29 192J

TAUB

DISSERTATION.

QP

a.

Reprinted from THE AMERICAN JOURNAL OF PHTSIOLOQT
Vol. 69, No. 1, February, 1922

-OGlf

LIBRARY
G

STUDIES IN THE REGENERATION OF BLOOD1

ZALIA JENCKS

From the Sheffield Laboratory of Physiological Chemistry, Yale University,

New Haven, Connecticut

Received for publication September 8, 1921

Studies in the regeneration of blood after simple anemia have been
made on many species of animals and on man. Although various phases
of the growth of blood have been extensively investigated in connection
with destruction of the erythrocytes by chemical agents or specific
diseases, much less information is available regarding recovery from
the anemias produced by hemorrhage.

Many, if not most, of the earlier researches lack a convincing char-
acter because relatively few of the variables have been sufficiently
taken into account. Heretofore the work on blood regeneration has
been on animals whose dietary control was not complete. Inasmuch
as the more recent investigations of nutrition, conducted on laboratory
animals, have made it possible to control a variety of dietary factors,
only one variable will need to be taken into consideration for the dura-
tion of a particular series of experiments.

The present studies on albino rats were undertaken because of the
relatively large amount of information available concerning the dietary
requirements of these animals. The rat is small enough to make
possible the use of large numbers for. experimental purposes and it has
been employed as a laboratory animal for so many generations that
laboratory conditions do not make its confinement unnatural. Our
rats were from the colony of the Connecticut Agricultural Experiment
Station. They were kept on a standard synthetic diet2 while in experi-

1 Material for this paper was taken from the dissertation submitted for the
degree of Doctor of Philosophy, Yale University, 1921.

3 Standard diet used : per <**t

Cornstarch 50.5

Casein 18.0

Lard 18.0

Washed butter 9.0

Salt mixture 4.5

240

STUDIES IN THE REGENERATION OF BLOOD 241

mental use and during all of the time when they were not under direct
observation. This eliminated complications arising from having the
animals eat such complex mixtures as they would, had they been fed
table scraps.

Technique. The preliminary experiments were designed to discover
the limit of successful bleedings in the rat, the period for regeneration
of blood after hemorrhages, and to find the effect of the dietary factors
on such regeneration.

The rats on which hemorrhages were produced were kept in iron-wire
cages with paraffined tin cups for water and porcelain cups for food.
The methods and technique employed have been described by Miss
Ferry (1). The standard synthetic diet developed by the work of
Osborne and Mendel (2), (3), (4) and others was used as a basis for
all the dietaries employed. Adult and young animals of both sexes
were used, varying in average weight from 100 grams for the young
to 300 grams for the adults. The tables of Donaldson (5) were carefully
followed in estimating the blood volume of each experimental animal
used.

Experimental technique. The blood of every rat was carefully ex-
amined for the number of erythrocytes and percentage of hemoglobin
before any hemorrhages were made. The counts were checked in every
case during the first 2 months until the operator had attained sufficient
skill to make such duplications unnecessary. The method of blood
count was the familiar one with a Thoma-Zeiss hemocytometer and the
use of either Hayem's or Toisson's solution for blood dilution. Hemo-
globin was determined by the colorimetric procedure of Cohen and
Smith (6) . Rat blood was used as a standard and its color was checked
by fresh material at frequent intervals.

The sample of blood for examination was taken from a drop extruded
when the end of the tail was snipped. The rat was placed in an open
glass bottle, the bottom of which had been removed and a tin cap with
a hole for the tail placed over the opening; leather straps from the neck
of the bottle held the rat securely in this armor (see fig. 1). This
arrangement allowed free manipulation of the tail by the experimenter.
The skin of the tail was softened with mineral oil. Previous to removing
the end of the rat's tail it was placed in warm water or brushed over
with toluene in order to suffuse the blood vessels. There are four blood
vessels in the rat's tail, one dorsal, one ventral and two lateral. The
blood was obtained from these by manipulating the tail after the fashion
of milking and allowing the fluid thus "milked" out to drop into a

