per cent. 
 
 A large quantity of corn oil, including samples from four different 
 sources'*, was then secured in order to make a more thorough investiga- 
 tion. The oil is obtained as a by-product in the manufacture of corn- 
 starch and glucose-sugar, and all of the samples secured were of a pale 
 straw color and evidently fresh and pure. 
 
 Specific Gravity. — Three of these samples of corn oil were sufficient 
 
 in cjuantity to enable me to make determinations of their specific gravity 
 
 by means of a delicate Westphal balance which by trial gave the specific 
 
 gravity of pure water at 15 - as i.oooo. The samples of oil gave the 
 
 following results: 
 
 X. 2. 3. 
 
 Specific gravity ... . (15') 0.9245 0.9262 0.9258 
 
 1 Journal American Chemical Society (iSgS) 20, 309 
 
 '-'Smith has found the solubility of corn oil in alcohol by volume to be 2 per 
 cent, at 16° and 13 per cent, at 63°. 
 
 ^Samples of corn oil were very kindly furnished me by President Wm. F. Piel, 
 Jr., of The National Starch Manufacturing Company, New York City; by The Chas. 
 Pope Glucose Company, Geneva, 111.; by The Glucose Sugar Refining Company, 
 Chicago; and by Messrs, Elbert and Gardner, New York City. 
 
1898.] CHEMISTRY OF THE CORN KERNEL. 17I 
 
 Melting Point. — Preliminary experiments confirmed the observation 
 of Smith that the oil is still fluid at — 20 , a temperature of — 23-^ 
 (obtained with snow and concentrated sulfuric acid) failing to solidify 
 the oil. It was found, however, that the oil became hard and solid at 
 about — 36°. 
 
 The melting point was determined by a modification of the method 
 of the Association of Official Agricultural Chemists'. 
 
 In a tall beaker of about 2.5 liters capacity was placed a small 
 quantity of concentrated sulfuric acid (to absorb water vapor so that 
 the apparatus would remain transparent at low temperatures). A second 
 beaker of about 2 liters capacity was placed in the first, being sup- 
 ported by the rim without touching the bottom. A i -liter beaker taller 
 than the second was placed in the latter and filled with alcohol, the 
 space between the two being filled with solid carbon dioxid. A glass 
 tube 30 mm. in diameter and closed at the bottom was fitted into the 
 inner beaker with a large cork, the tube being about one-third filled 
 with a mixture of 1 volume of concentrated sulfuric acid and 3 volumes 
 of absolute alcohol, and then nearly completely filled with absolute 
 alcohol. The temperature of the alcohol in the beaker was kept 
 uniform throughout by constant stirring with a wire which passed 
 through the cork and terminated in a ring surrounding the glass tube. 
 A heavy glass spoon and a glass spatula were placed in the alcohol. 
 
 When the temperature reached — 50°, the spoon was removed and 
 a drop of the oil at once let fall upon it. A thin, solid, white, opaque 
 disc formed and was quickly made to drop into the inner tube by using 
 the glass spatula. The disc of solidified oil settled through the absolute 
 alcohol to the denser liquid below and there remained in suspension. 
 
 The beaker which had contained carbon dioxid was replaced by 
 another and the temperature allowed to slowly rise. An alcohol ther- 
 mometer was used for reading the temperatures below the freezing 
 point of mercury. Above — 38 a delicate mercury thermometer was 
 employed. 
 
 As the temperature rose the disc remained unchanged until at — 19^ 
 it began to lose its opacity. At — 14° it had become perfectly trans- 
 parent, but no change in shape could be detected below — 7^. The 
 disc was much contracted and thickened at — 5^ and became entirely 
 symmetrical in form at — 2.3 ". A second determination gave practically 
 the same results, the final reading being — 2.4 . The change in temper- 
 ature (when near the melting point) required 5 to 6 minutes for one 
 degree. 
 
 To determine the change in the consistency of the oil, a thin-wall 
 tube of 8 mm. diameter, closed at the bottom, and containing i cm. of 
 
 lU. S. Dept. of Agr., Div. of Chem. Bui. (1895) 46, 34. 
 
