K-a?
71

R3

PHYSIOLOGICAL NOTES

Randolph and Dixon

UCrNRLF

B 3 371 10H

THE LIBRARY

OF

THE UNIVERSITY
OF CALIFORNIA

PRESENTED BY

PROF. CHARLES A. KOFOID AND
MRS. PRUDENCE W. KOFOID

NOTES

FROM THE

PHYSIOLOGICAL LABORATORY

UNIVERSITY OF PENNSYLVANIA.

EDITED BY

N. *A. RAXDQJLPH, M.D.,

Assistant Demonstrator of Physiology in the University of Pennsylvania
Fellow of the College of Physicians of Philadelphia ; Member of the
American Philosophical Society, of the Academy of Natural
Sciences of Philadelphia, of the Philadelphia Neuro-
logical Society, of the Society of Naturalists
of the Eastern United States, and
of the American Society for
Psychical Research,

SAMUEL G. DIXOX,

Assistant Demonstrator of Physiology at the University of Pennsylvania.

PRINTED BY

J. B. LIPPIXCOTT COMPANY,

PHILADELPHIA.

1885.

B

PREFACE.

THE papers which form this little volume are
simply the brief records of facts of interest brought
to light in the course of physiological study.

The constant aim of the writers has been to
present these facts with the greatest conciseness
compatible with scientific accuracy.

Judgment upon this and other qualities is, how-
ever, left to the friendly reader by

THE EDITORS.

M348932

CONTENTS.

PAGE

I. — A NOTE ox THE F.ECES OF STARCH-FED INFANTS.
N. A. RANDOLPH. Trans. Col. Phys. Phila., 3d series,
vol. vi., 1883 7

II. — A^r EXAMINATION or THE FJECES OF TWENTY PER-
SONS RECEIVING INUNCTIONS OF COD-LIVER OIL.
N. A. RANDOLPH & A. E. ROUSSEL. Phila. Med.
Times, 1883 11

III. — A STUDY OF THE DISTRIBUTION OF GLUTEN
WITHIN THE WHEAT-GRAIN. N. A. RANDOLPH.
Proc. Acnd. Nat. Sci., 1883 16

IV.— ON CERTAIN UNTOWARD EFFECTS OF THE ADMIN-
ISTRATION OF TURPETH MINERAL. N. A. RAN-
DOLPH & A. E. ROUSSEL. Phila. Med. News, 1884 . 24

V. — A PRELIMINARY NOTE ON A REACTION COMMON
TO PEPTONE AND BILE-SALTS. N. A. RANDOLPH.
Proc. Acad. Nat. Sci., 1884 31

VI. — A NOTE ON THE BEHAVIOR OF HYDROBROMIC
ACID AND OF POTASSIUM IODIDE IN THE DIGEST-
IVE TRACT. N. A. RANDOLPH. Read before the
Phila. Neurological Society, April 28, 1884 . . 34

VII. — ON THE DIGESTION OF RAW AND OF BOILED
MILK. N. A. RANDOLPH & A. E. ROUSSEL. Proc.

Acad. Nat. Sci., 1884 42

1* 5

6 Contents.

PAGE

VIII. — A STUDY or THE NUTRITIVE VALUE OF BRANNY
FOODS. N. A. KANDOLPH & A. E. ROUSSEL. Trans.
Col. Phys. Phila., 3d series, vol. vii., 1884 . • .44

IX. — A METASTATIC HEAT REGULATOR. N. A. RAN-
DOLPH. Journal of the Franklin Institute, 1884 . 69

X. — ON THE BEHAVIOR OF PETROLATUM IN THE DIGEST-
IVE TRACT. N. A. RANDOLPH. Proc. Acad. Nat.
Set., 1884 73

XI. — CUTANEOUS ABSORPTION OF NICOTINE. N. A.
RANDOLPH & SAMUEL G. DIXON. Proc. Acad.
Nat. Sci.j 1884 . . '. " 76

XII. — ON THE DIETETIC FACTOR IN THE TREATMENT
OF ANGINA PECTORIS. N. A. RANDOLPH. Read
before P/tila. Neurological Soc., 1884 . . .78

XIII. — A PAINLESS ES'CHAROTIC. N. A. RANDOLPH

& SAMUEL G. DIXON. Phila. Medical News, 1885 81

XIV. — ON THE CUTANEOUS ABSORPTION OF SALICYLIC
ACID. N. A. RANDOLPH & SAMUEL G. DIXON.
Phila. Medical News, 1885 . . . . .83

I.

A NOTE ON THE FJECES OF STARCH-FED
INFANTS.

THE series of experiments presented in the pre-
ceding paper by Dr. Keating seems to me to be in
the highest degree suggestive, for it is only rational
to suppose that the development of the amylolitic
ferment of the pancreatic juice is coincident with
the appearance of the analogous salivary ferment.1
Inasmuch, however, as the food even in spoon-fed
infants is retained but a short time in the mouth,
and further, as the continued action of the saliva
after it enters the stomach is as yet problematical,
the only absolute control for such observations is
afforded by an examination of the faeces.

Through the kindness of Dr. Keating I have
been enabled to examine the stools of twenty-four
starch-fed infants, of ages varying from forty-five
days to eighteen months. Twenty-three of these
children were fed upon cracker-dust, water, and

1 The experiments in question demonstrated the activity
of the saliva of very young infants.

7

8 Notes from the Physiological Laboratory

condensed milk. The twenty-fourth received corn-
starch boiled in milk.

The freshly evacuated faeces of each infant were
carefully bottled and labelled, and a drop of a solu-
tion of iodine was added to a small portion of each
specimen, which was then submitted to microscopi-
cal examination. Besides turning the starch blue,
and indicating the presence of dextrine by a pecu-
liar mahogany-red color, the iodine has the advan-
tage of rendering any fats which may be present
much more readily apparent. The reaction of each
specimen was taken, but though this varied from
acid to alkaline and neutral, no correlation between
the reactions and the other properties of the speci-
mens could be observed. A decoction of each was
tested for glucose with freshly-prepared Feh ling's
solution, but except in one instance no appreciable
amount could be found.

The presence of starch was exceptional and ap-
parently in no degree dependent upon the age of
the child. The stools of eighteen out of the
twenty-four children contained either no starch, or
but a trace, — i.e., no more than is frequent in the
evacuations of a healthy adult upon a mixed diet.
Six of these specimens were from children of three
months or less, — the youngest being but forty-five

of the University of Pennsylvania. 9

days old. In many cases the broken and empty
cellulose envelopes of the starch-granules were
clearly discernible.

The six infants in whose evacuations a note-
worthy amount of starch was present were aged
respectively three, four, ten, thirteen, fourteen, and
seventeen months. The eldest two were in very
bad health.

The following is a tabular statement of the age,
diet, and appearances of the faeces in the children
forming the subject of this study :

AN EXAMINATION OP THE F^CES OF TWENTY-FOUR STARCH-
FED INFANTS.

No.

Name.

Age.

Food.

Starch
present.

Remarks.

1

Savin

45 days.

Condensed

None.

milk and

cracker-

dust.

2

Jocker

2 mos.

M

Traces.

3

McGcttinger.

2+ "

•1

**

4

McGowaii

3 "

»

«

Twice examined : no

fat before inunc-

tion, about 10 per

cent, after.

5

ROSS

3 "

«

«

6

Hays

3 "

"

About J4

starch.

7

Sov

3 "

«

Traces.

8

Ueuwich

4 "

Corn-starch

«

and milk.

9

Moore

4 "

Condensed

None.

Many broken cellu-

milk and

lose envelopes.

cracker-

dust.

10

Conway

4+"

Traces.

Evidences of potato

surreptitiously

given.

11

Roach

5 u

<i

About %

starch.

12

Anxier

5+"

'<

None.

13

Schmiiz

5+"

«

Many bacteria.

14

McKinley

(5+"

"

u

10 per cent, fat; had

had inunctions.

10 Notes from the Physiological Laboratory

AN EXAMINATION OF THE FAECES— (Continued).

No.

Name.

Age.

Food.

Starch
present.

Remarks.

15

Hall

8-f- mos

Breast and

Traces

16

17

Hensen
Devine

10+"
13—"

cracker-
food.
Condensed
milk and
cracker-
dust.
<(

More than
normal.

20 to 30

Many bacteria; evi-
dences of potato
surreptitiously
given.
Some glucose pres-

18

Croncia

14—"

(i

per ct.
Traces.

ent and indications
of dextrine ; saliva
was found to be iu-
efficieut.

19

20

Madden
Boyle

14 "
14 "

"

10 per ct.

Sick.

21

22
23

24

Glass ....

Kinscher
Wood

Dane

14+"

17—"
17-"

18 "

M

starch.
None.

Over %
starch.

Traces.

Except a few large
cells containing
starch from potato.

Syphilitic; saliva was
found to be ineffi-
cient.
Indications of dex-
trine.

The facts presented appear to justify the follow-
ing conclusions :

First, that many infants of under three months
can digest starchy foods ;

Second, that the individual variations in this re-
gard are so numerous that no broad and general
statement can be made as to the period at which
infants begin to digest starches; and,

Third, that the physician can be absolutely cer-
tain that a farinaceous ingredient in the diet of a
young infant is beneficial only by an examination
of the dejecta under such diet.

of the University of Pennsylvania. 11

ii.

AN EXAMINATION OF THE FAECES OF
TWENTY PERSONS RECEIVING INUNC-
TIONS OF COD-LIVER OIL.

IN a study of the fseces of starch-fed infants1 one
of us observed a specimen in which there was present
a very notable amount of oil-globules. Upon in-
quiry, it was found that the child in question had
been receiving inunctions of cod-liver oil.

The same coincidence was a second time noted,
and the following series of experiments was then
instituted.

The faeces of fourteen infants, in fairly average
health, were examined with negative results as far
as oil was concerned, except in one case.

These infants were then thoroughly rubbed with
cod-liver oil twice daily for eleven days, care being
taken to cleanse the surface of the body after each

1 Randolph : Transactions of the College of Physicians of
Philadelphia, 3d series, vol. vi. p. 443.

12 Notes from the Physiological Laboratory

inunction, and the faeces of each examined for oil at
the end of the third and of the eleventh day of
inunction. At the end of the third day, traces of
fat were observed in the majority of the specimens.
On the eleventh day all but three specimens ex-
hibited, on microscopical examination, a decidedly
notable quantity of unabsorbed fat, — numerous oil-
globules being apparent in every field.

In like manner an examination was made of the
dejecta of six adults, after which each was twice
daily well rubbed with cod-liver oil in the groins
and axillae for a period of three weeks. The faeces
of the adults contained normally much more fat
than those of the infants, but in all but one case
there was a well-marked increase in the proportion
of fatty globules at the end of the treatment.

The circumstances of the examination precluded
the application of the ether method for the estima-
tion of fats, and we were forced to rely upon a close
microscopical examination. For the micrometric
method only relative accuracy is claimed, and we
hope soon to be able to go over the same ground,
substituting a chemical for the optical method in
the determination of fats. By the use, however, of
well-mixed specimens, and by carefully averaging
the contents of many fields from the same specimen,

of the University of Pennsylvania.