242

ZALIA JENCKS

tared glass dish. At the beginning of this series of experiments, hemor-
rhages of from one-third to one-half of the estimated total blood volume
were produced. After "milking out" 20 or 30 drops a clot usually
formed ; this was carefully wiped off with a previously weighed piece
of cotton and added to the blood in the dish. Then more blood was
worked out of the end of the tail. The blood and vessel were weighed
rapidly to centigrams — two or three times, if necessary — until at least
one-third of the whole blood volume contained in the rat had been
removed. This method which was laborious and unsatisfactory re-
sulted in occasional injury to the tail accompanied in some cases by

Fig. 1. This shows a rat held in the bottle so that the tail is exposed for
"milking" out blood.

infection. Frequently a second hemorrhage was desired before the
wound on the tail was completely healed. Because of this soreness
and the possibility of infection it often became impossible to obtain
a sample of healthy blood for cell count and hemoglobin determination.
Subsequently, therefore, the method used for obtaining blood from
guinea pigs in serum work was adopted.3 In this procedure blood is
secured directly from the jugular vein. The rat was anesthetized with
ether, the fur closely clipped from its neck, a slit about \ inch long made
in the skin, the jugular exposed, a v-shaped nick made in the vein with

3 Thanks are due my co-worker, Dr. W. G. Karr, for his kindly suggestion as
to use of this method and for his assistance in the first operations.

STUDIES IN THE REGENERATION OF BLOOD 243

scissors, and the animal held over a weighed glass vessel into which the
blood was allowed to drop. If care was exercised it trickled slowly and
in a well-directed stream and scarcely touched the fur. The blood was
allowed to flow into the dish up to the mark previously placed to indicate
one-third the estimated total volume of blood. By the time this had
run out a clot had usually formed. The clot was carefully and gently
wiped off from the wound with a previously weighed bit of cotton, and
this added to the blood in the dish, and the whole was then weighed.
If a clot failed to form the bleeding was stopped by pressing a small
(weighed) piece of cotton against the cut in the Vein. Ordinarily this
proved effective. If less than one-third of the (estimated) rat's blood
had run out by the time a clot had formed, it was easy to start the
bleeding again by harshly wiping the nick in the vein with a weighed
pledget of cotton; then more blood dripped and a second weighing
was made. This second bleeding was, however, seldom necessary.
The wound in the skin was then washed with dilute alcohol (25 per
cent) and sewed up. The rats recovered readily, the wound healing
in from 2 to 3 days in every case.

Blood counts and hemoglobin determinations were made daily until
the original values returned. During the period of regeneration frag-
mentary red cells were often seen in the blood, but as regeneration
proceeded these became fewer in number and finally disappeared alto-
gether. The number of leucocytes increased the first day or two after
the hemorrhage, but not in great abundance. As shown by Lamson (7)
the number of erythrocytes as well as the percentage of hemoglobin
varies among the individuals, but the drop after hemorrhage in each
case is comparable.

Criteria of regeneration. The return of the number of red blood cor-
puscles and the percentage of hemoglobin to the values noted before any
loss of blood had been sustained by the rat were the criteria used in
judging regeneration. These values remained approximately constant
for two successive days before the rat was considered to have regenerated
his blood. For normal animals of either sex fed on standard diet
(see footnote 2) with the addition of dried brewery yeast, the time was
from 6 to 9 days (table 1). This has been corroborated by the sub-
sequent studies of Geiling and Green (8) in this laboratory. At the
end of the period required for regeneration, in many cases a second
hemorrhage required about the same time for a return to normal blood
conditions. A third hemorrhage "was made on some of these rats, but
regeneration in such animals always needed more time. If, however,

244

ZALIA JENCKS

a week's time intervened between return to normal and the following
bleeding, the regeneration rate was normal. Similar experiences have
been recorded by Geiling and Green for double hemorrhages.