172 I'.UI.LETIN NO. 53. \_J>'ly^ 
 
 the oil, was placed in alcohol at — 45 . After the oil had become solid a 
 glass rod 20 cm. long and 2 mm. thick (the lower end being widened to 
 5 mm. diameter) was placed in the tube so that its weight was entirely 
 supported by the solidified oil. At — 13° the oil had become trans- 
 parent but still supported the rod. At — 10 the rod began to settle 
 appreciably and at — 9 ' it had passed through the centimeter of oil to 
 the bottom, although a disc of oil suspended beside the tube in the 
 same liquid had not changed appreciably in shape. The change of 
 temperature from — 10 to — 9" required 5 minutes. 
 
 lodin Absorptioti. — The method of Hiibl' was employed for this 
 determination, except for certain details of the process. 
 
 Standard sodium thiosulfate solution was prepared by dissolving 
 47.2 gms. of the crystallized salt (Na^ S.^O..; sH.^O) in water and diluting 
 to 2-liters. From theory i cc. of this solution should be equivalent to 
 12.06 mgs. of iodin if the salt were pure'\ The solution was standard- 
 ized with resublimed iodin with the following results: 
 
 Iodin taken ... 0.5160 0.5574 g^is. 
 
 Thiosulfate solution required 42.9 46.4 cc. 
 
 Iodin equivalent to I cc 12.03 12.01 mgs. 
 
 The average of these results, 12.02, was used in the following 
 work: 
 
 The iodin solution, containing 50 gms. iodin and 60 gms. mercuric 
 chlorid in 2 liters of alcohol, was standardized whenever used. 
 
 Little j)ipettes of about 0.5 cc. capacity were placed in 5 cc. vials 
 nearly filled with the corn oil, the bulb of the pipette being immersed, 
 and the whole weighed. The measure of oil was then transferred to a 
 500 cc. glass stoppered bottle, the pipette returned to the vial, and the 
 exact weight of oil taken determined by difference. The duplicate is 
 taken immediately and necessitates only one more weighing. 10 cc. of 
 chloroform and 40 cc. of iodin solution were added to the oil. After 
 2 hours 25 cc. of 10 per cent, potassium iodid solution and about 125 
 cc. of water were added and the excess of iodin determined by titrating 
 with the sodium thiosulfate solution, starch indicator being added near 
 the close of the reaction. 
 
 Duplicate determinations of four different samples of oil from as 
 many different sources gave the following results: 
 
 'Journal Society Chemical Industry {18S4) 3, 641. 
 
 '■'Sutton's Volumetric Analysis, (1890) 115, states that standard sodium thiosul- 
 fate solution may be made by simply dissolving an exact weight of the crystallized 
 salt, Naj S2O3 5H2O, in water and diluting to a definite volume. 
 
CHEiMISTKV or I'llE CORN KERNKL. 
 
 173 
 
 Oil taken, 
 gms. 
 
 lodin absorbed, 
 gms. 
 
 lodin absorbed 
 per cent. 
 
 < 0.3473 
 
 ( 0.3844 
 
 0.4255 
 0.4729 . 
 
 122.5 
 123.0 
 
 S 0.4251 
 I 0.4714 
 
 0.5179 
 0.5729 
 
 121. 8 
 121. 5 
 
 \ 0.4281 
 '( 0.4742 
 
 0.5212 
 0.5772 
 
 121 .7 
 121.7 
 
 j 0.4326 
 ( 0.516S 
 
 0.5324 
 0.6351 
 
 123. 1 
 122.9 
 
 Oxygen Ahsorptio7i.-—\\\ order to afford a large surface for the 
 absorption of oxygen, the oil was placed in a low crystallizing dish of 
 75 mm. diameter. This was allowed to stand at the room temperature, 
 the weight of the oil being determined from time to time as follows: 
 
 Weight of oil taken 2 . 1732 gms. 
 
