Why Broth is Beautiful “Essential”
Roles for Proline, Glycine and
Gelatin
By Kaayla T. Daniel, MS CCN
Several years ago Knox Gelatin introduced a new product named
Nutrajoint with great fanfare. This supplement contains gelatin,
vitamin C and calcium, and advertisements touted “recent scientific
studies” proving that gelatin can contribute to the building of strong
cartilage and bones.
In fact, the evidence goes back more than a century, and not only
established gelatin’s value to cartilage and bones but also to the
skin, digestive tract, immune system, heart and muscles.
These early studies, however, have fallen off the radar screen of
Knox
as well as that of nearly everyone else. So it was not surprising in
1997 when the editors of the Tufts University Health & Nutrition
Letter advised consumers not to buy Nutrajoint or similar supplements
because the idea that gelatin can contribute to the building of strong
cartilage and bones “is a theory that has yet to be investigated.” As
for the theory itself, they sniffed that it “sounds tidy-rather along
the lines of ‘you are what you eat.’” In conclusion, they stated that
even if Nutrajoint worked as claimed, it would be totally unnecessary
because “the body can manufacture its own proline and glycine as needed
and therefore suffers no shortfall.”1
The notion that the body can create proline and glycine is, of
course,
the reason that neither amino is considered “essential.” The ability to
manufacture them easily and abundantly as needed, however, is probably
true only of people enjoying radiant good health. Common sense suggests
that the millions of Americans suffering from stiff joints, skin
diseases and other collagen, connective tissue and cartilage disorders
might be suffering serious shortfalls of proline, glycine and other
needed nutrients.
To understand why these nutrients might be so critical to joint
health,
I consulted several textbooks and learned that hyaline cartilage, the
most common type in the human body, derives its strength from a dense,
criss-crossing, ropey network of collagenous fibers, and its resilience
from the gel-like matrix into which these fibers are embedded.
According to a textbook on bone disorders,2 proline and glycine
play
starring roles in the collagenous fibers built from gigantic proteins
containing some 1,000 amino acids each. Glycine contributes one-third
of the total aminos. Glycine is a tiny amino with a talent for
structuring very tightly packed chains. The other aminos that figure
prominently are proline and hydroxyproline, an uncommon team with a
passion for twisting themselves into tightly wound, left-handed
helixes, then switching directions and twisting to the right into a
superhelix. These little twisters form tight, tough, rodlike macro
molecules, which in turn form thicker rods called fibrils. No wonder
cartilage can have such impressive tensile strength.
The remarkable resilience of cartilage comes from its gelatinous
matrix. Far from being a jiggling blob of all-natural Jello, this
matrix is highly structured with complex proteins and sugars. Best
known are the proteoglycans that wind over, under and around the
collagenous fiber network. As the name suggests, these giant molecules
are comprised of proteins and sugars. Their primary job is to get and
hold water, and they were designed to be very, very thirsty.
Accordingly, their elaborate structure includes a central strand of
hyaluronic acid on which hang as many as 100 of the biggest proteins
found in the body. These in turn, divide into chain gangs known as
chondroitin sulfates and keratin sulfates. In electrical terms, these
chains carry negative charges and so repel each other. By keeping their
distance from each other, they create space for the very water they
attract.
Living amidst the proteoglycans are the cartilage
cells-chondrocytes-whose jobs are to regulate cartilage metabolism,
manufacture the giant proteoglycan molecules and collagenous fibers and
build new cartilage as necessary. To do so, the chondrocytes need the
right nutrients delivered in the right proportions by the water and
synovial fluid that feeds cartilage. Not surprisingly, those nutrient
needs include lots of the very aminos that collagen and cartilage are
made of : proline and glycine. Although the textbooks don’t come right
out and say so-and the Tufts editors scorn the very concept-common
sense suggests that-cartilage wise, at least-we might very well be
“what we eat.”
In fact there is solid scientific backing for this common sense
observation. Research on proline and glycine is far from a growth
industry, but a few good studies exist and serve to clarify the
essential nature of these supposedly “inessential” aminos. Most of the
researchers believe that both proline and glycine should at the very
least be considered “conditionally essential” (along with arginine,
cysteine, glutamine, serine, taurine and tyrosine)3, which means that
under most conditions, the body cannot make enough of these compounds
and must get them from food. Even more interestingly, this modern
research suggests that many of the long-forgotten 19th and early 20th
century studies should be looked at anew.