Blood regeneration in growing rats. To study the effect of loss of
blood on the growth of young animals bleedings were made on healthy
growing rats fed on the standard diet and brewery yeast as the adults
were fed, the hemorrhage procedure being the same as for the grown
rats. The time of total regeneration for these little rats was from 7 to
9 days (see table 2). After the hemorrhage they recovered quickly,

TABLE i
Blood regeneration in adult rats after a single hemorrhage on the standard diet

BODY WEIGHT

TOTAL BLOOD

AMOUNT OF
HEMORRHAGE

RED BLOOD
CORPUSCLES*

HEMOGLOBIN

TIME FOR
REGENERA-
TION

grams

grams

grams

per cmm.

days

220

130

5.5

9, 360, 000

91

10, 136, 000

104

7

210

12.5

5.5

9,472,000

100

9, 168, 000

87

9

272

15.7

5.5

8,256,000

94

9, 008, 000

87

8

310

17.5

7.0

9,264,000

104

9, 504, 000

91

6

250

14.5

5.1

9,500,000

110

9, 104, 000

98

7

210

12.4

5.0

9,000,000

94

9, 100, 000

96

7

300

17.4

5.0

9,664,000

107

8, 800, 000

91

8

* The figures in the tables under the heading Red Blood Corpuscles give the
number of ery throcy tes before hemorrhage and the number at the end of recovery.

continued to grow and increase their body weight in a normal manner.
Apparently the loss of one-third of their blood did not hinder growth
in any observable respect. Some young animals whose growth had
previously been delayed by lack of vitamin B in experiments by
Cajori (9) were also used, but these recovered in the same way as the
animals showing uninhibited growth.

Diet and dietary factors. In order to make these experiments as
accurate as possible and to eliminate some of the variables occurring in
other work on blood regeneration, the standard diet, with the addition
of dried brewery yeast, was used. Diets of each component of this

STUDIES IN THE REGENERATION OF BLOOD

245

composite food were used, that is, protein only (casein) ; carbohydrate
only (cornstarch) ; fat only (washed butter) ; protein-free food (butter,
lard, cornstarch and salt mixture)4 and one food accessory (vitamin
B) in a relatively concentrated form. The sources of the food accessory

TABLE 2
Blood regeneration in growing rats after a single hemorrhage on standard diet

BODY WEIGHT

TOTAL BLOOD

AMOUNT OF
HEMORRHAGE

RED BLOOD
CORPUSCLES

HEMOGLOBIN

TIME FOR
REGENERA-
TION

grams

grams

grams

per cmm.

days

92

6.1

2.1

11,264,000

. 100

8,500,000

100

9

95

6.3

2.1

9, 536, 000

100

7, 752, 000

96

9

85

6.0

2.25

10,880,000

110

9,312,000

110

9

111

7.2

2.4

8, 256, 000

94

7,442,000

96

7

112

7.2

2.4

10, 336, 000

114

9,440,000

98

7

103

6.77

3.0

9,504,000

110

8, 448, 000

94

7

113

7.2

2.5

10, 000, 000

110

9, 109, 000

110

7

TABLE 3

Blood regeneration in adult rats after a single hemorrhage on a mixed diet

DIET

BODY
WEIGHT

TOTAL
BLOOD

AMOUNT
OF HEM-
ORRHAGE

RED BLOOD
CORPULCLES

HEMO-
GLOBIN

TIME FOR
REGEN-
ERATION

grams

grams

grams

per cmm.

days

322

18.34

8.2

10, 192, 000

94

Dog biscuit

8,400,000

98

7

320

18.0

6.3

10, 080, 000

100

8,912,000

98

7

Table scraps <

310

17.7

5.25

8,812,000
8, 800, 000

78
96

10

were dried brewery yeast, yeast concentrate5 (10), tomato juice and
orange juice.

4 Salt mixture, Osborne and Mendel, Journ. Biol. Chem., 1919, xxxvii, 572.
8 Yeast concentrate, Osborne and Wakeman (10).

246

ZALIA JENCKS

Mixed diets. In order to learn what difference, if any, existed between
the effect of our standard (synthetic) diet and that of scrap food on the
rate of blood regeneration, two rats were fed on dog biscuit for 2 days
before bleeding and then during the entire period of the manufacture
of new blood. The results are shown in table 3. In both cases the
organism regenerated hemoglobin more rapidly than red cells. This
may have been merely accidental, but the same circumstances occurred
in the case of one rat fed on table scraps (meat, lettuce, bread, etc.).
This opens the question as to what factor or factors are here present
which we did not have in the standard basal diet with added yeast as
a source of vitamin B.