 Weight after i day 2 . 1722 
 
 7 days 2.1718 
 
 " II " 2.1718 
 
 12 " 2.1718 
 
 These results confirm those of SpiiUer, showing that the oil does 
 not take up oxygen under these conditions. 
 
 The dish was then placed in a water oven and the following data^ 
 obtained: 
 
 Weight after i hour 2.1726 gms. 
 
 I day 2 . 1996 
 
 " " 2 days 2 . 24SS 
 
 2.2590 
 2.2588 
 2.2558 
 2.2513 
 2.2448 
 
 The first action of air upon the hot oil is evidently the direct addi- 
 tion of oxygen; but after 2 or 3 days the oil began to turn noticeably 
 darker in color and finally to lose weight, evidently due to a secondary 
 reaction which effects some decomposition of the oil with formation of 
 volatile products. 
 
 Lecithiiv. — A weighed quantity of oil was mixed with potassium 
 nitrate and sodium carbonate in a platinum dish and ignited until the 
 carbon was completely burned. The fused mass was dissolved in dilute 
 
 iThese results emphasize the importance of avoiding the presence of oxygen in 
 drying corn or corn oil in analytical work. 
 
 -Lecithin is commonly regarded as a compound of the base, neurine, with di- 
 stearyl-glycero-phosphoric acid, although one or both of the stearic acid radicals may 
 be replaced by radicals of palmitic or oleic acid, and the neurine (trimethylhydroxy- 
 ethyl ammonium hydroxid) is sometimes replaced by another base; e. g., betaine. 
 
174 r.ULLi<:TiN no. 53. \_J"^yy 
 
 hydrochloric acid, and the total phosphoric acid determined'. The 
 amount of lecithin was calculated by multiplying the weight of mag- 
 nesium pyrophosphate obtained by the factor 7.25''. Duplicate deter- 
 minations gave the following results : 
 
 Oil taken 10.728 6.435 gnis. 
 
 KNO3 used'-' 10. o 35.0 
 
 Mg-.P-.O^ obtained 0.0221 0.0132 
 
 Lecithin o. 1602 0.0957 " 
 
 Lecithin in oil ' 1.49 i-49 percent. 
 
 CJiolestt-rol'. — To determine cholesterol'' about 50 gms. of the oil 
 were saponified on the water bath with 20 gms. of potassium hydroxid 
 and 100 cc. of 70 per cent, alcohol. The soap was transferred to a 
 large separatory funnel with 200 cc. of water and shaken first with 500 
 cc. of ether and then 3 times with 250 cc. of ether. The four portions 
 of separated ether were combined, and the ether distilled, the residue 
 being resaponified with 2 gms. of potassium hydro.xid and jo cc. of 70 
 per cent, alcohol. The solution was then transferred to a small sep- 
 aratory funnel with 20 cc. of water and shaken with 100 cc. of ether. 
 After separating the aqueous layer the ether solution was washed four 
 times with 10 cc. of water, the ether solution being finally transferred 
 to a weighed flask, the ether distilled and the weight of the dry residue 
 (cholesterol) determined. Three determinations gave the following 
 results : 
 
 Oil taken 50.16 5J.5o 54-24 gms. 
 
 Cholesterol obtained 0.7002 0.7114 0.7512 
 
 Cholesterol in oil i . 40 1.33 i • 38 ' per cent'' 
 
 The cholesterol was recrystallized from absolute alcohol in charac- 
 teristic glistening plates, melting at 137 to 137.5^. It also gave the 
 characteristic color reactions'* for cholesterol : i, when shaken with 
 chloroform and sulfuric acid; 2, when evaporated to dryness with 
 nitric acid; 3, when warmed with hydrochloric acid and ferric chlorid. 
 
 'Cf. Hoppe-Seyler, Jahresbericht uber die Fortschritte der Chemie (1S66) 744; 
 Schulze and Frankfurt, Landwirtschaftliche Versuchs-Stationen (1893) 43, 207. 
 
 -'7.25 parts of lecithin (C., JI„„0,,PN)yield i part of Mg., P. O7, 
 
 ='The proportions of KNO„ used were purposely varied, but the results indicate 
 that the smaller proportion was sufficient. 
 