PROLINE
Evidence is mounting that proline should be classified as an
“essential” amino acid. Research shows that plasma levels fall by 20 to
30 percent when individuals in normal health are put on proline-free
diets4 This suggests that the body can produce proline but probably not
in sufficient quantities without dietary assistance.
The Tufts editors thought proline deficiency highly unlikely
because it
is found in virtually all food proteins except lactalbumin, and because
few Americans suffer malnutrition from starvation. However, people
could still have low proline levels if they consume little protein.
This is not only possible but probable in America today, given the
popularity of high-carbohydrate, low-protein and low-fat diets. For
most of these people the way to bring proline consumption up to par is
obvious-add protein to the diet.
Occasionally, however, the problem is not protein intake but the
body’s
inability to metabolize proline into the active form of hydroxyproline.
Both acute and a chronic deficiency of vitamin C produce a significant
increase in the proline to hydroxyproline ratio in urine,5 a sign that
the conversion is not being made.5 Iron is another needed cofactor and
vitamin C is well known to improve iron assimilation.8, 9, 10, 11
Vitamin C’s function is to maintain the enzyme prolyl hydroxylase in an
active form: without this enzyme the proline and lysine in procollagen
cannot be hydroxylated.7
As one might expect, proline has been recommended as a supplement
that
might benefit people interested in soft, non-sagging “youthful” skin.
Little hard science backs up this idea, but a popular book by Leon
Chaitow DO, ND recommends supplementation of 400-1000 mg per day and
always along with Vitamin C. Chaitow cites research by Carl Pfeiffer
discussed in Mental and Elemental Nutrients (Keats, 1975), but not
apparently in journals.12
A study in the Journal of Gerontology, however, begged to differ,
concluding that there were “no significant age-related variations in
the content of proline, hydroxyproline, lysine and hydroxylysine over
the range of 0-93 years of age.” What they found was that “changes in
cross-links derived from gelaldehyde may be responsible for the effects
of age.”13
Proline and Vitamin C also team up for other vital functions.
Linus
Pauling and Matthias Rath have proposed that heart patients with
elevated lipoprotein (a) levels take a formula consisting of proline,
lysine and vitamin C to help reverse the artery-blocking effects of
lipoprotein (a).14
GLYCINE
Glycine might also be considered a “conditionally essential” amino
acid.
As the simplest amino acid, it constitutes a basic nitrogen pool
for
manufacture of other amino acids, and it is used in the synthesis of
hemoglobin, creatine, porphyrin, bile salts, glutathione and the
nucleotides DNA and RNA. Glycine is involved in glucogenesis (the
manufacture of glucose), and low levels may produce hypoglycemic-like
symptoms.
Another vital function is detoxification. The human body requires
copious amounts of glycine for detoxification after exposure to
chemicals, and it conjugates directly with benzoic acid. In that
individuals stressed with benzoic acid show inhibition of glutathione
synthesis, and glycine is a precursor amino acid for glutathione, some
researchers have concluded that glycine might improve the functioning
of Phase II hepatic detoxification. “Benzoic acid is used widely in the
food industry as a preservative. Under normal circumstances these
sources of benzoic acid can be handled with ease at the levels found in
the total diet by most normal individuals. However, even these low
levels might present a problem to individuals who already have a
compromised glycine status in trying to satisfy an increased demand,
such as pregnancy or sickle cell disease.”15
Glycine also helps digestion by enhancing gastric acid secretion.