13

we have obtained results which we believe accu-
rately represent the changes in the relative propor-
tion of fat in the specimens examined, although the
unit assumed may not correspond with that obtained
by gravimetric methods.

The individuals under observation were upon a
diet practically uniform in composition and quan-
tity, both before and during the treatment. At the
end of the period of inunction a marked gain in
weight and general health was noted in the majority
of the cases.

The results of our study are indicated in the fol-
lowing tables :

ga

ga

SJj

S*"1 _•

.a1"1 •

o •

No.

Age.

Diet.

C ^ *3

H'»-2

«•„!

fc ^U

^ >. "S

2*§

S 9 a

§5*

<M s

1

2 months.

Milk and crackers.

Negative.

Negative.

Negative.

2
3

3

(( (C

!!

Traces.

3 per cent.
3.5 " "

4

5

Corn-starch and milk.

"

5 " "

5

5

Milk and crackers.

M

«•

3 " "

6

7

5

6

« «

Traces.

Negative.
Traces.

Negative.
Traces.

8
9

6

8

« «

Negative.

Negative.

"

3.5 per cent.
5 " "

10

11

(i ii

«

Traces.

3.5 " "

11

12

«

3 ** **

12

14

«< «

««

«

3.5 " "

13

14 «

"

«

H

2.5 " "

14

15 "

Corn-starch and milk.

"

(1

3.5 «• "

14 Notes from the Physiological Laboratory

No.

Age.

Diet.

Fat in Faeces
before Inunc-
tion.

Fat in Faeces
after 21 Days'
Inunction.

1

Adult

Hospital Diet

Traces

Traces.

2

:{

it

« <(

2 " "

10+ " "

4.

(4

<( M

3 " "

10 " "

5

4i

(( 1C

G

K

« (1

It will be seen, from the tables given above, that
in 80 per cent, of the cases a notable increase of the
fatty matters passed per an urn was observed after the
persistent inunction of cod-liver oil. In the remain-
ing 20 per cent, the quantity of faecal fats was un-
altered by the treatment, and in one case remained
negative throughout.

We venture to suggest, as a provisional hypothe-
sis, that by the continued inunction the circulating
fluids became to some extent surcharged with fats,
and that, in consequence, a certain amount of the
fatty constituents of the food was refused by the ab-
sorbent surfaces of the intestine and passed from the
body unaltered. This supposition is strengthened
by the observations of Berthe,1 who showed that
pure cod-liver oil, given internally, could be taken
for a longer time without appearing in the feeces,

1 L'Union Medicale, t. x. No. 62, 1856.

of the University of Pennsylvania. 15

than could an equal amount of butter or any of the
other animal and vegetable fats.

We further suggest that, in practice, the increase
of fat in the stools constitutes a physiological test
for the efficiency of the aliptic treatment in the great
majority of cases, and that by the application of this
test both the frequency of exhibition and the amount
of a remedy rather repugnant to the average patient
may be reduced to the minimum necessary for effi-
cient treatment.

16 Notes from the Physiological Laboratory

in.

A STUDY OF THE DISTRIBUTION OF GLUTEN
WITHIN THE WHEAT-GRAIN.

THE object of the present paper is to briefly de-
scribe several methods for the demonstration of
gluten in the central portion of the wheat-grain, and
the results of their application.

For many years the great majority of observers
and of writers upon gluten have stated that this
highly important nitrogenous element of food is
found almost, if not quite exclusively, in the fourtli
layer (Parkes) of the grain, immediately below and
adherent to the third or inner coat of the true bran.
This fourth layer is composed of closely-packed yel-
lowish granular cells of ovate or cuboid form, each
of which is provided with a dense, laminated cellu-
lose wall, and contains a large proportion of free fat.
Immediately within this layer of so-called " gluten-
cells," and constituting the greater portion of the
grain, is an aggregation of much larger, usually
elongated, cylindrical cells, whose contents are appa-

of the University of Pennsylvania. 17

rently made up exclusively of starch-granules which
exhibit great diversity in size.

So fixed and widespread has the belief become
that the gluten of the wheat resides in specific corti-
cal cells of the grain, that not only do many most
intelligent persons habitually rasp their digestive
surfaces with branny foods, but attempts to deter-
mine, by microscopical examination, the nutritive
values of various prepared foods have been made,
in which the proportion of " gluten-cells" found in
a given food formed the criterion of its value.1
These assumptions have called forth merited criti-
cism from Prof. Richardson, of this city, and from
Prof. Leeds, of Hoboken, both of whom empha-
sized the fact, singularly ignored by Cutter, Jacobi,
and their followers, that ordinary white wheat-flour
contains a varying but always notable quantity of
gluten.

So far as the writer is informed, however, there
has not been recorded any ocular demonstration of
the gluten of the wheat-grain, in situ and entirely
independent of the "gluten-cells." Such a demon-
stration may be conclusively made by either of the
following methods :

1 E. Cutter, M.D., Galliard's Mod. Jour., Jan. 1882.
2*

18 Notes from the Physiological Laboratory

1. If whole wheat-grains be macerated in water
to which a few drops of ether have been added to
prevent germination, they will, in a few days, be-
came thoroughly softened, and the contents of each'
grain may then be squeezed out as a white tena-
cious mass. Examination of the remaining bran
shows the "gluten-cells" undisturbed, closely adher-
ing to the cortical protective layers. By now care-
fully washing the white extruded mass, the major
part of its starch may be removed ; and upon the
addition of a drop of iodine solution, microscopic
examination shows numerous net- works of fine yel-
low fibrils, still holding entangled in the'ir meshes
many starch-granules colored blue by the iodine.
In carefully-washed specimens, these sponge-like
net-works are seen to retain the outline of the cen-
tral starch-filled cells, and evidently constitute the
protoplasmic matrix in which the starch-granules
lay. Upon gently teasing such a specimen under a
moderate amplification the fibrils will be seen to be-
come longer and thinner in a manner possible only
to viscid and tenacious substances, — a class repre-
sented in wheat by gluten alone.

An eminently satisfactory proof of the proteid
nature of these central net-works may be obtained by
heating the specimen in the solution of acid nitrate

of the University of Pennsylvania. 19

of mercury (Millon's reagent), when the fibrils will
assume the bright pink tint characteristic of albu-
minoids under this treatment. The results of the
application of the xanthoproteic and biuret re-
actions are equally conclusive, but .more care is re-
quired in the use of these proteid tests, and the
resultant differentiation is not so clear. Reticuli
similar to those above described, but much broken
and smaller, may be seen, upon close examination,
scattered throughout fine white flour, without the
addition of any reagent.

By general consent, the albuminoids of the wheat-
grain are grouped together as gluten, which is, how-
ever, further separable into gluten-fibrin, gliadin,
and mucedin, proteid bodies practically equal in
nutritive value, but differing in certain physical
properties, notably that of solubility. It must,
therefore, be borne in mind that in this, as in all
other methods of separating gluten from the other
constituents of the grain, its relatively small soluble
portion is removed with the starch, and that any
estimate of the quantity of gluten based upon such
methods will probably be rather under than over
the actual amount.

2. In even the thinnest sections of the wheat-grain,
the gluten of the central portion is always masked

20 Notes from ike Physiological Laboratory

by large numbers of starch-granules. These may,
to a large extent, be removed by immersing the sec-
tion for a short time in liquor potassse, with subse-
quent careful washing. The alkali effects the hy-
dration and partial solution of the starch ; but if its
application be too long continued, the gluten will
also be dissolved. This treatment is well adapted to
show the rather dense gluten net- works usually found
in bran, immediately below the fourth layer.

3. The most satisfactory method of studying the
distribution of gluten in sections of wheat is that of
artificial salivary digestion. If the section be gently
boiled for a moment to hydrate the starch, then
transferred when cool to filtered saliva, and main-
tained for from half an hour to an hour at a tem-
perature of about 98° Fahr., all the starch will be
digested away, while the insoluble proteid and other
constituents will remain entirely unaltered. A
section of wheat-grain thus treated will exhibit,
throughout its entire central portion, close-meshed
gluten net-works, which become slightly denser to-
ward the cortex of the grain. The proteid char-
acter of these reticuli is here, as in the first method,
susceptible of micro-chemical demonstration by Mil-
Ion's reagent or the biuret reaction. A relatively
very faint coloration, indicating the presence of

of the University of Pennsylvania. 21

albuminoids, is noticeable in the " gluten-cells,"
while the gradual condensation of the gluten of the
endosperm as the cortex is approached, is evidenced
by a quite vivid coloration of the fibrils.

Schenk * has applied Millon's reagent to sections
of wheat with a resultant assumption by the endo-
sperm of a pink tint and " no coloration of the corti-
cal gluten-cells." The starch was not removed, and
the method of distribution of gluten was not deter-
mined. By artificial gastric digestion of wheat sec-
tions, the same observer noted that the starch of the
section became readily detached, and deduced from
this the just proposition that the gluten lay between
the starch-granules.

Objections are not infrequently offered by the
chemist to the microscopical determination of or-
ganic compounds, especially where any attempt at a
quantitative estimation is made. All that is claimed
for the methods above described is the demonstration
of gluten in very considerable quantity in the inner
layers of the wheat-grain. It is but just to state,
however, that by these methods a conception may
be obtained of the quantity of proteids within the
grain fully as accurate as that given by the usual

1 Anat.-Physiol.-Unters., p. 32. Wien, 1872.

22 Notes from the Physiological Laboratory

chemical method of estimating the albuminoids of
a given body, namely, from the entire amount of
nitrogen contained in it. Especially is this true in
the case of vegetable tissues. In a close analysis of
the potato, Schultze and Barbieri found that only
56.2 per cent, of all its nitrogen existed in albu-
minoid combination, while in the fodder-beet only
20 per cent, of the nitrogen went to the formation
of albuminous compounds; the remainder in each
case entering into the composition of non-nutritious
bodies, as amides, nitrates, ammonia, and asparagin.

The fact that the gluten net- works become denser
toward the periphery of the endosperm, together
with the presence of non-albuminoid nitrogenous
compounds in the perisperm, explains the notable
percentage of nitrogen found in bran as ordinarily
roughly removed.

The color-tests mentioned above indicate that the
amount of proteids contained in the cells of the
fourth layer is relatively very slight; but admitting
for the moment that these cells contain gluten,
the question naturally arises whether, in view of
their dense cellulose walls, they are capable of serv-
ing as a food-stuff for man. In artificial digestion
the writer has found these elements, even when
thoroughly cooked, to be unaffected by the digestive

of the University of Pennsylvania. 23

juices ; that is, well-boiled bran with its adherent
"gluten-cells/' will sustain prolonged maceration at
the temperature of the human digestive tract in
artificial gastric and pancreatic juice (in which,
under the same conditions, fibrin is readily digested)
without exhibiting any change. These cells were
further found to be unaffected by maceration for
thirty days in liquor potassse, except for a slight
swelling of the cell and the occasional coalescence of
some of its contained oil-globules. They were also
practically unchanged by a few days' immersion in
strong nitric acid. In order to obtain conclusive and
unassailable results as to the nutritive value of the
" gluten-cells" as far as man is concerned, the writer
has at present under observation a number of healthy
adults, who daily receive, in addition to their regu-
lar diet, a small fixed amount of boiled bran. Their
alvine dejections (containing all the undigested ele-
ments of food after the normal action of all the
digestive juices) will be submitted to close micro-
scopical examination, with a view to ascertaining
the extent to which the "gluten-cells" have been
digested, and a report will be made upon the results
in the near future.