 'By extracting corn with ether and alcohol, successively, Schulze and Frank- 
 furt (reference above) have obtained amounts of phosphoric acid equivalent to 0.25 
 to 0.28 per cent, of lecithin in the corn. 
 
 ■'•A monatomic alcohol, C^gH, .,OH. 
 
 '•Cf. Bcimer, Zeitschrift fiir Untersuchung der Nahrungs- und Genussmittel 
 (1898) 21, for recent work on the details of this method. 
 
 'Spiiller had obtained 1.35 percent, and Hart 1.55 per cent, of unsaponifiable 
 matter. 
 
 "Watt's Dictionary (1X89) 2, 147. 
 
1898.] CHEMISTRY OF THE CORN KERNEL. I 75 
 
 Total Faify Acids. — After removing the cholesterol from about 50 
 gms. of oil the remaining soap solution (about 500 cc.) was acidified 
 with hydrochloric acid and shaken in a separatory/unnel. An ethereal 
 layer of about 150 cc. at once separated. After adding 100 cc. more 
 ether and thoroughly shaking, the aqueous layer was drawn off, the 
 ether solution of the fatty acids was washed with several portions of 
 water and then transferred to a weighed flask, the ether distilled off, a 
 few cubic centimeters of absolute alcohol dissolved in the residue and 
 evaporated to remove traces of water, ami the weight of the total fatty 
 acids determined : 
 
 Oil taken 50 . 160 gms. 
 
 Fatty acids obtained 46 . 935 
 
 Fatty acids in oil 93-57 per cent. 
 
 The fatty acids form a solid mass at 15°, but melt nearly com- 
 pletely at one or two degrees above, the last particles of solid disap- 
 pearing at 23°. Prepared as described the fatty acids absorbed only 
 126.4 psr cent, of iodin instead of 130. 7 per cent, as calculated from the 
 iodin absorption of the oil. This indicates that oxygen had been ab- 
 sorbed by the acids during the process of separation. It was found that 
 oxygen is slowly absorbed by the fatty acids while standing in a desic- 
 cator at the ordinary temperature. Kt 100° the absorption is much 
 more rapid although, as with the oil, secondary reactions soon begin at 
 the higher temperature. The change in weight was found to be as 
 follows : 
 
 Time, Weight of fatty acids, gms., 
 
 in days. in desiccator. in water oven. 
 
 o 1 . 9685 2 . 2740 
 
 I 1 .9692 2.3106 
 
 2 1. 9717 2.3366 
 
 3 1-9777 2.3366 
 
 4 1.9847 2.3282 
 
 8 2.0231 
 
 12 2.0665 
 
 16 2. 091 1 
 
 22 2. 1 157 
 
 28 2.1293 
 
 34 2.1297 
 
 All action apparently ceased after about one month's time. A con- 
 siderable portion of the fatty acids had separated in the solid form and 
 of a pure white color, while the other portion remained a colorless, 
 oily liquid. 
 
 It is of interest to note the apparent relation between the iodin 
 absorption and the oxygen absorption by the fatty acids. As already 
 shown the fatty acids as prepared absorbed 126.4 per cent, of iodin. 
 If an equivalent amount of the bivalent oxygen may be absorbed instead 
 
176 BULLETIN NO. 53. [^'^^j 
 
 of the univalent iodin, then 8.0 per cent, of oxygen should be taken up. 
 The results show that 1.9685 gms. of the fatty acids absorbed 0.1612 
 gms. of oxygen, an amount equal to 8.2 per cent. 
 
 Time would not permit the preparation of the fatty acids in a 
 manner which would prevent the absorption of oxygen during the 
 process, and then a repetition of the quantitative determination of the 
 absorption. This is especially desirable in order to confirm the results 
 as given above, and the writer expects to investigate this point more 
 fully in the near future. 
 