Research published in 1976 established that only proteins stimulate
gastric acid secretion, but apparently not all amino acids do so.16
Glycine is one of those that do, a fact that was known in 1925.17 The
effects of other amino acids and their related peptides on acid
secretion has not been determined, but researchers have proposed that
“glycine may have application in the design of chemically defined diets
for patients with gastrointestinal disorders.”18
The ability to digest protein obviously plays a vital role in the
maintenance of good health. Many popular health writers, including
Adelle Davis and Linda Clark, have identified problems caused by
widespread hydrochloric acid deficiencies, especially after the age of
40. As Davis put it, “Too little hydrochloric acid impairs protein
digestion and vitamin C absorption, allows the B vitamins to be
destroyed and prevents minerals from reaching the blood to the extent
that anemia can develop and bones crumble.” Strong words, but quite
possibly backed by the wealth of studies she cites dating from 1939 to
1961.19
More recently, Robert Atkins, MD, has taken up the cry. “A lack of
stomach acid is commonplace, the result of aging, genetics, use of
certain medications and a variety of other factors.” Citing 11 studies
provided by his chief researcher Robert Crayhon, Dr. Atkins contends
that the inability to properly digest protein contributes to asthma,
diabetes, food allergies, osteoporosis, iron deficiency anemia,
pernicious anemia, candida, rheumatoid arthritis, intestinal
infections, psoriasis, vitiligo, hives, eczema, dermatitis,
herpetiformis and acne.”20
Glycine also plays a vital role in wound healing. In a study
dating
back to 1929, as well as more recent studies, evidence points to “a
narrow margin between the metabolic demand for glycine and the rate at
which glycine can be formed or made available in the body. A marginal
state of glycine availability is probably more common than has been
appreciated in the past.”21 In other words, when the body needs glycine
for repair, it probably cannot make all it needs, and must obtain
additional glycine from the diet.
Researchers at Rutgers University also studied glycine and wound
healing. Rats were fed diets with and without supplements of glycine
plus arginine or glycine plus ornithine, and the team found that the
glycine-plus-arginine combination significantly improved nitrogen
retention in both the traumatized and non-traumatized rats. The
researchers theorized that glycine and arginine were the most helpful
because both “occur in particularly high concentrations in skin and
connective tissue and might, therefore, be required in greater amounts
for tissue repair.” They further speculated that the beneficial effect
of arginine-plus-glycine is “related to the creatine synthesis needed
for wound healing.”22
Yet another group of people likely to be short of glycine consists
in
patients with sickle cell anemia. “In sickle cell disease the ongoing
haemolysis creates a demand for glycine of the order of 1-2 gram per
day to satisfy the needs of haem synthesis. A normal dietary intake
might just provide this amount of glycine, and endogenous synthesis of
glycine must be insufficient to satisfy the remaining needs of the
body. These people exist in a chronically precarious state with respect
to glycine sufficiency.”23
To meet so many and diverse metabolic demands, glycine must be
readily
available. The body can make it, obviously, but there are plenty of
reasons to think that even normal, healthy people might not be able to
make enough. For example, researchers found that the endogenous
synthesis of glycine in adult men on low-protein diets failed to
satisfy the normal metabolic demand. Studying both glycine and alanine,
they found that glycine (but not alanine) synthesis declined when
dietary amino acids were removed, especially at the lower intakes.
Glycine metabolism (unlike alanine) appears to be “responsive to the
amino acid composition of the diet.” Although unsure of the exact
metabolic and functional significance of this finding, they concluded
that prolonged restriction of dietary nitrogen and/or the supply of
glycine and dietary amino acids would probably limit the capacity of
tissues to form creatine, prophyrins, purines and glutathione.24
Children and pregnant women also need goodly amounts of glycine in
the
diet. Research indicates that glycine deficiency could limit growth in
infants, and stated that the “demands of the growing fetus for glycine
are very high, in both absolute terms and relative to other amino
acids, two to ten times as great on a molar basis.” By optimizing the
intake of this amino acid, the outcome of pre-term infants could be
improved.25
In addition, glycine is the limiting amino acid in children
recovering
from malnutrition, and it is the limiting amino acid for rapid
growth.26 Furthermore, glycine status is an important marker of normal
pregnancy. “As pregnancy advances the endogenous production of glycine
may be insufficient to satisfy the increasing demands.”27
Another infant feeding study showed that the sum of free amino
acids in
plasma increases after feeding and the ratio of glycine to valine
falls. The type of meal determines how quickly this happens and how
soon before normal levels are restored. Breast feeding as opposed to
formula feeding produced faster alteration as well as speedier
normalization.28 This explains why prior to the mid 20th century,
doctors recommended the addition of glycine-rich gelatin to the
homemade infant formulas that were used when breast feeding was not
possible.29
Taken together these studies strongly support the idea that if
glycine
is limited during the early months of life, growth could be limited as
well. And once children grow up, the need for glycine does not
diminish. As noted above, this little amino acid serves many metabolic
functions and is not automatically produced in sufficient quantities by
the body.