24 Notes from the Physiological Laboratory

ON CERTAIN UNTOWARD EFFECTS OF THE
ADMINISTRATION OF TURPETH MINERAL.

have recently had under our personal ob-
servation five cases in which the administration of
turpeth mineral was followed by unexpected symp-
toms.

On the occasion in question each of eight well-
nourished men, in average health, was given five
grains of turpeth mineral ; * and as emesis did not
follow within half an hour, three grains additional
were given, with the result of inducing vomiting,
more or less copious, within twenty minutes after
the administration of the second dose. Beyond a
continuation of the retching for some time and a
general complaint of a sense of burning in the
throat and fauces, nothing unusual was observed at
the time, and but little depression immediately fol-
lowed the emesis.

1 The drug was purchased from a reliable wholesale dealer
in this city.

of the University of Pennsylvania. 25

On the following morning, however, our atten-
tion was called to the condition of five out of the
eight men above mentioned. A rather violent diar-
rhoea had followed in from ten to twenty hours
after the administration of the drug, attended by
much griping and a rather unusual amount of con-
stitutional depression. Each of these five men. had
passed in the twenty-four hours succeeding the ex-
hibition of the drug from eight to fifteen stools.
These stools at first resembled those of calomel, but
eventually became yellow. Appropriate treatment
was administered, and on the following day the
diarrhoea was partially or wholly checked, and the
cases progressed favorably to recovery. It is worthy
of note that in each case the first few stools con-
tained minute particles of the yellow sulphate,
showing that not only had its elimination by emesis
been far from complete, but also that the drug had
been for from ten to twenty hours in contact with
the tissues and fluids of the digestive tract.

In the fifth case, John H., a German, set. 38,
complained of a soreness of his gums, and of the
large amount of saliva dribbling from his mouth.
He had up to this time received no preparation of
mercury for several months. An examination
showed the gums to be soft and spongy, with the

26 Notes from the Physiological Laboratory

teeth partially loosened, the tongue swollen, cov-
ered with a thick, yellowish coat, and showing dis-
tinctly the imprint of each tooth. This, together
with the large amount of saliva secreted, and the
characteristic fetor of the breath, proved it to be a
well-marked case of salivation, such as is for-
tunately rarely witnessed at the present day, either
in hospital or general practice. Under appropriate
treatment, however, the man improved, and was
ultimately cured.

Had the cases been younger or less vigorous, a
different termination might have resulted.

At the time we regarded these results as peculiar,
but shortly afterwards our attention was called to
an article by Dr. McPhedran,1 in which was given
a detailed account of two fatal cases occurring in
children, in which, however, emesis failed to result,
as also a similar case in the Medical and Surgical
Reporter.2

Upon examining the literature of the subject we
find that Dr. Hubbard, of Maine, was among the
first to use this drug; but to Dr. Fordyee Barker,
of New York, belongs the credit of bringing it

1 The Medical News, December 22, 1883, p. 682.

2 January 19, 1884, p. 93.

of the University of Pennsylvania. 27

prominently before the attention of the profession.
In an article on " Croup," l Dr. Barker states that
after an experience of twenty years he considers
turpeth mineral the best emetic for use in this dis-
ease, and goes so far as to recommend that it be
kept on hand in all families with children of a
croupy tendency, administered at the earliest symp-
toms of an attack, and before sending for a phy-
sician.

Abroad, also, the drug seems to have been re-
ceived with favor. Drs. Desmartis and de Titray,2
who consider the membrane in croup as due to the
result of blood-poisoning of a fermentative charac-
ter, advocate the merits of the remedy as twofold,
viz., as exerting a specific agency upon the ferment,
and also as removing the deposits by emesis. They
record its use in a number of cases of different ages
with good results.

Again, Dr. Smith,3 in his work on " Diseases of
Children,'7 speaks of this drug in connection with
croup, and mentions it as probably the 'best emetic
in ordinary cases of this disease.

1 American Journal of Obstetrics, May, 1870.

2 Nouveau Traiternent du Croup, etc., Paris, 1860, p. 28.

3 Fifth edition, p. 548.

28 Notes from the Physiological Laboratory

Prof. Alfred Stille*1 quotes two cases occurring in
adults with fatal results. In one, a boy, aged six-
teen, took about a drachm of this drug; symptoms
of the ingestion of an irritant poison followed, to-
gether with great salivation, and death ensued in a
week's time.2

"In the second case, a man, set. 27, took forty
grains of this medicine by mistake for JEthiops
mineral. The primary symptoms were precisely
the same as in the above case just related. Death
occurred at the end of ten days. The inner surface
of the month, gums, palate, and fauces were cov-
ered with black sloughs ; the parotid and submax-
illary glands were enlarged ; the mucous membrane
throughout the intestinal canal was softened and
easily torn ; the glands of the stomach and intes-
tines unnaturally large; the kidneys were much
enlarged, and the bladder full of urine." 3

A case of poisoning, with recovery, by the same
drug, in a dose of "less than a drachm," is reported
by Yowndes.4

1 Therapeutics, fourth edition, vol. ii. p. 769.

2 Letheby, London Medical Gazette, xxxix. p, 474.

3 Taylor, Guy's Hospital "Reports, 3d series, x. 180.

4 Abstract in Lancet, March 10, 1860.

of the University of Pennsylvania. 29

In the "United States Dispensatory"1 we find
it stated that the drug in question operates with
great promptitude, but sometimes excites saliva-
tion.

As seen by the references above given, our cases
present little of novelty, excepting that the dose we
used was quite within therapeutic limits as ordi-
narily given ; but we deem it our duty to call atten-
tion to the danger attending the administration of
this drug, especially as its poisonous properties
seem to have been overlooked by several recent
writers on therapeutics.

Prof. Bartholow,2 it is true, states that " serious
results might be produced if emesis did not so
promptly follow," which seems to agree with the
experience of Dr. McPhedran, already mentioned.
In the cases under our own observation, however,
the poisonous symptoms followed, notwithstanding
that fairly copious emesis resulted in every case.
The time which elapsed between exhibition and
emesis (thirty-five to fifty minutes) was possibly
sufficient to permit the occurrence of chemical
changes in the drug as it lay in the stomach, and

1 Fifteenth edition, p. 767.

2 Therapeutics, fifth edition, p. 252.

3*

30 Notes from the Physiological Laboratory

the minimum time of ten hours elapsing between
the ingestion of the drug and its final elimination
with the faeces was (in one case at least) fully suf-
ficient to account for the resultant symptoms, which
were of a character tending to substantiate the
statement of Miahle, that all mercurial preparations
are absorbed in the form of chlorides.1

We are informed by several prominent dealers in
drugs that the demand for turpeth mineral is quite
large, and is apparently growing. This fact, to-
gether with the praise it has received in several
quarters, justifies us in emphasizing the following
conclusions, based upon the observations, old and
new, which are given above :

1. That a dangerous quantity of turpeth mineral
often remains in the stomach after emesis.

2. That this drug possesses sufficient toxic and
irritant properties not only to demand from the
profession much, more than usual caution in its
administration, but to condemn its use where the
exhibition of any other emetic is practicable.

3. That it should not be placed in the hands of
1 te laity.

1 See the Medical News, January 26, 1884, p. 89.

of the University of Pennsylvania. 31

A PRELIMINARY NOTE ON A REACTION COM-
MON TO PEPTONE AND BILE-SALTS.

IF the acid nitrate of mercury (Millon's reagent)
be added to a cold aqueous solution of potassium
iodide, a red precipitate of mercuric iodide always
appears. When, however, either peptone or biliary
salts are present in noteworthy amount, the precipi-
tate of nascent mercuric iodide assumes the yellow
phase. As practically applied, the red may vary
from salmon to scarlet, the yellow from pale lemon
to orange.

In order to render the test sensitive to the
presence of minute quantities of the substances
in question, it is necessary to limit the amount
of potassium iodide employed. Thus to each five
cubic centimetres of the suspected fluid — which
must be cold and either neutral or faintly acid — are
added two drops of a saturated solution of potas-
sium iodide, the two liquids being well mixed.

32 Notes from the Physiological Laboratory

Four or five drops of Millon's reagent are now
added, the contents of the vessel thoroughly stirred
or shaken. Under these circumstances the presence
of peptone in amounts of less than one part in five
thousand is readily shown. By reducing the quan-
tities of the reagents used it is possible to demon-
strate the presence of peptone in a solution con-
taining but one part of that body in seventeen
thousand parts of water.

The conditions interfering with this reaction are :
alkalinity of the fluid examined (readily overcome
by neutralization) ; heat, which has the same influ-
ence upon the nascent mercuric iodide as have pep-
tone and the bile-salts; and the presence of certain
compounds, as potassium ferrocyanide, which chem-
ically prevent the production of the mercuric
iodide.

The following bodies in moderate amount do not
affect the reaction : saliva, syntonin, amygdalin,
para-albumen, diastase, kreatin, leucin, tyrosin,
mucic acid, glucose, urea, uric acid, nitric, hydro-
chloric, sulphuric, and picric acids, glycerine, alco-
hol, atropia sulphate, pilocarpin nitrate, caffeine,
sodium carbonate, ammonium oxalate, sodium
phosphate, and manganese chloride and ferric
chloride.

of the University of Pennsylvania. 33

[This test is not applicable to urine, nor is it
available in the presence of albumen or gelatin.]

It is obvious that this reaction is useless to the
student as an isolated test, inasmuch as it responds
to two entirely distinct compounds, but its sim-
plicity and striking colorations give it very consid-
erable value when employed in corroboration of
other tests.

34 Notes from the Physiological Laboratory

A NOTE ON THE BEHAVIOR OF HYDROBRO-
MIC ACID AND OF POTASSIUM IODIDE IN
THE DIGESTIVE TRACT.1

I VENTURE to present before the Society a brief
note upon a subject not strictly neurological, but
having direct bearing upon the relations entertained
to the processes of digestion by two drugs, which
are of interest to the neurologist.

In a series of artificial digestions, in which hy-
drobromic acid was present in the digestive mixture
in amount corresponding to the therapeutic dose, I
have noted, —

(a) That salivary digestion was completely sus-
pended, whereas

(6) The peptonization of proteid food-stuffs was

1 The general deductions herein made from the study of
these two drugs are applicable respectively to all acid and
alkaline drugs given by the mouth, and a more descriptive
title of the paper would have been " Time Relations in the
Exhibition of Acids and of Alkalies."

of the University of Pennsylvania. 35

in no wise retarded, the variation from the nor-
mal, if any, being toward an acceleration of this
process.

It is evident, therefore, that, other things being
equal, the appropriate time for the exhibition of
this drug is immediately upon the cessation of sali-
vary digestion within the stomach, or, in other
words, upon the first formation of free acid within
that viscus.