 Volatile Acids. — About 5 gms. of oil were saponified in a 500 cc. 
 flask with 2 gms. of potassium hydroxid and 40 cc. of 80 per cent, 
 alcohol. After evaporating the last of the alcohol, 100 cc. of recently 
 boiled water were added, the soap solution acidified with 40 cc. of dilute 
 sulfuric acid (i to 10), a few pieces of freshly ignited pomace stone 
 added, the flask connected with a condenser by means of a safety bulb 
 tube, and no cc. of distillate collected. After mixing, 100 cc. were 
 passed through a dry filter and titrated with one-twenty-fifth normal 
 barium hydroxid solution. 
 
 Four determinations gave the following results: 
 
 Oil taken 4 .506 5.S94 5-671 5.718 gms. 
 
 N 25 Ba (OH)2 required. 1.3 1.5 1.4 1.3 cc. 
 
 As two blank determinations required 1.3 and 1.5 cc, respectively, 
 of the barium hydroxid solution it is evident that the oil contains no 
 volatile acids. ^ 
 
 Scparatiotr and Determination of Fatty Acids. — It has been found 
 especially by Hazura- and his associates that the oxidation of unsatu- 
 rated fatty acids by alkaline potassmm permanganate serves as a basis 
 for the a])proximate separation of several fatty acids. Under proper 
 conditions the oxidation is chiefly confined to the direct addition of the 
 hydroxyl group (OH) wherever " free valences " exist. The following 
 shows the relations among several acids in the series containing eighteen 
 atoms of carbon in the molecule'*: 
 
 Unsaturated Acids. Saturated Acids. 
 
 Stearic, CjuHgcO... 
 Oleic, CjgHa^O^,, oxidizes to. . . .dihydroxy stearic, Cj„H.,.,(0H).,02. 
 Linolic, C,hH3.,02, oxidizes to. . tetrahydroxy stearic, C, „H.,.^(OH)jO.^. 
 Linolenic, Cj„H.,„0.,, oxidizes to.hexahydroxy stearic, C, „H.j„(OH)gO.,. 
 
 'Spiiller gives Reichert's number for the volatile acids as 0.33; Smith states 
 that the oil examined by him contained volatile acids equivalent to 0.56 per cent, of 
 KOH; and Morse (New Hampshire Experiment Station Bulletin (1892) 16, 19) gives 
 volatile acids as 3.2 per cent, in a sample of corn oil which absorbed 112.8 per cent, 
 of iodin. 
 
 ^Monatshefte fiir Chemie (1886) to (1889), Vols. 7 to 10. 
 
 3Cf. Hazura, ibid. (1887) 8, 269. 
 
^^98-] CHEMISTRY OF THE CORN KERNEL. " 177 
 
 After removing the cholesterol from 53.5 gms. of oil, the combined 
 soap solution was heated till the dissolved ether was distilled, cooled 
 and dduted to 3 liters. Two liters of a x./ per cent, potassium 
 permanganate solution were then gradually added with constant stirring 
 After 10 mmutes the precipitated manganese hydroxid was filtered off 
 and the clear filtrate acidified with hydrochloric acid. The precipitate' 
 thus formed was filtered off, washed, air-dried, and then extracted with 
 ether. The residue insoluble in ether weighed, after drying, 18 gms 
 It was extracted with boiling water until but 2 gms. remained, w^hich 
 when again extracted with ether, left a residue of only 0.6 gm and 
 soluble in boiling water. 
 
 The substance dissolve.l in hot water was practically completely 
 precipitated as the solution cooled^ and proved to be sativic acid 
 (tetrahydroxy stearic acid), as is indicated by the method of formation 
 and by its solubility in hot water. The melting point^ of the dried sub- 
 stance was 157 -I ^g,:. 
 
 The quantitative synthesis of the potassium salt was effected by 
 dissolving a weighed amount of the acid in warm alcohol and titrating 
 with standard alcoholic potassium hydroxid solution: '^ 
 
 Sativic acid Potassium hydroxid Per cent, potassium Per cent, potassium 
 *^''^°- required. in product. « (theory) ^ 
 
 ■^■°°° 0-1604 10.08 ,0.14 
 
 The ether solutions obtained as described above were combined 
 and the ether distilled. The residue was solid at the room temperature 
 melted gradually as the temperature rose from 40° to 60°, and was 
 found to absorb 79.2 per cent, of iodin, thus showing very incomplete 
 oxidation of the unsaturated acids. 
 