TABLE 4

Blood regeneration in adult rats after a single hemorrhage on a limited food intake —

5 grams per day

BODY WEIGHT

TOTAL BLOOD

AMOUNT OF
HEMORRHAGE

RED BLOOD
CORPUSCLES

HEMOGLOBIN

TIME FOB
REGENERA-
TION

grama

grams

grams

per cmm.

days

292

16.7

5.8

10, 000, 000

91

9, 128, 000

90

7

320

18.3

6.4

8, 256, 000

94

8, 480, 000

90 .

7

240

14.0

4.8

9,360,000

91

' 8, 886, 000

91

7

230

13.4

4.6

9, 472, 000

100

9, 776, 000

104

6

200

11.9

4.0

7, 328, 000

70

8, 128, 000

72

6

Underfeeding. A series of hemorrhages was made on animals with
a limited supply of food, i.e., 5 grams per animal per day, including
0.2 grams yeast daily added to the standard basal diet as above. This
limited food consumption did not prolong the duration of regeneration
appreciably, the normal being reached from 6 to 7 days after the initial
loss of blood (table 4) . Loss of body weight occurred in each case, as
might be expected since the caloric intake was insufficient, but the
animals remained healthy and active throughout the period of limited
feeding.

Starvation. When animals were not allowed any food throughout
the period of blood regeneration, the rate of return to normal hemoglobin
value and number of erythrocytes was slower than in the above cases,
the period for one animal being as long as 13 days. A control rat with-

STUDIES IN THE REGENERATION OF BLOOD

out hemorrhage was starved at the same time; its blood was found to
vary no more in red cell count and hemoglobin percentage from day to
day than that of a normal animal eating as much as it desired. Normal
rats do not maintain wholly constant values for either hemoglobin
percentage or number of red cells. This slower rate of regeneration
during inanition is in agreement with the results of Hooper and
Whipple (11) on fasting dogs after simple anemia (table 5).

Protein only. Since casein is the protein used in our standard synthetic
diet and has been shown to be an adequate protein (2), this was fed
as a sole source of nourishment to another group after hemorrhage
until blood regeneration was accomplished. Only 2 grams per day per
animal were used after it was found that the rats refused to eat more
than this amount in that period. This limited protein diet was used
to see whether in accord with the experience gained with the protein-

TABLE 5

Blood regeneration in adult rats after a single hemorrhage; during this period they

received no food

BODY WEIGHT

TOTAL BLOOD

AMOUNT OF
HEMORRHAGE

RED BLOOD
CORPUSCLES

HEMOGLOBIN

TIME FOR
REGENERA-
TION

grams

grams

grams

per cmm.

days

340

19.2

7.5

8, 860, 000

114

8,900,000

110

13

330

18.7

6.6

8, 562, 000

74

0, 728, 000

87

10

rich diet of dogs (11) the rate of regeneration was more rapid than on
other diets of one food factor only.

The tune of blood regeneration in this set of experiments was from
9 to 12 days, more rapid than in starvation but not so rapid as on some
other equally limited diets (table 6). It must be borne in mind how-
ever that no food accessories (vitamins A and B) were present and
hence the animals ate less than they otherwise would. The energy
intake was obviously inadequate so that underfeeding complicated
the problem. In all these feeding periods where the diets were limited
in amount or kind, or both, the rats were more coprophagous than
normal, no doubt in an effort to satisfy their desire for a feeling of
fullness.

Fat only. In feeding the fat portion of the basal diet, butter washed
free of salt was used in an amount corresponding to the daily weight
of protein fed. The rats did not eat the butter readily and never ap-

248

ZALIA JENCKS

peared so anxious for their food as did the animals on the other diets.
The time required for regeneration of blood by this set of fat-fed animals
was 9 days, not longer than for the protein-fed rats (table 7).