Recent studies1 have shown that the acidity of
the gastric contents, found even in quite early stages
of digestion, is not due to the presence of free acid ;
and the ingenious observations of Von den Velden2
go far toward proving that the development of free
acid within the stomach does not occur until from
forty -five minutes to an hour after breakfast, and
from one to two hours after dinner. These results
were obtained chiefly by the use of methyanilin violet
and tropseolin, bodies delicately responsive, by color-
change, to the presence of free acid. There is little
doubt in my mind that hydrochloric acid is devel-
oped in the stomach at an earlier period than that

1 Deutsch. Archiv Klin. Med., xxiii. 369. See also
Jahresb. ii. d. Fortschr. d. Thier-Chemie, 1880, p. 302, and
Danilewsky, Centralb. f. d. Med. Wiss., 1880.

2 Zeitschr. f. Physio! . Chemic, iii. 205.

36 Notes from the Physiological Laboratory

above indicated, but it seems very probable that by
immediate combination with albuminoids it loses
somewhat of its characteristic activity. This is il-
lustrated by an observation made in the course of
this study, namely, that the addition of small
amounts of potassium iodide to dilute solutions of
acid-albumen containing two-tenths of one per cent,
of hydrochloric acid does not result in the libera-
tion of iodine. The addition of the same amount
of the iodide to the same quantity of an aqueous
solution of hydrochloric acid of the same degree
of acidity results in an immediate liberation of
iodine.

This interesting discovery of two stages of acidity
in the gastric juice has, I believe, not yet been in-
corporated in the text-books. It serves to reconcile
the contradictory opinions so frequently found as to
the value to the economy of saliva as a digestive
fluid, and explains the completely diverse results
obtained . by such careful workers as Frerichs,1 and
Bidder, and Schmidt.2

Besides an observance of the time-limitations just
indicated, I would suggest the advisability of milk

1 Wagner, Handwoerterbuch. d. Physiologie, iii., a, 772.

2 Bidder und Schmidt, Verdauung u. Stoffwcchsel, p. 27.

of the University of Pennsylvania. 37

as a vehicle for the administration of hydrobronaic
acid. The curd thus formed is fine and flocculent,
the mixture closely resembling buttermilk in taste
and appearance, and in no wise suggesting medicine.
I have taken as much as a tablespoon ful of the di-
lute acid in a tumbler of milk without any repug-
nance. The milk used must be raw. With this,
as with most other acids, boiled milk gives tough
and bulky coagula.1

As regards the exhibition of the iodide of potas-
sium, the rationale of its time relations is altogether
different. Although this drug is distinctly alkaline,
its presence in a mixture of hydrated starch and
saliva certainly does not suspend the action of the
amylolytic ferment, nor, so far as I can determine,
materially retard it.2 When, however, the iodide is
added, even in very small amount, to a mixture of
artificial gastric juice and egg albumen or fibrin, the
rapidity of peptone formation, as determined Jby the

1 Randolph : Verbal Communication on Differences be-
tween Raw and Boiled Milk.— Proc. Acad. Nat Sci. of
Phila., 1884, p. 120.

2 Langley & Eves, Jour, of Physiology, iv., p. 19, have
shown that although a distinctly alkaline medium retards
salivary action, the presence of a proteid body in the digest-
ive mixture will prevent this retardation.

4

38 Notes from the Physiological Laboratory

nascent mercuric iodide reaction * or by the biuret
reaction and control test, is greatly diminished.
This result is not due to a slight diminution in the
acidity of the solution, caused by the addition of
an alkaline body; for the same effect is noted when
the acidity of the solution is at once again brought
up to the normal degree. The pepsin is apparently
but little, if at all, affected by the presence of the
iodide, if we may judge by the indifference of
ptyalin to the drug, and by the fact that quantities
of the iodide corresponding to the maximal thera-
peutic dose neither entirely suspend the peptic ac-
tivity, nor induce greater retardation of the diges-
tion than do much smaller quantities. A slight
effect is exerted by the iodide upon the proteid
food-stuffs, evidenced in an increased toughness pro-
duced in, e.g., fibrin, and, when the drug is abun-
dantly present, in the acquisition by the albuminoid
of a slightly yellow tinge, due to staining by iodine,
which is liberated by the free acid of the artificial
gastric juice.

The most important factor in the delay of pep-
tonization lies in the power possessed by potassium

1 Kandolph : A Keaction Common to Peptone and Bile-
salts.— Proe. Acad. Nat. Sci. of Phila., 1884.

of the University of Pennsylvania. 39

iodide, even in relatively minute quantity, of pre-
cipitating acid albumen in solutions, which shall,
after its addition, possess the normal degree of
acidity of human or even canine gastric juice. The
same may be said of potassium bromide and of sev-
eral other analogous compounds. The precipitation
effected by the iodide is so complete that when solu-
tions of acid-albumen are thus treated and filtered,
the still acid filtrate yields no trace of proteid mat-
ter. This observation, which is doubtless old,
though I have been as yet unable to find it re-
corded, tends to show that the time at which the
administration of this drug is least liable to disturb
digestion is either during or immediately after the
ingestion of food.

There are several t sources of error in attempts at
deduction from the results of artificial digestion, as
ordinarily performed. Thus the continued activity
of a digestive fluid is largely conditioned by the re-
moval of the products of its action soon after their
formation. This occurs in the living viscus, but
not in the test-tube of the experimenter. The
maintenance of the normal temperature of the ac-
tive stomach is, of course, readily accomplished, but
the conscientious imitation of other factors in the
normal digestive process implies not only a constant

40 Notes from the Physiological Laboratory

mechanical intermingling of food-stuff and digestive
fluid, but the continued addition of small amounts
of the digestive fluid itself. I have nearly perfected
an apparatus which in a large degree obviates the
difficulties just cited.

In it artificial salivary digestions are conducted in
a thin tube of fish-bladder, closed at one end, which
is, by mechanical means, kept in gentle agitation.
The contents of this tube are maintained at the
proper temperature by a surrounding body of warm
water which is slowly but constantly changed. For
gastric digestions the animal membrane is substi-
tuted by one offering equally great surface for dial-
ysis, but resistant to peptic action. Despite, how-
ever, the inaccuracies attending existing methods of
study, the following deductions from the facts, old
and new, which are here presented, appear justi-
fiable.

I. That the earliest production of free acid
within the stomach is approximately three-fourths
of an hour after a meal ; its appearance being still
futher delayed by the ingestion of food in large
quantity.

II. That hydrobromic acid is liable to impede
the digestion of starchy foods when administered
with the interval just named ; and,

of the University of Pennsylvania 41

III. That iodide of potassium should be given at
such time and in such dilution that its absorption
shall be complete before the appearance of free acid
within the gastric contents.1

1 Since this paper was read, I find that Landois in the last
edition of his " Lehrbuch der Physiologic," 1885, p. 306,
accepts without question the results of Von den "Velden and
others here summarized. The same authority (p. 311) quotes
Fubini and Fiori as stating that potassium iodide impedes
gastric digestion. Chambers, in his " Manual of Diet," Phila-
delphia, 1875, p. 257, advises that potassium iodide be admin-
istered before meals, " as the mixture of the drug with food in
the stomach diminishes the efficiency of both."

42 Notes from the Physiological Laboratory

•VII.

ON THE DIGESTION OF RAW AND OF
BOILED MILK.

DK. N. A. RANDOLPH referred to certain pro-
found changes produced in milk by boiling. In
this operation the casein is not coagulated, but there
is an evolution of sulphuretted hydrogen (Schreiner),
a diminution in the gaseous constituents of the fluid
and a change in the amount of ozone present.

The most striking difference between raw and
boiled milk lay in their respective responses to
rennet and acids.

At the body-temperature the firm coagulation of
raw milk occurred almost immediately upon the
addition of a neutral rennet solution, whereas boiled
milk, under the same conditions, did not clot for a
far longer period, and the coagula were not firm.
On the other hand, dilute or strong acids were ten-
fold as active upon boiled as upon raw milk. Some
time after making these experiments Dr. Randolph
found that so far as acids and rennet were con-

• of the University of Pennsylvania. 43

cerned, similar results had been obtained by Schreiner
(Chem. Centralbl., III. Folge, IX. Jahrg.), and he
desired to present his observations in these particu-
lars simply as confirmatory of those of that observer.
Artificial digestions showed that milk was more
readily digested when raw than when boiled. This
was further confirmed by a comparative examina-
tion and weighing (in over fifty cases, and in which
he was aided by Dr. Roussel) of the contents of the
stomach after raw and boiled milk had been, in
different individuals, undergoing actual gastric di-
gestion. In these cases the residue found in the
stomachs of those persons receiving boiled milk was
greater than the similar residue found in the stomachs
where raw milk had been undergoing digestion for
the same length of time. [In obtaining the gastric
contents of the individuals under observation, tur-
peth mineral was used in the first series of eight
persons with most unsatisfactory results. It was
always thereafter substituted by hypodermic injec-
tions of apomorphia.]

44 Notes from the Physiological Laboratory

A STUDY OF THE NUTRITIVE VALUE OF
BRANNY FOODS.

FROM an economic stand-point the question of the
nutritive value of bran is one of great importance,
for the removal of this portion of the wheat implies
a loss of from 17 to 20 per cent, in the weight
of the grain. In spite of this loss, which neces-
sarily renders white bread more expensive than that
made from whole wheat-flour, even the poorest in-
habitants of most civilized countries where bread is
not the staple food, insist upon eating the bread
made from the finer grades of flour. A tendency
so widespread as this would apparently indicate the
unconscious summation of the experiences of many
generations, and go far toward proving the pro-
priety of such a selection.

The use of flour representing the entire wheat-
grain has, however, been long and ably advocated ;
the reasons given for the retention of bran being
that its removal entails the loss of, —

of the University of Pennsylvania. 45

I. " Nutritive salts" (Niihrsalze of Liebig).
II. Carbohydrates.

III. Proteids, notably gluten.

The facts, also, that branny foods in common
with many others will spur an atonic bowel to
activity, give due bulk to its contents, and induce
the passage of stools of the normal or feculent con-
sistency are noteworthy, but their further consider-
ation is beyond the limits of the present paper.
The other reasons for the retention of bran in wheat-
flour will be discussed seriatim.

I. The fact that fine flour contains a much smaller
percentage of salts than does either bran or the whole
wheat — a fact evidenced by the relatively small
amount of ash which it yields — forms the basis of
the theory of Liebig,1 that in the removal of bran
nutritive salts of value are lost. The investigations
of Meyer 2 and Forster 3 are often cited as showing
that after the removal of bran, these salts are still
present in quantity sufficient for the needs of the
economy.