Gelatin: The Traditional Way
to Ensure Adequate Proline and Glycine in
the Diet
For many people the simple act of steering clear of low-protein
diets
and including sufficient protein might do the trick. Protein eaters who
still come up short might choose to self medicate by taking proline and
glycine supplements, but would be advised to order a custom-blended
amino acid formula based on results of an amino acid assay test.
A better solution would be to improve their collagen status by
adding
gelatin to their diets in the form of gelatin-rich broth used in soups,
stews and sauces. This traditional food, which has nearly disappeared
from the American table, fits the “you are what you eat” prescription
to a T. Manufactured gelatin is also a useful item in that it is
nothing less than heat-denatured collagen. However, because
manufactured gelatin contains small amounts of MSG, it should be
avoided by those who are sensitive to it.
Gelatin is especially rich in proline and hydroxyproline.
According to
a food industry website, it contains 15.5 and 13.3 grams per 100 grams
of pure protein respectively. It also contains 27.2 grams of glycine
per 100 grams pure protein. Lysine and hydroxoylysine needed for
collagen synthesis are present in the smaller amounts of 4.4 and 0.8
grams per 100 grams pure protein. Others sources provide somewhat
different figures (depending on the ingredients used in gelatin
manufacture and the quality of their sources), but they all
consistently show high levels of proline, hydroxyproline and glycine.
Gelatin, then, is rich in the proline and glycine components that
people need, but weak in methionine, histidine and tyrosine and utterly
lacking in tryptophan. Accordingly, textbook writers from the 19th
century on have rated gelatin a “poor quality protein.” But in spite of
its seeming limitations, gelatin was valued for its medicinal benefits
for thousands of years and was long considered a panacea for everything
from skin and joint disorders to digestive distress to heart ailments.
Gelatin first began to fall out of favor in the 19th century when
scientists demonstrated that a diet of bread and gelatin alone could
not support life.30 The obvious conclusion-that gelatin is not a
replacement for meat or other dietary protein-hardly means that it has
no place at all in our diets. On the contrary, a substantial body of
evidence exists suggesting that gelatin should have a very big place.
Unfortunately, most of these early studies are hard to locate,
having
been published in 19th century and early 20th century journals that are
not found in most medical libraries. The two most valuable sources are
a fascinating 1937 article by Francis Pottenger, MD, on the value of
gelatin in digestion, and a copy of an obscure but very valuable 1945
book Gelatin in Nutrition and Medicine by N.R. Gotthoffer, Director of
Research for Grayslake Gelatin Company, Grayslake, Illinois. In his
foreword to this 162-page book, Gotthoffer states that he spent 18
years between 1927 and 1945 studying the scientific literature on
gelatin.
Dr. Gotthoffer published his findings several years after Dr.
Pottenger
announced his theories and research on the value of gelatin in health
and digestion with great fanfare in 1937, at the Annual Meeting of the
American Therapeutic Society in Atlantic City. “Gelatin may be used in
conjunction with almost any diet that the clinician feels is
indicated,” said Pottenger. “Its colloidal properties aid the digestion
of any foods which cause the patient to suffer from ‘sour stomach.’
Even foods to which individuals may be definitely sensitive, as proven
by the leucopenic index and elimination diets, frequently may be
tolerated with slight discomfort or none at all if gelatin is made part
of the diet.”31
By then, Dr. Gotthoffer had already turned up many earlier studies
supporting gelatin’s role in digestion. Early in this century
researchers showed that gelatin increases the utilization of the
protein in wheat, oats, and barley, though not of corn; that the
digestibility of beans is vastly improved with the addition of gelatin;
and that gelatin helps the digestion of meat protein.32 The last
appears to confirm the subjective reports of many people who say that
meats found in soups and pot roasts-cooked with bones for a long time
in a liquid to which a touch of vinegar has been added-are easier to
digest than quickly cooked steaks and chops, and why gelatin-rich
gravies are at the heart of many culinary traditions.