Carbohydrate only. Two grams of cornstarch, made in the form of
a paste with water to prevent scattering, were fed daily to each of three
rats after they had been bled. These animals required 12 days for

TABLE 6

Blood regeneration in adult rats after a single hemorrhage on a protein diet —

2 grams casein per day

BODY WEIGHT

TOTAL BLOOD

AMOUNT OP
HEMORRHAGE

RED BLOOD
CORPUSCLES

HEMOGLOBIN

TIME FOR
REGENERA-
TION

grams

grams

grams

per cmm.

days

290

16.7

7.7

10,656,000

96

10, 032, 000

96

9

180

11.9

4.25

11, 072, 000

104

10, 500, 000

105

12

153

10.2

3.9

10,432,000

100

9,600,000

100

12

158

10.56

3.0

10,336,000

104

10, 112, 000

104

9

TABLE 7

Blood regeneration in adult rats after a single hemorrhage; on a diet of butter fat only

— 2 grams per day

BOOT WEIGHT

TOTAL BLOOD

AMOUNT OF
HEMORRHAGE

RED BLOOD
CORPUSCLES

HEMOGLOBIN

TIME FOR
REGENERA-
TION

grams

grams

grams

per cmm.

days

295

17.0

7.0

8,528,000

98

9, 136, 000

98

9

355

20.0

9.0

8,480,000

76

7,800,000

80

9

165

11.0

4.0

10,416,000

91

9,440,000

80

9

complete regeneration. This is somewhat longer than for those on the
protein diet, in agreement with the work on dogs receiving a carbohy-
drate-rich diet (11) (table 8).

Protein-free food. This food was made up after the formula for the
standard diet with the casein replaced by corn starch, making a food
containing 68.5 per cent corn starch, 18 per cent lard, 9.0 per cent
butter and 4.5 per cent salts. Three animals were given 5 grams of

STUDIES IN THE REGENERATION OF BLOOD

249

this protein-free food daily, hemorrhages were made and the process
of blood regeneration watched by the methods used before. These rats
replenished their blood supply in from 9 to 12 days (table 9), slightly
more time being required in this series than in the case of the diets of
fat only, but in one case less than with carbohydrate only. Yeast was
fed with this protein-free food to the extent of 0.1 gram per day but
the exceedingly small amount of protein therein evidently had little

TABLE 8

Blood regeneration in adult rats after a single hemorrhage; on a carbohydrate diet —
2 grams cornstarch per day

BODY WEIGHT

TOTAL BLOOD

AMOUNT OF
HEMORRHAGE

RED BLOOD
CORPUSCLES

HEMOGLOBIN

TIME FOR
REGENERA-
TION

grams

grams

grams

per cmm.

days

150

9.5

3.2

10, 288, 000

90

9, 568, 000

91

12

395

22.0

8.5

11,600,000

116

10, 368, 000

114

12

240

14.0

6.0

9,600,000

91

9,696,000

94

12

TABLE 9

Blood regeneration in adult rats after a single hemorrhage; on a protein-free diet

— 5 grams per day

BODY WEIGHT

TOTAL BLOOD

AMOUNT OF
HEMORRHAGE

RED BLOOD
CORPUSCLES

HEMOGLOBIN

TIME FOR
REGENERA-
TION

prams

grams

grams

per cmm.

days

195

11.6

4.47

8,976,000

87

8,496,000

90

9

255

14.8

6.0

10,896,000

110

10, 392, 000

107

12

190

11.45

5.3

10, 000, 000

110

10,400,000

110

12

or no effect on the speed of blood-cell formation. In all cases it was
impossible to keep the animals eating this ration without the addition
of the dietary essential, vitamin B. This led to work on diets without
added yeast, with yeast as a sole source of nourishment, and with other
vitamin-containing products, such as tomato juice and orange juice
alone.

Standard diet without yeast. Four rats were supplied with an unre-
stricted quantity of standard diet and an abundance of fresh water, but

250

ZALIA JENCKS

no yeast, i.e., no vitamin B, was given to them; they were bled accord-
ing to the regular procedure and their recovery was apparently normal.
They ate less and less as time went on, as has been the case for all
animals with lack of vitamin B (12), and they lost in weight. The
return to normal blood values came in from 12 to 13 days; in three of
the four cases hemoglobin values were low. This could not be due to
lack of iron, for some iron was eaten in the salt mixture, although more
iron would have been consumed had yeast also been added to the diet
(table 10).