Our experiments upon young pigs, described fur-
ther on, show that although survival is quite pos-

1 Chemische Briefe, 1851.

2 Zeitschrift f. Biologie, vol. vii. p. 33.

3 Ibid., vol. ix. pp. 293-380.

46 Notes from the Physiological Laboratory

sible upon an exclusive diet of bread from white
flour, growth is much more active upon a diet of
bread containing a greater amount of inorganic
matter. It is possible that Liebig's estimate of the
needful amount of inorganic matters was too high,
but it is equally noteworthy that there is a ten-
dency on the part of late writers to give insufficient
prominence to the importance of these elements of
food. It may not be out of place here to mention
a striking illustration of the absolute necessity for
inorganic salts in the fluids of the economy, as re-
corded by Dr. S. Ringer.1 This observer found
that while minnows were kept in ordinary tap water
they would live for weeks unfed. When, however,
they were placed in distilled water they died on an
average in four hours and a half. Further, that in
a rude imitation of spring water, made by the ad-
dition to distilled water of potassium and calcium
chlorides, and of sodium bicarbonate, the fish lived
on an average about two weeks. Study of the fac-
tors in the experiments showed that death was due
to a diminution of salts in the economy of the fish.
That such diminution, even when very slight, could

1 Journal of Physiology, vol. iv. No. vi., Feb. 1884, in the
appended Proc. Physiol. Soc., session Dec. 13, 1883.

of the University of Pennsylvania. 47

result fatally, was shown by an analysis of the dis-
tilled water after the death of the fish ; traces only
of inorganic matter being found.

II. The loss of carbohydrates involved in the
removal of bran, appears at first sight not inconsid-
erable, as it amounts to about 20 per cent, of the
carbohydrates present in the entire grain. The
members of this group represented in bran are
starch and cellulose. The former is present in ex-
tremely small amount, while the latter, as has been
proven by the experiments of Bonders,1 Mulder,2
and Poggiale,3 is digestible in any noteworthy
degree4 by the herbivora only. The observer last
named subjected a given weight of dry bran to the
successive actual digestions of two dogs and one hen,
and, thereafter, was able to recover over 65 per cent,
of its non-nitrogenous constituents. The loss in
cellulose was probably much less than that here in-
dicated, for we have found that during the macera-
tion of bran in the digestive tract, certain portions

1 Nederl, Lancet, vol. vi. pp. 227, 244.

2 Physiologische Chomic, p. 1024.

3 Comptes-Rondus, vol. xxxvii. p. 173.

4 See, also, Weiske (Centralblatt, No. 26, 1870), who finds
that a small percentage of cellulose, especially when cooked,
is dissolved in the human digestive tract.

48 Notes from the Physiological Laboratory

become detached from the main flake, and are with
the greatest difficulty recovered.

III. Wheat-bran contains a considerable but vary-
ing proportion of nitrogenous compounds, averaging,
however, about 14 per cent.1 This fact has per-
mitted the continued existence of two widely cred-
ited assumptions : (a) That this nitrogen exists in
albuminoid combination, or, in other words, is in a
nutritious form ; and (6) that the prote'id matter of
wheat is contained almost exclusively in specific cor-
tical cells of the grain, — the so-called " glu ten-eel Is."

(a) Nearly all the existing estimates of the pro-
portion of proteids in food-stuffs are based upon the
hypothesis that all of the contained nitrogen is
present in some albuminoid combination. The per-
centage of nitrogen in a given food is therefore as-
certained, multiplied usually by either 6.5 (Pay en)
or 6.33 (Ritthauseu) and the result recorded as the
percentage of proteid matter. It has lately been

1 Dempwolf, Ann. d. Chem. u. Pharm., vol. cxl. p. 343.
His figures, of interest here, are as follows : The amount of
nitrogenous matter in the whole wheat was 14 35 per cent.
The amount varied in the different grades of white flour from
11.01 to 15.56 per cent. The nitrogenous matter of the two
grades of bran made from this wheat was respectively 13.93
and 14.06 per cent.

of the University of Pennsylvania. 49

conclusively proven that nitrogen in non-albuminoid
combination — i.e., in compounds not capable of afford-
ing nourishment to any of the higher organisms — is
present in many food -stuffs, and especially in those
of vegetable origin. As a case in point may be
mentioned the analysis of AVigner,1 in which it is
shown that of the total nitrogenous matter of the
entire wheat-grain, 87.9 per cent, is coagulable, —
i.e., distinctively proteid. Of the bran only 42.4 per
cent, of its nitrogenous compounds are coagulable,
whereas, in the flour, 89.7 per cent, of these bodies
come under the head of true proteids. Yet more
marked instances of the inaccuracies attending the
ordinary methods of estimating proteids have be-
come evident in the course of researches by Schulze
and Barbieri,2 who find that of the entire nitrogen
of the potato but 56.2 per cent, enters into the com-
position of albuminoid matter, while in the fodder-
beet only 20 per cent, of its contained nitrogen is
thus combined, the remaining 80 per cent, aiding in
the formation of amides, nitrates, and ammonia. It
is evident from these facts that estimates of the nu-

1 Der oeslerr. ungar. Miiller, 1879, p. 52.

2 Quoted by Voit, Hermann's Hdb. d. Physiol., vol. vi. p.

462.

5

50 Notes from the Physiological Laboratory

tritive value of branny and other foods, based upon
the percentage of nitrogen present, must be received
with caution.

(6) The term "gluten -cell" is, through a wide-
spread misapprehension, applied to the cells consti-
tuting the fourth layer (Parkes) of the wheat-grain.
These cellular elements exist usually in a single
stratum, as irregularly cuboidal bodies in each of
which, surrounded by a dense and laminated cellu-
lose wall, is seen the semi-opaque granular contents.
Upon the addition of reagents, especially in the form
of caustic alkaline solutions, there is almost con-
stantly noticeable a differentiation of the contents
strongly suggesting the presence of a nucleus.
Under these conditions, also, a coalescence of many
of the individual granules forming the contents oc-
curs with the formation of several highly refractive
spheroidal bodies, an appearance which has led
Payen (as quoted by Dr. Richardson) to use the
name ole"if£res as a synonyme for the cellular constit-
uents of the fourth coat. The hypothesis that the
cells of this layer are the chief gluten-bearers of the
wheat-grain is usually attributed to Donders.1 The

1 Nederl, Lancet, iv. 739; vi. 227, 244. Third series, vol
i. 377.

of the University of Pennsylvania. 51

return of bran to flour was at about the same period
also advocated by Millon and Mege Mouries.1

From this time on, with but few dissenting voices,
the " gluten -cell" has been generally spoken of as
the index of the nutritive nitrogenous matter2 of the

1 Comptes-Kendus, vol. xliv. p. 47.

2 By general consent the albuminoids of the wheat-grain are
grouped together as gluten, which is>, however, further sepa-
rable into gluten-fibrin, gluten-casein, gliadin, and mucedin,
proteid bodies practically equal in nutritive value, but difler-
ing in certain physical properties, notably that of solubility.
It must therefore be borne in mind that in all methods of
separating gluten from the other constituents of the grain, its
(relatively small) soluble portion is removed with the starch,
and that any estimate of the quantity of gluten based upon
such methods will probably be belo\v rather than above the
actual amount. Kitthausen (Die Eiweiss-Korper der Ge-
treidearten, 1872) believes that a certain amount of true
albumen should be included with the constituents of gluten
just mentioned. An observation of Denis (^lemoire sur le
sang, 1859) confirmed by Hoppe-Seyler (Med. Chem. Unters.,
1867) and Weyl (Ber. d. deutsch. Chem. Ges., xiii. 10, 1880)
demonstrates that a portion of the proteids of the cereals
exists in the form of a globulin. Thus the observer last
named has shown that in wheat-flour trca'ted with a 15 per
cent, solution of sodium chloride, no formation of gluten
occurs. We have found that bran, when macerated in 15 per
cent, salt solution, yields a considerable amount of proteid
matter precipitable by nitric and picric acids. "VVe inclii.e

52 Notes from the Physiological Laboratory

wheat grain, while the central portion included
within this layer, and constituting fully 80 per cent,
of the grain, has been popularly regarded as being
made up almost exclusively of cellulose and starch,
and attempts have even been made to estimate the
nutritive value of certain cereal food-stuffs by a
microscopical determination of the proportion of
" gluten-cells" present.1

The manifest impropriety of such methods has of
late been strongly emphasized by Prof. Richardson,
of this city, and Prof. Leeds, of Hoboken. The
credit of the first disproof of the exclusive limita-
tion of gluten to the cells of the fourth layer is
probably due to Schenk,2 who treated sections of
wheat-grain with Millon's reagent, a pink coloration
of the endosperm resulting. This coloration was
most vivid at the periphery, indicating a gradual
condensation of the proteid constituents of the grain
as the cortex was approached. The same writer
found ."no coloration of the ' gluten-cells7 as a
result of this reagent/7 an observation which we
cannot confirm; for, apart from the readily demon-

to believe, however, that this is not a true albumen. (See
Vines, Journal of Physiology, vol. iii. p. 93.)

1 E. Cutter, M.D , Gaillard's Med. Journ., Jan. 1882.

2 Anat.-Physiol. Untersuch., p. 32, Wien, 1872.

of the University of Pennsylvania. 53

strable slight coloration of the contents of "gluten-
cells" after the application of Millon's reagent, it is
more than difficult to conceive a cell, however spe-
cialized, which shall exhibit no proteid matter as a
portion of its contents. Schenk also noted in arti-
ficial gastric digestions of sections of wheat, that
the starch-granules which (to a great extent) fill
the cells of the central portion of the grain became
detached, and from this fact deduced the just propo-
sition that the starch-granules lay imbedded in some
albuminoid substance. In a study of the distribu-
tion of gluten within the wheat-grain,1 the senior
writer has described several methods for the ocular
demonstration of gluten, in very considerable
amount, in that portion of the grain included
within the fourth layer, and entirely independent of
the "gluten-cells." The methods were as follows:

If whole wheat-grains be macerated in water, to
which a few drops of ether have been added to pre-
vent germination, they will in a few days become
thoroughly softened, and the contents of each grain
may then be squeezed out as a white, tenacious mass.

Examination of the remaining bran shows the

1 Randolph, Tree. Acad. Nat. Sci., Philadelphia, Dec. 11,
1883, p. 308.

5*

54 Notes from the Physiological Laboratory

"gluten-cells'7 undisturbed, closely adhering to the
cortical protective layers.

By now carefully washing the white extruded
mass, the major part of the starch may he removed;
and, upon the addition of a drop of iodine solution,
microscopic examination shows numerous net-works
of fine yellow fibrils, still holding entangled in their
meshes many starch-granules, colored blue by the
iodine.

In carefully washed specimens, the sponge-like
net-works are seen to retain the outline of the central
starch-filled cells, and evidently constitute the pro-
toplasmic matrix in which the starch -granules lay.
Upon gently teasing such a specimen under a mod-
erate amplification, the fibrils will be seen to become
longer and thinner in a manner possible only to
viscid and tenacious substances, — a class represented
in wheat by gluten alone.

An eminently satisfactory proof of the proteid
nature of these central net- works may be obtained
by heating the specimen in the solution of acid
nitrate of mercury (Millon's reagent), when the
fibrils will assume the bright pink tint characteristic
of albuminoids under this treatment. The results
of the application of the xanthoproteic and biuret
reactions are equally conclusive, but more care is

of the University of Pennsylvania. 55

required in the use of these proteid tests, aud the
resultant differentiation is not so clear. Reticuli,
similar to those above described, but much broken
and consequently far smaller, may be seen upon
close examination scattered through fine white flour,
without the use of any reagent.