Confirming recent studies showing that glycine helps infants grow
properly, Gotthoffer reports the existence of more than 30 years of
research studies showing that gelatin can improve the digestion of milk
and milk products. Accordingly, nutrition textbook writers of the 1920s
and 1930s recommended that gelatin be included in infant formulas to
help bring cow’s milk closer to human milk. Gotthoffer’s explanation
was that the “curd obtained from the coagulation of woman’s milk was
softer and more easily digested than that of cow’s milk. However, when
gelatin was added to cow’s milk, a curd of equally desirable
characteristics was formed. In addition, gelatin exerted a very
important influence on the milk fat. It served not only to emulsify the
fat but also, by stabilizing the casein, improved the digestibility and
absorption of the fat, which otherwise would be carried down with
casein in a lumpy mass.” As a result, infants fed gelatin-enriched
formulas showed reduced allergic symptoms, vomiting, colic, diarrhea,
constipation and respiratory ailments than those on straight cow’s
milk.33
Likewise Gotthoffer found studies showing that convalesing adults
who
have lost weight because of operations, dysentery, cancer and other
illnesses fare better if gelatin is added to their diet. “It is said to
be retained by the most sensitive stomach and will nourish when almost
nothing else will be tolerated,” wrote L. E. Hogan in 1909.34 One
reason gelatin was recommended so highly for malnourished individuals
was that it diminishes the amount of complete protein needed by the
body.
The “sparing” effects of gelatin on protein were of particular
interest
to many early researchers. By “sparing protein,” they meant that the
body is less likely to cannabilize the protein stored in its own
muscles, a common occurrence during fasting or during rapid weight loss
from illness. Gelatin thus helps keep the body in what today’s
nutritionists call “nitrogen balance.” As Carl Voit, a researcher who
spent ten years studying gelatin, wrote in 1872, “By being itself
decomposed, it prevented the breakdown of protein in the body and thus
exerted its remarkable sparing powers.” He found that gelatin alone,
however, was not able to build up protein supplies in the body.35
Gelatin and Digestion
Voit also found that gelatin improved digestion because of its
ability
to normalize cases of both hydrochloric acid deficiencies and excesses,
and was said to belong in the class of “peptogenic” substances that
favor the flow of gastric juices, thus promoting digestion.36
Gelatin’s traditional reputation as a health restorer has hinged
primarily on its ability to soothe the GI tract. “Gelatin lines the
mucous membrane of the intestinal tract and guards against further
injurious action on the part of the ingesta,” wrote Erich Cohn of the
Medical Polyclinic of the University of Bonn back in 1905. Cohn
recommended gelatin to people with “intestinal catarrh”-an inflammation
of the mucus membrane now called irritable bowel syndrome.
Interestingly, the type of gelatin used in follow-up experiments done
on people with even more serious intestinal diseases was specified as a
“concentrated calves foot broth.”37 This form of gelatin would have
been rich in cartilage and bone and presumably provide a better amino
acid profile than straight collagen.
Today clinical nutritionists see more and more cases of
dysbiosis-imbalances of “good” and “bad” bacteria in the intestinal
tract. In that the fermentative disturbances that result are linked to
allergies to grains and/or excessive carbohydrate consumption, it is
fascinating to find that a researcher named C.A. Herter spoke directly
to that point back in 1908:
“The use of gelatin as a foodstuff in bacterial infections of the
intestinal tract has never received the attention it deserves. The
physician is not infrequently confronted with a dietetic problem which
consists in endeavoring to maintain nutrition under conditions where no
combination of the ordinary proteins with fats and carbohydrates
suffices to maintain a fair state of nutrition. The difficulty which
most frequently arises is that every attempt to use carbohydrate food
is followed by fermentative disturbances of an acute or subacute nature
which delay recovery or even favor an existing infection to the point
of threatening life. A great desideratum, therefore, is a food which,
while readily undergoing absorption, shall furnish a supply of caloric
energy and which at the same time shall be exempt from ordinary
fermentative decomposition. Such a food exists in gelatin.”38
Years later Schwick and Heide found that excess
hydroxyproline-containing proteins in serum and urine provides a
reliable marker of pathological conditions. They posited that the
breakdown of collagen most probably results from an antigenic reaction.
“Not so long ago the opinion prevailed that gelatin was not antigenic
or immunogenic. However, with the introduction of sensitive
immunological methods - particularly the haemagglutination techniques
-antibodies against gelatin could be demonstrated. It was surprising to
find antibodies against gelatin in human and animal serum of
individuals who had never been injected with gelatin or collagen.”
Schwick and Heide added that this occurs frequently in cases of
rheumatoid arthritis and other degenerative joint diseases. 39
Though they offered no explanation for this pathological
occurrence,
many clinical nutritionists report that rheumatoid arthritis and
degenerative joint diseases reverse when priority is given to the
healing of the GI tract and of “leaky gut” syndrome (in which
incompletely broken down proteins cross the mucosal barrier and enter
the bloodstream and tissues only to be attacked by the immune system).