Yeast only. Because of these results with protein-free food and with
other diets without yeast, a series of hemorrhages was made on rats
which were fed nothing but yeast during the period of recovery. AC-
TABLE 10

Blood regneration in adult rats after a single hemorrhage; on the standard diet,

without yeast

BODY WEIGHT

TOTAL BLOOD

AMOUNT OF
HEMORRHAGE

RED BLOOD
CORPUSCLES

HEMOGLOBIN

TIME FOR
REGENERA-
TION

grams

grams

grams

per cmm.

days

295

170

6.48

11,648,000

107

11,292,000

96

13

315

180

6.0

10, 112, 000

91

10,288,000

94

12

355

200

6.9

11,584,000

114

12, 100, 000

104

12

270

156

5.4

10, 768, 000

98

(Sick)

»

10, 068, 000

85

13

cordingly four animals were selected which had responded in a normal
manner to regeneration after experimental anemia several weeks pre-
vious to this time and each was again subjected to a hemorrhage.
These rats were then fed 0.5 gram dried brewery yeast daily. They
ate the yeast with great avidity as soon as it was offered. This
amounted to practical starvation, and although they lost body weight
the animals all regenerated their blood in from 6 to 8 days (table 11).
In each case the hemoglobin values were equal to or exceeded the origi-
nal. This group of animals regenerated their blood in less time than
the group without food.

As a check for these results with yeast alone a group was given 0.5
gram protein (casein) daily to see if the small quantity of yeast protein
was the stimulant to forming new blood or whether it was in truth the

251

food accessory in the yeast. The time required for these three animals
to regenerate their blood was 7 to 10 days. The hemoglobin values
were again low in two cases as for the animals which were fed no yeast
(table 12). The casein contained no iron but the rats were in iron-wire
cages and continually gnawed at the wires.

,;,; TABLE 11

Blood regeneration in adult rats after a single hemorrhage; on a diet of yeast only —

0.5 gram per day

BODY WEIGHT

TOTAL BLOOD

AMOUNT OP
HEMORRHAGE

RED BLOOD

CORPUSCLES

HEMOGLOBIN

TIME FOR
REGENERA-
TION

grams

grams

grams

per cent

days

292

16.76

6.5

11, 184, 000-

112

•

10,416,000

112

8

320

18.0

6.2

9, 134, 000

90

9, 648, 000

98

7

290

16.7

7.0

10,784,000

96

10,336,000

98

6

355

20.0

7.0

10, 144, 000

102

10,656,000

104

7

TABLE 12

Blood regeneration in adult rats after a single hemorrhage; on a protein diet-

0.5 gram casein per day

BODY WEIGHT

TOTAL BLOOD

AMOUNT OF
HEMORRHAGE

RED BLOOD
CORPUSCLES

HEMOGLOBIN

TIME FOR
REGENERA-
TION

grams

grams

grams

per cmm.

•

days

147

9.34

3.2

8,704,000

102

9, 036, 000

98

7

150

9.5

3.0

12, 000, 000

108

9,924,000*

104

7

157

10.5

4.1

11, 040, 000

87

11, 770, 000

91

10

* R.B.C. constant 3 days

Water soluble vitamin (£). Two products other than yeast, rich
in this dietary essential, were used as a sole nutrient for a group of rats
which had experienced hemorrhages. Orange juice, containing no
iron (by analysis and according to Sherman (13)) and tomato juice
containing no iron (by analysis and according to Sherman) were fed
to two sets of animals. The orange juice was prepared by straining a

252

ZALIA JENCKS

mass of crushed pulp and juice through four layers of clean cheesecloth.
This resulted in a perfectly clear fluid which was measured out for
feeding by means of a pipette. The tomato juice was the juice from
canned tomatoes, from which the pulp and seeds were separated by

TABLE 13

Blood regeneration in adult rats after a single hemorrhage; on a diet of orange juice
only — vitamin B — 5 cc. per day

BODY WEIGHT

TOTAL BLOOD

AMOUNT OF
HEMORRHAGE

RED BLOOD
CORPUSCLES

HEMOGLOBIN

TIME FOR
REGENERA-
TION

grams

grams

grams

per cmm.

days

250

13.5

4.9

12, 384, 000

114

11,548,000

114

6

118

7.7

2.8

12/000, 000

110

11, 880, 000

112

6

170

11.2

3.2

9, 776, 000

102

10, 608, 000

112

6

275

16.