In even the thinnest sections of the wheat-grain,
the gluten of the central portion is always masked
by large numbers of starch -granules. These may
to a large extent be removed by immersing the
section for a short time in liquor potassae, with
subsequent careful washing. The alkali effects the
hydration and partial solution of the starch ; but if
its application be too long continued, the gluten will
also be dissolved. This treatment is well adapted
to show the rather dense gluten net-works usually
found adherent to bran immediately below the
fourth layer.

The most satisfactory method of studying the
distribution of gluten in sections of wheat is that
of artificial salivary digestion. If the section be
gently boiled for a moment to hydrate, the starch
then transferred when cool to filtered saliva, and
maintained for from half an hour to an hour at a
temperature of about 98° Fahr., all the starch will
be dissolved, while the insoluble proteid and other

56 Notes from the Physiological Laboratory

constituents will remain in situ, and entirely unal-
tered. The same result may be obtained from a
somewhat more prolonged digestion of the unboiled
section. A section of wheat-grain thus treated will
exhibit throughout its entire central portion close-
meshed gluten net-works, which become slightly
denser toward the cortex of the grain. The pro-
teid character of these reticuli is here, as in the first
method, susceptible of micro-chemical demonstration.
Upon the application of Millon's reagent to such a
section, a relatively very faint coloration, indicating
the presence of albuminoids, is noticeable in the
"gluten-cells," while the gradual condensation of
the gluten of the endosperm, as the fourth layer is
approached, is evident even to the unaided eye.

The fact that the gluten net-works become denser
toward the periphery of the endosperm, together
with the presence of non-albuminoid nitrogenous
compounds in the perisperm, explains the notable
percentage of nitrogen found in bran as ordinarily
roughly removed.

The small proportion of albuminoids present in
the cells of the fourth layer as evidenced by their
feeble response to the proteid tests, together with
the very considerable quantity of gluten which we
have shown to exist in the central four-fifths of the

of the University of Pennsylvania. 57

grain (i.e., the portion lying within the fourth
layer), justifies us in the conclusion that by far the
major portion of the nutritious nitrogenous matters
exist in entire independence of the "gluten-cells."

The difficulties which attend the complete isola-
tion of these cells, however, have as yet rendered
impossible any accurate estimation of the proportion
of their proteid contents. Admitting for the mo-
ment that the "gluten-cells" contain albuminoids in
any noteworthy amount,1 there are yet present con-
ditions which seriously affect if they do not entirely
nullify the nutritive efficiency of this portion of the
grain.

The first of these conditions is the presence of the
rough bran-scales, which, by increasing peristalsis,
so hasten the passage of the entire intestinal con-
tents that complete digestion and absorption are pre-

1 Apart from the statement of Schcnk, above cited, the en-
tire absence of gluten in the cells of the fourth layer has been
latterly affirmed by Mege Mouries, who is quoted by Payen
(Substances Alimentaires) to the effect that these cells are
" filled with nitrogenous substances, of which gluten is not
at all one." He finds the cells in question to contain, in ad-
dition to the salts of magnesium, lime, and p»tasb, a peculiar
diastatic ferment, cereulin, whose function is the transforma-
tion of the starch of the grain into dextrine and glucose for
the nourishment of the germinating seed.

58 Notes from the Physiological Laboratory

vented. The second is that, owing to the dense cel-
lulose walls of the "gluten-cells," their contents are
practically unaffected by the digestive juices. The
fact that the presence of branny scales in the diges-
tive tract prevents the thorough digestion of the in-
testinal contents, and induces the passage of faeces
containing a considerable excess of undigested nitro-
genous matter, is fully attested by the observations
of Meyer and Rubner.1 Edward Smith2 has also
closely studied the economic phase of this subject,
and reports most unfavorably upon the use of
branny foods, stating that the diminished absorption
of nutritive matters, entailed by their use, more than
counterbalances the (apparent) gain in cheapness.
Of interest in this connection is the observation of
Fr. Hofmann,3 who noted that the amount of fa3ces
passed upon a meat diet was remarkably increased
by the addition of cellulose to the food taken.

The feeble response of the "gluten-cell" to re-
agents and digestive juices has been noted by several
observers. Thus Bonders4 states that these bodies
are digested by the herbivora, but not by dogs or

1 Zeitschrift f. Biologie, vol. vii., ibid., xix. 1883, p. 46.

2 "Foods," 1875, p. 175.

3 Yoit, Sitzgsber. d bayr. Acad., Dec. 18G9.
* Physiologic (German ed.), p. 273.

of the University of Pennsylvania. 59

man. Similar results are recorded by Poggiale,1
and for domestic fowls by Meissner and Fliige.2 J.
Lehmann3 records the feeding of pigs for thirty-
two days on bran which contained almost no flour,
with a nearly negative gain in weight, although
the bran contained 15.5 per cent, of nitrogenous
matters.

The ability of herbivora to digest "gluten-cells"
and similar bodies is probably due to the relatively
powerful amylolytic ferments of their digestive fluids,
for it has been demonstrated that pepsin is unable to
traverse cellulose.4 It has also been shown by one
of us5 that the cells of the fourth layer are, to all
appearance, entirely unaffected by prolonged artifi-
cial digestions, — salivary, gastric, and pancreatic, —
and further that their contents were but little
changed, and their walls in nowise disintegrated
by immersion for some days in strong acids and
alkalies.

1 Comptes-Rendus, 1853.

2 Zeitsch. f. rat. Med., vol. xxxi. p. 185, and vol. xxxvi. p.
184.

3 Amtsbl. f. d. Handl. u. wer. d. K5nigr. Sacbsen, 1868,
No. 2.

4 Hammersten, Jabresber. d. Tbierchemie, vol. iii. p. 207.

5 Randolph, Proc. Acad. Xat. Sciences, 1883, p. 311.

60 Notes from the Physiological Laboratory

Lately, however, in the course of an admirable
paper upon the nutritive relations of gluten, Rubner1
has stated that, although branny foods increase the
amount of nitrogen in the faeces, fully three-fourths
of the nitrogenous matter of bran is digested. In
the bran used there was present 4 per cent, of nitro-
gen, "equalling 25 per cent, albuminoids," while
in the bran obtained from the faeces of the persons
tinder observation only 0.9 per cent, of nitrogen was
obtainable. We hesitate in criticising the results of
so able an observer, but it seems to us that there
were two sources of error in this portion of his
investigation. In the digestion of bran the free,
adherent gluten, which properly belongs to the more
central layers, is, of course, readily dissolved, with a
consequent reduction in the nitrogen of the bran.
Apart from this, however, a loss in nitrogen is to be
expected, from the diffusion of nitrogenous crystal-
loids. Further, the "gluten-cells" become so sepa-
rated from the true bran, during their maceration in
the intestinal contents, that it is nearly, if not quite,
impossible to recover them.

In order to satisfy ourselves regarding the diges-
tibility of the cells of the fourth coat, we have

1 Zeitscb. f. Biologie, vol. xix. 1883, p. 46.

of the University of Pennsylvania. 61

subjected bran with its adherent "gluten-cells" to
actual digestion by twelve well-nourished adults, six
males and six females. These twelve persons were
selected from a larger number by excluding all
whose fseces exhibited under microscopic examina-
tion any inefficiency in the amylolytic and proteo-
lytic digestive ferments as evidenced by the presence
of starch or muscle fibre in more than a minimal
amount. Sources of error arising from individual
peculiarities having been eliminated by the number
of persons under observation, and the best conditions
for digestion having been obtained, these persons
then received daily for three days, in addition to
their regular food, one ounce of thoroughly boiled
bran. Their fasces for the last two days of the
treatment were submitted to close microscopical ex-
amination, with results so nearly uniform as not to
require tabulation. In every case the number of
"gluten-cells'7 present was more than sufficient to
render a diagnosis of the food taken a matter of
great ease. In two-thirds of the cases no evidences
of disintegration of any of the cells could be found
upon repeated examination of many fields from each
specimen. In four cases a small proportion (less
than 10 per cent.) of the numerous cells examined
showed evidences of having been affected by the

G

62 Notes from the Physiological Laboratory

digestive process, the cell contents having become
lighter in color and less opaque. If, however, any
true digestion of the cells had occurred, it is evident
that many of these elements in different stages of
disintegration would have been seen.

As a rule, we found that the several layers of the
bran presented an appearance not of having been
digested, but simply of having been subjected to
prolonged maceration. Thus the three coats of the
true bran while entirely unchanged were frequently
found separated from each other. We had expected
to find the fourth layer closely adherent to the third,
as is the case in dry bran, but in the majority of
specimens these two coats became separated, and
occasionally large sheets of "gluten-cells," to all
appearance perfectly normal, were seen. As a rule,
however, that portion of the faecal mass representing
the meal at which bran was taken1 was found to
contain these thick-walled cells in nearly every
field.

1 We did not find it needful to give with the bran any col-
oring matter to differentiate in the fasces the meal at which it
was taken, as the scales of bran were always a sufficient in-
dex. "When requisite, such differentiation may readily be
obtained by the method of Cramer (Zeitschr. f. Physiol.
Chem., vol. vi. p. 354), or that of Kubner (1. c.).

of the University of Pennsylvania. 63

A study of the nutritive relations of a given food
may be approached from three sides: First, from
that of the exact chemical composition of the food,
a knowledge absolutely essential to any scientific
scheme of diet. Second, from that of the various
excretions of the individual or animal upon the
diet in question ; and, third, from the more clinical
stand-point of study of the effects exerted by a given
diet upon the growth and nutritive processes of the
organism under observation. After an examination
of branny food in the light of the first two methods,
we attempted its study by the third. To this end
six young pigs of the same litter, and all in fair
health, were weighed and placed under the same
conditions in pairs in three separate bins. Those in
the first bin daily received bread especially made
from whole wheat-flour, in amount corresponding to
one-fourth pound of dry bread each. To those in
the second bin was given a corresponding amount of
bread made from wheat whose three external coats
only had been removed. The pigs in the third
bin received the best white bread in amount cor-
responding to the standard above mentioned. A
sufficient (fixed) quantity of water was given twice
daily. The following table shows the weight of
eacli pair at the beginning of the observation, and

64 Notes from the Physiological Laboratory

at the end of respectively ten and thirty-two days
thereafter :

-•J
ja

— :D

o

«

%

M«J

it ^2

Q

To

e

OJ ^

'3 JH

'I »--

Bin.

Age.

Food.

*£

'?!>

h

!l

1«

.11

la

.z -^»

.=«

? s*

•^ ^

5

9

o

o

o

>-»

!-S

1-5

^

•-S

Weeks.

Lb».

Lbs.

ZA«.

its.

£&«.

I.

6

Broad from whole wheat.

24.5

29.0

4.5

:«.25

8.75

II.

6

("Brown luvad from de-)
| corticated wheat j

24.75

28.25

3.5

34.50

975

III.