 A second lot of corn oil (54.24 gms.) was oxidi/ed bv alkaline 
 permanganate, the cholesterol and then the dissolved ether having been 
 previously removed. Tne soap was diluted to 2 liters and cooled to 0° 
 by ice kept in the solution. A solution of potassium permanganate 
 containing 80 gms in 2 liters of water was slowly added with constant 
 stirring. After 30 minutes precipitated matter was filtered off and 
 washed; the clear filtrate was acidified with 150 cc. of concentrated 
 hydrochloric acid; the precipitated acids were filtered off, dried, and 
 extracted with ether. The residue insoluble in ether (17.7 gms.) was 
 
 I2000CC of the filtrate from the precipitated sativic acid required only 0.5 cc. of 
 N 5 KOH to show alkalinity with phenol phthalein. 
 
 ■•Bauer and Hazura, Monatshefte fiir Chemie (1886) 7, 225, give r6o° as the 
 melting point of several samples of sativic acid, prepared in a manner similar to 
 the above. 
 
 ^'Calculated weight -1. 000 + 1604 ^^- ''^~ '°°^ 
 .T^ ^ r t 56.148 
 
 ^ForC,„H3,(OH). O..K. 
 
178 BULLETIN NO. 53. \_/"h'y 
 
 dissolved in boiling 95 per cent, alcohol. On cooling, the sativic acid 
 separated in the crystalline form, melting at i6r -[63 . 
 
 By distilling the ether from the solution obtained as above 
 described, a brown residue (9.5 gms.) was obtained which melted at 55^ 
 to 60° and showed an iodin absorption of only 9.2 per cent. 
 
 The aqueous acid solution from which the insoluble organic acids 
 had been precipitated by hydrochloric acid was evaporated nearly to 
 dryness, a black tarry mass gradually separating, showing that, although 
 a small amount of unsaturated acids had been unacted upon, the oxida- 
 tion had gone far beyond the simple addition of hydroxyl groups to the 
 unsaturated compounds. 
 
 To further investigate the fatty acids, a method essentially that of 
 Muter^ was tried for their separation and determination. It is based 
 upon the fact that the lead salts of the unsaturated acids, oleic, linolic, 
 etc., are soluble in ether; while the lead salts of the saturated acids, 
 stearic, palmitic, etc., are not. 
 
 About 1.5 gms. of the oil were saponified with alcoholic potash and 
 the soap dissolved in water, the unsaponifiable substance (cholesterol) 
 being separated from the soap solution by shaking with ether. The 
 solution was then neutralized with acetic acid, and the fatty acids pre- 
 cipitated with lead acetate, a slight excess being added. The lead salts 
 were washed with water, and then transferred with 50 cc. of ether to a 
 glass cylinder of about 60 cc. capacity, which was stoppered and then 
 violently shaken for 5 to 10 minutes. The small quantity of matter in- 
 soluble in ether was then allowed to settle. A stopper carrying two 
 glass tubes similar to those used in the ordinary washing bottle was 
 placed in the cylinder, the long tube reaching nearly to the undissolved 
 sediment. By blowing in the short tube the clear solution is transferred 
 almost completely without disturbing the sediment. The undissolved 
 substance was then shaken with more ether, allowed to settle, and the 
 ether transferred as before as completely as possible. This treatment 
 was twice more repeated. The undissolved lead salt was then warmed 
 with about 25 cc. of dilute hydrochloric acid, till the fatty acids sep- 
 arated; and, after cooling sufificiently the whole was transferred to a 250 
 cc. graduated bulb tube, ether being used to complete the transfer. 
 The portion of the tube below the bulb contained 50 cc. and was 
 graduated to 0.2 cc. A small glass tube carrying a stopcock was sealed 
 in just below the 50 cc. mark. The tube was filled to the 250 cc. mark 
 (above the bulb) with ether, and thoroughly shaken. The aqueous 
 layer, containing the excess of hydrochloric acid and the precipitated 
 lead chlorid was allowed to separate. 
 