Because healing protocols generally involve the avoidance of antigenic
foods, Schwick and Heide’s findings might lead some readers to put
gelatin on their already long list of foods to avoid.
However, gelatin is precisely what the turn-of -the-century
doctors
ordered, not only to heal digestive disorders and the intestinal mucosa
but all allergies. Gelatin was even sometimes injected as a plasma or
blood substitute.40 More recently, John F. Prudden, MD, DSci discovered
that therapeutic doses of cartilage (which always contains copious
amounts of proline and glycine) dramatically improved rheumatoid
arthritis as well as other degenerative joint conditions and
inflammatory bowel diseases.41
Additional evidence comes to us recently from a team of Russian
researchers. In an article in Pathophysiology, they reported that
gelatin will protect gastric mucosal integrity, at least in lab rats
subjected to ethanol-induced mucosal damages.42
Doctors of the past also once knew the value of gelatin in
treating
celiac disease. In 1924, a researcher named Haas stated that the
response of patients to a low-carbohydrate diet in which gelatin
“milks” were given at the noon and evening meals was “striking and
almost uniformly good results were obtained over a period of about ten
years.”43
Today many people have solved their digestive problems by
following the
food combining rules popularized in the bestseller Fit for Life by
Harvey and Marilyn Diamond (Warner, 1985), which was inspired by the
work of natural hygiene pioneer Herbert Shelton. Particularly pertinent
here is the rule that warns us never to eat protein foods with
starches. The reason is that they are supposedly digested on different
timetables in the gut, upping the likelihood of indigestion.
Dr. Pottenger, however, found that if gelatin is included as part
of
the meal, digestive action is distributed throughout the mass of food
and digestion of all components proceeds smoothly.44
A more recent theory that has helped many people’s digestion is
laid
out in the book Eat Right 4 Your Type by Peter J. D’Adamo (Putnam,
1996). Yet the very grains that Dr. D’Adamo has found to be a problem
for people with Type O bloods are easily digested if soaked, then
cooked in a gelatin-rich broth. Type A people-who typically lack the
abundant secretions of hydrochloric acid (HCl) necessary for easy
digestion of meats-find meats far easier to digest if they are served
with a gelatin-based gravy, cooked in a gelatin broth or served after
drinking a cup of properly made soup and, as we have seen, gelatin may
even increase their production of HCl. Finally gelatin can alleviate
the allergic reactions and sensitivities that Dr. D’Adamo has related
to blood Types B and AB. Thus gelatin not only opens up the dietary
possibilities for each blood type but can prove a boon for married
couples of different blood types who would obviously prefer to eat the
same meals.45
Fifty years ago Pottenger pointed out a reason that raw food diets
can
be so effective in reversing disease and contributing to rejuvenation.
“Man’s food in the raw state consists largely of hydrophilic (water
loving) colloids. The heat of cooking on the other hand . . .
precipitates the colloids of our diet. This change in colloidal state
alters the hydration capacity of our foods so as to interfere with
their ability to absorb digestive juices.” Happily for those who prefer
their food cooked, Dr. Pottenger went on to explain that this digestive
problem could be easily remedied by adding one-half ounce to one ounce
of gelatin to a cooked meal of meat, potatoes, vegetables and fruits. 46
Edgar Cayce-the “Sleeping Prophet” whose extraordinary psychic
readings
have often anticipated modern medical science by decades-also had good
things to say about gelatin and digestion. In his readings he
recommended that gelatin be consumed to help the assimilation of
vitamins, help the glands function better and to optimize energy and
health. Particularly relevant was Cayce’s counsel that raw vegetables
and salads be eaten with gelatin.47
Gelatin and the Liver
Early research has also indicated that gelatin helps the liver.
This is
plausible in that the liver uses the amino acid glycine for
detoxification, and its ability to detoxify is limited by the amount of
glycine available. Back in 1935, Reuben Ottenberg, MD wrote in the
Journal of the American Medical Association: “It has been suggested
that the administration of extra amounts of proteins containing an
abundance of glycine (such as gelatin) will help the work in the liver.