5.3

10, 528, 000

107

10, 608, 000

102

6

TABLE 14

Blood regeneration in adult rats after a single hemorrhage; on a diet of tomato juice

only — 5 cc. per day

BODY WEIGHT

TOTAL BLOOD

AMOUNT OF
HEMORRHAGE

RED BLOOD

CORPUSCLES

HEMOGLOBIN

TIME FOR
REGENERA-
TION

grams

grams

grams

per cmm.

days

400

22.3

5.5

10,768,000

104

11,682,000

107

6

225

13.0

4.7

10, 192, 000

100

10, 176, 000

100

6

367

20.5

8.7

10, 808, 000

100

10, 880, 000

96

8

305

17.5

5.6

8, 592, 000.

94

8, 352, 000

92

6

straining through four layers of cheesecloth. This was also measured
with a pipette. The four rats on 10 cc. of orange juice daily, reached
their normal blood values in 6 days (table 13), those on the tomato
juice, 5 cc. daily, (they refused to eat as much as 10 cc. per day) recovered
in from 6 to 8 days; again the hemoglobin values varied (table 14).

STUDIES IN THE REGENERATION OF BLOOD 253

SUMMARY OF RESULTS

Hemorrhages of approximately one-third of the estimated total
blood volume can be borne by albino rats without interfering with
complete recovery. When one-half or more of the blood was removed
by hemorrhage, death ensued. The criteria used in judging blood
regeneration in the rat were the return of the number of erythrocytes
and the percentage of hemoglobin to the values noted before the animal
had sustained any loss of blood.

By varying the diet from elimination of one factor to elimination of
all but one factor therein, the speed of regeneration of blood was
changed, but with each diet the organism replenished its normal supply
of blood to the original values for red cells and hemoglobin.

Protein permitted more rapid blood regeneration than either carbo-
hydrate or fat when fed as a sole nutrient (2.0 grams daily) .

The diets of vitamin-rich food, even in very small amounts, gave
somewhat more speedy regeneration than any other diet containing
one food factor only.

This study of blood regeneration has not covered the effect of iron on
blood formation. Work on this phase of the problem is now being
carried out.

I desire to express my sincere thanks to Prof. Lafayette B. Mendel
who outlined this problem, for his suggestions and interest throughout
the investigation.

BIBLIOGRAPHY

(1) FERRY: Journ. Lab. Clin. Med., 1920, v, 735.

(2) OSBORNE AND MENDEL: Journ. Biol. Chem., 1912, xiii, 233.

(3) OSBORNE AND MENDEL: Journ. Biol. Chem., 1913, xv, 311.

(4) OSBORNE AND MENDEL: Journ. Biol. Chem., 1915, xx, 351.

(5) DONALDSON: The rat, Philadelphia, 1915.

(6) COHEN AND SMITH: Journ. Biol. Chem., 1919, xxxix, 489.

(7) LAMSON: Journ. Pharm. Exper. Therap., 1915, vii, 169.

(8) GEILING AND GREEN: Proc. Soc. Exper. Biol. and Med., 1912, xviii, 191.

(9) CAJORI: Journ. Biol. Chem., 1920, xliii, 583.

(10) OSBORNE AND WAKEMAN: Journ. Biol. Chem., 1919, xl, 383.

(11) HOOPER AND WHIFFLE: This Journal, 1918, xlv, 573.

(12) KARR: Proc. Soc. Exper. Biol. and Med., 1920, xvii, 84.

(13) SHERMAN: Chemistry of food and nutrition, New York, 1919, 2nd ed., 335.