6

White bread

25.25

27.25

2.0

33.0

7.75

Comparison of these weights exhibits curious and
apparently contradictory results, viz., that during
the first ten days the gain was greatest in the pigs
fed upon whole wheat bread, whereas at the end of
thirty-two days of such feeding the gain was most
pronounced in the pigs fed upon bread made from
wheat whose three outer coats had been removed.
The cause of this variation in results is not far to
seek. At the commencement of the experiments
the animals were small, and the food given was in
each case more than sufficient to replace the waste
in both the tissues and circulatory fluids. Even the
pair fed upon bread containing the innutritious and
waste-inducing bran, digested and absorbed suffi-
cient proteid matter to supply the needs of the
tissues, and normal growth was also favored by the

of the University of Pennsylvania. 65

presence of a bulky intestinal contents of a mechan-
ically stimulating nature, and also by the nutritive
salts which were present in this bread in larger
amounts than in others. On the other hand, at the
end of the thirty-two days the animals had notably
increased in size; the food given was then barely
sufficient for the needs of the economy, and any
conditions impeding its complete digestion and ab-
sorption produced a notable effect upon the rate of
growth of these young animals.

It must be borne in mind that these experiments
relate only to the value of the different breads when
taken alone to the exclusion of other foods. The
experiments of Rubner before cited leave no doubt
that a white bread contains more assimilable nutri-
ment than does one made from the whole wheat,
but this does not render it a desirable food-stuff for
exclusive use. On the contrary, a weaned, but still
quite young omnivorous mammal thrives better
upon an exclusive diet of bran bread than on white,
and, presumably, because the earthy and alkaline
salts are present in greater abundance in the former,
and, also, because the indigestible constituents tend
to give to the intestinal contents that bulk and con-
sistence which are essential to the hygiene of the

digestive tract. But, as has been shown by Edward
6*

66 Notes from the Physiological Laboratory

Smith and others, the branny scales are needlessly
irritating, and unduly hasten the passage of food1
but partially digested and absorbed. The end which
popular hygiene attempts to effect by the retention
of bran in breadstuff's can be better attained by other
means. Thus the nutritive salts of food so fre-
quently lost in ordinary methods of preparation are
readily restored by the concentration of the liquor
in which meats and vegetables are cooked into a
soup stock, as is practised in almost every French
kitchen. Again, the various fresh green vegetables
used as salads yield in abundance these inorganic
food-stuffs, the presence of which we have seen is
indispensable to normal tissue activity. A further
advantage of these and other .succulent vegetables
lies in the fact that their cellulose, while efficient in
giving proper bulk and consistence to the stools, is,
as compared with bran-scales, soft and unirritating
to the digestive tract.

From the facts, old and new, which have been

1 An observation worthy of mention in this connection is
that of Kubner, who finds that while the presence of much
woody fibre and harder cellulose in the intestinal contents
induces the passage of stools containing an excess of undi-
gested proteid foods, the absorption of fats under the same
conditions is not materially affected.

of the University of Pennsylvania. 67

presented, the following deductions appear to us
justifiable:

I. The carbohydrates of bran are digested by
man to but a slight degree.

II. The nutritive salts of the wheat-grain are
contained chiefly in the bran, and, therefore, when
bread is eaten to the exclusion of other foods,
the kinds of bread which contain these elements
are the more valuable. When, however, as is
usually the case, bread is used as an adjunct to
other foods which contain the inorganic nutritive
elements, a white bread offers, weight for weight,
more available food than does one containing bran.

III. That by far the major portion of the gluten
of wheat exists in the central four-fifths of the
grain, entirely independent of the cells of the fourth
bran-layer (the so-called "gluten-cells"). Further,
that the cells last named, even when thoroughly
cooked, are little if at all affected by passage
through the digestive tract of the healthy adult.

IV. That in an ordinary mixed diet the reten-
tion of bran in flour is a false economy, as its pres-
ence so quickens peristaltic action as to prevent
the complete digestion and absorption not only of
the proteids present in the branny food, but also of
other food-stuffs ingested at the same time; and,

68 Notes from the Physiological Laboratory

V. That inasmuch as in the bran of wheat as or-
dinarily roughly removed there is adherent a note-
worthy amount of the true gluten of the endosperm,
any process which in the production of wheaten
flour should remove simply the three cortical pro-
tective layers of the grain would yield a flour at
once cheaper and more nutritious than that ordi-
narily used.

of the University of Pennsylvania. 69

IX.

A METASTATIC HEAT REGULATOR.

THE instrument about to be described is adaptefl
to maintain a constant temperature within any water-
or air-chamber heated by gas, the degree of temper-
ature thus maintained being adjustable at will.

Reference to the illustration shows an air-ther-
mometer so modified that the rise of mercury in the
limb B will cut off the gas-supply which passes
through its bifurcated extremity. A second modifi-
cation lies in the accurately-fitting glass stop-cock
D, connected with the air-chamber A. By means
of this stop-cock the tension of the air within the
chamber, and consequently the height of the mer-
cury in the tube B, is readily adjustable. It is evi-
dent that when the mercury is forced high up in B,
a relatively slight increase in the temperature of the
surrounding medium will be sufficient to so expand
the air in A as to force the column of mercury to»
the point of shut-off. On the other hand, a far
higher temperature will be needed to effect the

70 Notes from the Physiological Laboratory

shut-off when the columns of mercury in A and
B are of the same height. In practice the adjust-
ment is effected by placing the instrument in a me-
dium of the required temperature, the cock D is
opened, and air slowly forced in with a syringe,
until the mercurial column in B is nearly at the
point of bifurcation ; the precise height varying, of
course, with the dimensions of the instrument, and
being readily ascertained by practice.

The pressure of the gas employed must be kept
quite low, otherwise, as the mercury rises above the
point of bifurcation, a portion will be blown out.
One of the simpler gas-pressure regulators may be
advantageously inserted between the source of gas-
supply and the heat regulator. It is wrell also
that the diameter of the limb C should be some-
what greater than that of its fellow, and also that
its point of junction with B should be somewhat
constricted in order that a smaller variation in tem-
perature shall effect either the patency or occlusion
of the gas exit.

When the mercury rises in B a trifle beyond the
point of bifurcation, the passage of gas from G to
E is arrested, and the flame from the burner I is
at once extinguished. Were no further provision
made, the vessel and its contents would soon cool

of the University of Pennsylvania. 71

sufficiently to again permit the flow of gas, which
would then pass off, unburnt, through I. This dif-
ficulty is obviated by the use of a second gas-jet, J,

so placed as to re-light the burner I, upon the re-
newed passage of gas, and so minute as not to give
out sufficient heat to counterbalance that which is
lost from the vessel by radiation, etc., during the

72 Notes from the Physiological Laboratory

temporary stoppage in the main jet. This second-
ary jet may be readily made from a common brass
blow-pipe, bent in the form shown in J, and
steadily supported in such manner tjiat its little
flame may constantly play immediately above the
opening of the main burner. It is usually neces-
sary to still further reduce the small opening of the
blow-pipe by squeezing it with pliers, or by other
means. The secondary flame is fed by a branch, H,
from the source of gas-supply.

The instrument must be protected from touching
the base of the containing vessel either by suspen-
sion or by the intervention of a plate of cork or
other non-conductor. It must also be held steadily
vertical, and should always be accompanied by a
thermometer to verify its adjustment. It is also
well to have each of the exposed surfaces of mer-
cury covered by a drop or two of glycerine to pre-
vent oxidation.

of the University of Pennsylvania. 73

x.

ON THE BEHAVIOR OF PETROLATUM IN
THE DIGESTIVE TRACT.

THE mixture of hydrocarbons, recognized by the
pharmacist under the name of petrolatum, and pop-
ularly used under the commercial names of cosmo-
line or vaseline, presents, on superficial inspection,
few points of difference from some of the organic
fats of the same consistency. Close examination re-
veals differences, both in physical properties and in
chemical constitution, between the bodies just com-
pared. One point of difference, which I have as yet
been unable to find recorded, lies in the respective
behavior of these two groups when in contact with
the absorbent surfaces of the digestive tract. Tims,
while the organic fats, as ordinarily taken in food,
are readily and almost completely absorbed, this soft
paraffine is entirely rejected, and found unchanged
in the faeces.

During eight days I took, daily, one-half ounce

7

74 Notes from the Physiological Laboratory

of commercial vaseline, in addition to my regular
diet. Digestion was in nowise altered, and no ap-
preciable results ensued. Later, two healthy adults
each received, in the course of forty-eight hours, one
ounce of vaseline. Their alvine dejections for three
days from the beginning of this observation were
collected and dried, and, at the suggestion of Dr.
John Marshall, of the University of Pennsylvania,
extracted with petroleum ether. Making a slight
allowance for incompleteness in extraction, the vase-
line ingested was, in each case, recovered in its to-
tality, showing* that it had passed through the econ-
omy unchanged and unabsorbed.

There are some important medical applications of
these facts, the discussion of which would be out of
place here, and which I reserve for further experi-
ment;1 but the following deductions appear permis-
sible, and are of strictly biological interest :

I. Pure petrolatum, while entirely unirritating to
the digestive tract, is valueless as a food-stuff.

II. The results of the experiments here described
lend support to the theory that oleaginous matters

1 The chief medical use of these facts lies in the adminis-
tration of vaseline as a bland emollient to the intestinal sur-
face. I have in several individuals succeeded in checking
diarrhoeas of irritation by this simple means.

of the University of Pennsylvania. 75

are dependent for their absorption, not upon mechan-
ical, but upon vital activities, and that in such ab-
sorption the selective power of the protoplasm of the
intestinal epithelium is manifested.

76 Notes from the Physiological Laboratory

XI.

CUTANEOUS ABSORPTION OF NICOTINE.

DR. N. A. KANDOLPH described the results of a
series of experiments performed by Mr. Samuel G.
Dixon and himself, relative to the absorption of
nicotine by the uninjured, healthy skin of the liv-
ing rabbit. In these experiments only rabbits of
ascertained good health were used. The fur of the
abdomen was carefully clipped (not shaved); suffi-
cient time, usually seven days, being allowed to in-
tervene between this operation and the application
of the drug to the skin, thus permitting any slight
scratch made at this time to fully heal. The absence
of cutaneous lesion was further confirmed by close
examination under a strong hand-magnifier. The
drug was then applied to the skin, no friction being
used. In order to preclude the possibility of its
vaporization and subsequent absorption by the lung-
surface, the nicotine was placed upon an adhesive
plaster, the backing of which was made of sheet-
rubber. The plaster, with the drug in its centre,

of the University of Pennsylvania. 77

was then applied in the open air, on a windy day.
Different doses were applied ; thus, in one case, one
drop of nicotine, applied to the skin, caused death in
five hours and eleven minutes. In each of three
cases a similar application of ten drops was fatal in
respectively one hundred and nine minutes, twenty-
eight minutes, and thirty-six minutes. In the fifth
case, a similar application of fifteen drops of nicotine
caused death in twenty-eight minutes.