 The volume of ether solution was observed, and 200 cc. of it were 
 
 'Analyst (1877) 2, 73.' 
 
CHEMISTRY OF THE CORN KERNEL. ^^^ 
 
 1898.] 
 
 drawn off into a weighed flask, evaporated to dryness, and the weight of 
 the residue determined. gju ui 
 
 Duplicate determinations gave the following^ 
 
 Oil taken.. 
 
 Volume of ether solution':: :::;:: :..:::::,,^;'°° '""'^ ^"''- 
 
 Ether solution taken 200 o 
 
 221.0 cc. 
 
 200.0 cc. 
 
 Saturated acids obtained ' " „ \^^^ '. ^ 
 
 4.44 percent. 
 
 Saturated acids in oil ' gg 
 
 The residue of saturated acids formed a white solid mass. It was 
 dissolved in hot alcohol and allowed to crystallize. The melting point 
 was 57 . The quantity of the saturated acids thus obtained was con- 
 sidered too small for further satisfactory examination (see foot note 
 below). 
 
 Before the lead salts of the saturated acids were completely washed 
 by decantation' the clear ether solution of the lead salts of the unsat- 
 urated acids absorbed o.xygen, and became cloudy, a white precipitate 
 forming m considerable amount. Two samples of the atmosphere in 
 the cylinders above the solutions were drawn off in gas burettes; and 
 after removing the ether vapor, the residual air was found to contain 
 only 15.3 per cent, and 13.9 per cent., respectively, of oxygen instead 
 of 20.8 per cent, as found in the air of the laboratory. 
 
 By subtracting the percentage (4.55) of saturated acids found in 
 the od from that of the total fatty acids (93.57) the amount of total 
 unsaturated acids is found to be 89.02 per cent., consisting of oleic 
 and linolic acids. (The melting point of the sativic acid obtained and 
 the composition of its potassium salt prove the absence of linusic acid 
 m the products of oxidation, and, hence, of linolenic acid in the total 
 fatty acids.) 
 
 From the iodin absorption, the amounts of oleic and linolic acids 
 can be accurately determined. Thus: 
 
 Oleic acid, C,3H3,0, -f I, = C,„H3,l30.„ diiodo stearic acid 
 Linohc acid, C.^H^.O, + 2I, = C.^H^.J.O,, tetraiodo stearic acid. 
 As 89.02 gms. of these unsaturated acids in the ratio in which they 
 exist m corn oil absorb 122.3 gms. of iodin, the following equation can 
 be stated, x being the number of gms. of oleic acid: 
 
 ^54 , ,„ 508 
 ''zST+^S^-oa-x) ^=122.3 
 
 'At least two days' time is required for this process, and even this was found 
 more satisfactory than filtration. I have no doubt that, if centrifugal force were 
 substituted for gravity, the washing by decantation could be done much better and so 
 qu.ckly that the unsaturated acids could also be determined before the absorption of 
 any appreciable amount of oxygen. Quantities of the separated materials sufficient 
 tor further examination could doubtless be obtained in a short time. No suitable 
 centrifuge was at hand for this work. 
 
l8o HULI-KTIN NO. 53. \_J"h'i 1898. 
 
 The oleic acid is found to be 42.92 gms. and the linolic acid 46.10 
 gms. 
 
 By subtracting from the amount of saturated acids the equivalent 
 of the 'Stearic acid contained in the lecithin, and calculating to the 
 respective glycerol esters the remaining saturated acids (as stearic acid), 
 the oleic acid, and the linolic acid, the following summary is obtained 
 as the composition of the oil of corn: 
 
 Cholesterol i . 37 per cent. 
 
 Lecithin 1.49 " 
 
 Stearin (?) 3-66 " 
 
 Olein 44 • '^5 " 
 
 Linolin '. 4'*^ -19 
 
 Total 99.56 
 
 X 
 
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