This seems particularly plausible since the recent work of Quick, who
has shown that the ability of the liver to perform this protective
synthesis is limited by the amount of glycine available.”
Ottenberg concluded with the recommendation that patients with
jaundice
and other liver problems take 5 to l0 grams of gelatin per day either
in the form of food or as a powdered medicinal supplement.48
Gelatin and Bone Health
Interestingly enough, Gotthoffer didn’t find a lot of studies
supporting the role of gelatin in joint and bone health, though a 1907
Italian study established that gelatin injections increased the calcium
in the circulating blood, which in turn was shown to stimulate bone
building.49
Recent studies, however, do support such use. A Japanese study
reported
on protein undernutrition, lowered bone mass and osteoporotic fracture.
Mice were fed for ten weeks with a low-protein diet containing either
10 percent casein or a combination of 6 percent casein and 4 percent
gelatin. The bone mineral content and bone mineral density of the femur
were significantly higher in the group given 6 percent casein plus 4
percent gelatin. The researchers concluded, “these results suggest that
gelatin has differential effects on bone mineral density and body
weight in protein undernutrition.”50
A 1999 German study also proved the truth of the saying “Man ist
was
man isst.” Their study was inspired by reports of the positive
influence of gelatin on degenerative diseases of the musculo-skeletal
system and curiosity about the “therapeutic mechanism and the
absorption dynamics.” Mice fed radioactive gelatin hydrolysate were
compared to control mice administered radioactive proline. They found
that 95 percent of the gelatin was absorbed within the first 12 hours,
and the labeled gelatin found in the tissues was similar to that of
labeled proline with one exception-the absorption and accumulation of
gelatin in the cartilage was twice as high. This suggested a salutary
effect of gelatin on cartilage metabolism that would not occur with the
ingestion of proline alone. They concluded, “These results demonstrate
intestinal absorption and cartilage tissue accumulation of gelatin
hydrolysate and suggest a potential mechanism for previously observed
clinical benefits of orally administed gelatin.”51
In 2000, Dr. Roland W. Moskowitz of Case Reserve University
published
the results of his review of the literature on collagen hydrolysate in
the treatment of osteoporosis and osteoarthritis. He was particularly
impressed with clinical studies that suggested that 10 grams of
pharmaceutical grade collagen hydrolysate per day were enough to reduce
pain in patients with osteoarthrisis of the knee or hip and that
gelatin held a significant treatment advantage over the placebo. For
bone patients, Moskowitz concluded that studies of the effects of
calcitonin (a hormone known to participate in calcium and phosphorus
metabolism with and without a collagen-hydrolysate-rich diet showed
that calcitonin plus the gelatin inhibited bone collagen breakdown far
better than calcitonin alone.52
The big question is why so many early studies showing the healing
power
of gelatin have languished in obscurity. The easy explanation is that
after the 1930s, pharmaceutical drugs were widely prescribed for ills
that were once healed with gelatin.
A more complete explanation is that many of the results of the
early
studies could not be replicated. Reading Gotthoffer’s compendium, it is
evident that one scientist would find that gelatin helps prevent, say,
muscular fatigue, the next would find some benefit and a third would
see no benefit at all. And so on with anemia, jaundice, ulcers and
other ailments. Not being able to repeat and verify results, scientists
probably moved on to other substances and apparently never found the
key to why gelatin sometimes worked well and sometimes did not.
Why were the studies so variable in their results? The most
probable
explanation is that the substance described as “gelatin” was not
consistent from study to study.
Most commercial gelatins today are brewed exclusively from
pigskins or
cowhide and so include no cartilage or bones. Years ago, however, some
commercial cartilages came from mystery blends of cartilage, bones,
skin and other junked animal parts. All these combinations differed in
terms of their physical and chemical characteristics and in their
physiologic actions. Gotthoffer reported that even glue was sometimes
sold as gelatin. Complicating matters further, some of the so-called
“gelatin” studies were done with the isolated amino acid glycine.53
Given the inconsistencies and hazards of gelatin manufacture, it
is no
wonder that studies were inconsistent. As for using gelatin today for
therapeutic benefits, the highest quality product would come from
making gelatin at home using skins, cartilage and bones from organic
chicken or meat. As Dr. Pottenger was wont to say: “A big stock pot is
the most important gift a bride could receive.”54
Whatever form of gelatin is used, it should never be cooked or
reheated
in the microwave. According to a letter published in The Lancet, the
common practice of microwaving converts l-proline to d-proline. They
write, “The conversion of trans to cis forms could be hazardous because
when cis-amino acids are incorporated into peptides and proteins
instead of their trans isomers, this can lead to structural, functional
and immunological changes.” They further note that “d-proline is
neurotoxic and we have reported nephrotoxic and heptatotoxic effects of
this compound.”55 In other words, the gelatin in homemade broth confers
wonderous benefits, but if you heat it in the microwave, it becomes
toxic to the liver, kidneys and nervous system.