Of the ante-mortem symptoms, contraction of the
pupil was constant, and often appeared very quickly.
Other prominent symptoms were great trembling,
with subsequent loss of muscular power in the
extremities. In one case actual convulsions were
noted, and in others, coldness of the skin and in-
creased lachrymal and nasal secretion. Immedi-
ately upon the death of two of the animals (after
the ten- and fifteen-drop doses respectively) blood
was removed, defibrinated, and tested with mercuric
chloride for the presence of nicotine in the manner
detailed by Wormley (Micro-Chemistry of Poisons).
In each of these two instances characteristic groups
of crystals were found upon microscopic examination
of the extract from the blood.

78 Notes from the Physiological Laboratory

XII.

ON THE DIETETIC FACTOR IN THE TREAT-
MENT OF ANGINA PECTORIS.

THERE has recently been under my care a patient
suffering from true angina, in whom, as is not seldom
the case, any slight gastric irritation constituted the
immediate exciting cause of the frequently-recurrent
paroxysms.

After the last attack there existed an inability to
retain the lightest and simplest foods, their ingestion
inducing not only nausea, but much cardiac distress.
Eecourse was had, with advantage, to milk, par-
tially digested by the commercial Extractum Pan-
creatis ; but the flavor of the resultant preparation
was unappetizing, and finally became repulsive to
the patient, who whimsically described its taste as
that of " stewed corpse."

To meet this emergency, there were devised two
food products, which I have not seen described, and
which, in practice, proved eminently satisfactory.

1. Pancrcatized Oysters. — The oysters of an or-

of the University of Pennsylvania. 79

dinary stew (containiDg milk) are removed and
finely minced, then returned to the liquid portion
of the stew. The whole is brought to a temperature
of 100° F., the appropriate proportions of pancreatic
extract and sodium bicarbonate are added, and the
mixture maintained at the temperature mentioned
for thirty minutes, with occasional stirring. It is
then strained and served, and forms not only a
highly nutritious and palatable soup, but one which
is retained by very irritable stomachs, and utilized
with a minimum of digestive power. After boiling,
to prevent the further action of the digestive fer-
ment, gelatine may be added, and the mixture served
cold as a jelly. Cooked tomato, onion, celery, or
other flavoring suited to the individual taste of the
patient, may be added at the beginning of the arti-
ficial digestion, and the solid residue removed in the
final process of straining, at which time it will be
noticed that the minced oysters originally added
have been in great part dissolved.

2. Pancreatized Milk-toast. — Ordinary milk-toast,
in which there is an abundance of milk, when
digested in the manner just described," becomes an
almost homogeneous pulpy mass, which, when the
crusts have been removed, is usually acceptably
retained by the irritable stomach. In extreme cases,

80 Notes from the Physiological Laboratory

however, it may advantageously be strained and the
fluid portion alone used, in which the partially pep-
tonized solution of casein of the milk is reinforced by
actually digested gluten and starch of the bread,
together with a very little dextrin. Plain, light
sponge-cake may be similarly digested, and occasion-
ally forms a desirable change.

In conclusion, I would express the hope that
these rather homely suggestions may prove of value
in other hands, in extending the somewhat scanty
bill of fare suited to patients suffering from gastric
hypersesthesia, and the various neurotic troubles of
which such a condition may be the exciting cause.

of the University of Pennsylvania. 81

XIII.

A PAINLESS ESCHAROTIC.

IN view of the rapidly growing literature of
cocaine it is not impossible that the application
which we here briefly describe has already been
employed ; but, if so, it has escaped our scrutiny
of the later developments regarding this drug.

When a saturated solution of cocaine hydrochlo-
rate in strong nitric acid is applied to the uninjured
skin, the ultimate result is precisely that which
would occur upon the similar application of pure
nitric acid, but the time required for the formation
of a deep eschar is considerably longer in the former
than in the latter case.

We have experimented with the mixture just
mentioned upon several individuals, ourselves in-
cluded, and can safely say that the sensations
attending its application cannot be accurately de-
scribed as painful. There is, however, a slight
pricking sensation soon after the mixture is first
dropped upon the skin.

82 Notes' from the Physiological Laboratory

Upon one person a control-experiment was insti-
tuted in the following manner: Upon his right arm
were placed four drops of strong nitric acid, while
upon the same point on his left arm was similarly
disposed the'sarne quantity of the mixture of nitric
acid and cocaine hydrochlorate. The pure acid
caused great pain, and was speedily removed ; the
mixture, which was applied later, caused a sensation
described as "tickling, with slight pricking," which
soon passed away.

In two cases the burned points were covered with
absorbent cotton wet with a two per cent, solution
of cocaine salicylate, a salt which we have not yet
seen described, but which, in addition to the pecu-
liar properties of its contained alkaloid, appears to
be somewhat antiseptic. There has been no discom-
fort after the formation of the eschar. Prof. Harri-
son Allen, to whom we presented a portion of our
solution of the salt last mentioned, kindly reports
that he has applied it several times in his practice
as a substitute for other salts of cocaine, with good
results.

of the University of Pennsylvania. 83

XIV.

A NOTE ON THE CUTANEOUS ABSORPTION
OF SALICYLIC ACID.

Ix view of the fact that the internal administra-
tion of salicylic acid and its salts is not infrequently
capable of producing or increasing gastric irrita-
bility, the advantages of inducing its cutaneous ab-
sorption are at once apparent. By the application
to the uninjured skin of salicylic acid, rubbed up in
a thin paste with olive oil, we have been able to
demonstrate the presence of the drug in the urine in
each of seven cases in which such application was
made. In six of these cases, an existing rheumatic
attack was relieved by the application. Of these, in
one case only did the application give a negative
result.

CASE I. — Man, set. 30, of rheumatic habit, who
had been suffering for three days from rheumatic
pains and stiffness in the right thigh. The pain had
grown daily worse, until motion of the limb became

84 Notes from the Physiological Laboratory

almost unbearable. He was ordered to remain in
bed, and twenty grains of salicylic acid were rubbed
into a paste with olive oil, and gently smeared in
each axilla. Four hours thereafter, the patient felt
somewhat better; and the urine examined at this
time showed the presence of the drug upon the ap-
plication of the ferric chloride test. At noon, on
the following day, the patient reported himself as
entirely well.

CASE II. — Female, set. 60, suffering from fre-
quently-recurrent and severe rheumatic pains in the
shoulder. The method of treatment used in the
preceding case was here employed, and the patient
reported marked relief on the following day, at
which time, also, the drug was found in her urine.

CASE III. — Female, set. 28. Rheumatic pains
in arm and shoulder. Application as in previous
cases. The drug here proved a decided irritant to
the very sensitive skin, and was removed in some
fifteen hours. Results negative. Urine not exam-
ined. Pain and stiffness subsequently disappeared
after the exhibition of large doses of sodium sali-
cylate internally.

CASE IV. — Male, set. 25, frequently subject to
rheumatism in the left shoulder, and always re-
lieved by the internal use of sodium salicylate ; was

of ike University of Pennsylvania. 85

relieved during a similar attack by the method
already described.

CASE V. — Male, at. 34, suffering with severe
rheumatic pains in left shoulder.

Thirty grains of salicylic acid were rubbed up in
olive oil, gently smeared upon the left side of the
abdomen, and covered with rubber-cloth. Here, as
in the other cases, the urine was tested for the drug
in question at the time that the application was
made, with negative results. Urine passed in one
hour and ten minutes thereafter gave, upon the ap-
plication of the ferric chloride test, the response
characteristic of the presence of salicylic acid ; and
this reaction was observed in several samples of
urine from this patient up to the thirty-sixth hour
after the application was made. In twelve hours
the rheumatic symptoms were greatly relieved, and
they entirely disappeared within twenty-four hours.

CASE VI.1— Dr. F., set. 29. Rheumatic swell-
ing of right knee, the circumference of which was
one-third greater than that of its fellow. Patient
gave history of previous persistent rheumatic at-

1 We are indebted for the report of this case to the cour-
tesy of Dr. William Gray, who pursued the method indi-
cated at our suggestion.

86 Notes from the Physiological Laboratory

tacks. Salicylic acid and oil (3ij to fSj) were
spread upon absorbent cotton, and the whole gently
wrapped around the knee, which was here too
acutely sensitive to permit of any friction. No
internal medication was used. In twenty-four
hours there was marked reduction both of pain
and swelling, and within three days the patient had
entirely recovered. During the treatment, swelling
commenced in the knee of the opposite side, but
disappeared under the same local treatment pursued
with the joint first affected. The urine was several
times examined during the treatment, and salicylic
acid found therein.

This case is of especial interest as indicating that,
superadded to the constitutional impress of the
drug, there was a specific local effect at the place
of its application.

We do not consider that the results of the six
experiments here cited would warrant us in an un-
qualified commendation of this method of exhibit-
ing salicylic acid, but we feel fully justified in
suggesting that a fair trial be given it by the
medical profession.

[The following brief statements summarize the
results of some of our experiments upon Cutaneous
Absorption, which are as yet unpublished.

of the University of Pennsylvania. 87

In general, drugs in solution in oil (not oleates)
are absorbed by the normal human skin with greater
or less ease. On the other hand, drugs in aqueous
solution are not so absorbed. Thus we have shown
that salicylic acid in oil is absorbed by the healthy
skin, whereas in the similar application of salicylate
of sodium, which is practically insoluble in oil, we
have never been able to obtain evidence of cutane-
ous absorption.

In this connection may be mentioned the fact,
which we believe has not hitherto been recorded,
that methyl salicylate (true oil of wintergreen) is
apparently absorbed by the human skin. If this
oil be gently rubbed over the arm, the presence of
salicylic acid in the urine is readily demonstrable at
the end of an hour after the application. We say
apparently absorbed, because the salicylate in ques-
tion is volatile, and consequently may be absorbed
by the lung surface. A series of control experi-
ments was instituted to determine this point. A
little pledget of cotton, saturated with oil of winter-
green, was suspended immediately beneath the nos-
trils in such wise that it did not come in contact
with the skin. The urine, which was found to be
free from salicylic acid at the beginning of the ex-
periments, constantly showed the presence of this

88 Notes from the Physiological Laboratory.

drug in from forty to fifty minutes thereafter. The
possibility exists that the specific therapeutic impress
of salicylic acid may be obtained by inhaling an
atmosphere impregnated with this volatile salicylate.
We hope to report upon this point in the near future.
The obstacles which prevent the cutaneous absorp-
tion of drugs in aqueous solution are the resistant
epiderm, and, much more important, the secretion of
the sebaceous glands. A very simple and efficacious
method which we have devised for removing these
obstacles consists in the addition of a proteolytic
ferment to the solution of the drug used. Thus
trypsin (prepared by Kiihne's method) is added to
a strong solution of (e.g.) morphia. Absorbent cot-
ton is saturated with the mixture, placed upon the
skin, and covered over with waterproof plaster.
The natural warmth of the part induces the activity
of the ferment and the consequent solution of the
epiderrn, narcosis supervening in from one to two
hours. This method, when applied under the super-
vision of the physician, affords one advantage over
ordinary modes of medication, namely, that when
the desired therapeutic effect'is obtained, the further
absorption of the drug may be prevented by at once
removing the external application.]