Another study suggested that the l-configuration and the proper
molecular size are both essential for beneficial effects of l-proline
upon memory and for the prevention of depression. 56 There is no reason
to think that proline is the only amino subject to this kind of
destruction, and it is likely that other aminos would be similarly
affected. The studies, however, were done on proline.
Concerned about possible excesses of the amino acids proline and
glycine? Humans have shown a high tolerance for both proline and
glycine with no ill effects. When people develop problems attributed to
an excess of proline, it is the result of a genetic disorder, not the
result of food or supplementation. In those few cases excess proline
causes renal and central nervous system dysfunction.57 Glycine excess
also can be attributed to a genetic disorder and indicates a very rare
genetic metabolism problem that can manifest as severe mental
retardation. Although this occurs very rarely, it should be evaluated
in any individual who is going to supplement with large doses in pill
form.58
Not By Gelatin Alone
Historically, gelatin ingestion has caused health problems but
nearly
all the documented cases occurred when the subjects were fed excessive
amounts of gelatin and little else. This occurred quite frequently
during the early to mid 19th century when people running hospitals,
soup kitchens and poor houses tried to economize by serving gelatin at
every meal in the form of bouillon, gelatinous biscuits and other
gelatin-based edibles-or inedibles as the case may be. Gelatin bashers
have long been fond of quoting one scientific study in which dogs died
after a few weeks on a gelatin diet. While it was true that the dogs
died, Gotthoffer argued that “no account was taken of the fact that the
animals refused to eat the food after a few days.”59
Remember also that the amino acids in gelatin, like all amino
acids,
can only be properly utilized when the diet contains sufficient
fat-soluble activators-vitamins A and D-found exclusively in animal
fats. So don’t hesitate to put cream in your broth-based soups and
sauces, and include other sources of vitamins A and D in your diet,
such as butter, egg yolks and cod liver oil.
These days no one is worried about eating too much gelatin, though
a
lot of people are worried about eating any gelatin at all. The fear is
“Mad Cow” disease. An industry website (it does not reveal its sponsor)
states that gelatin today is “hide gelatin,” never made from brains,
and that processing procedures such as degreasing, acid
demineralization, alkaline purification, washing, filtration, ion
exchange and sterilization reduce the chance of bovine spongiform
encephalopathy to less than zero.60 Whether this is honest information
or a public relations spin, or a little bit of both, is not known, and
research into this subject is outside the scope of this paper. In 1992,
the FDA took the fear seriously enough to forbid the import of any cow
products including gelatin from countries where BSE occurs, but lifted
the ban on gelatin in 1997. The main reason was that there have been no
cases to date implicating either commercial or homemade gelatin in “Mad
Cow” disease or any other neurological disorders.61
In favor of gelatin are thousands of years of historical reports
and
several hundred years of studies, most of which suggest that
gelatin-rich broth is the key to turning a quivering blob of ill health
into a sturdy specimen of good health. As the South American proverb
puts it, “Good broth can resurrect the dead.”62
REFERENCES
1. “Hard knocks for Knox Nutrajoint: Company’s claim for dietary
supplement are overblown, Tufts University Health and Nutrition Letter,
1997, 15, 6, 1.
2. Resnick, Donald and Niwayama, Gen, Diagnoses of Bone and Joint
Disorders (Philadelphia: WB Saunders, 1988), p. 758.
3. Irwin, MI, Hegsted DM. A conspectus of research on amino
requirements of man. Journal of Nutrition, 1971, 101, 387-429.
4. Jaksic, et al. Plasma proline kinetics and concentrations in
young
men in response to dietary proline deprivation, American Journal of
Clinical Nutrition, 1990, 52, 307-312.
5. Bates, CJ, Vitamin C deficiency in guinea pigs: changes in
urinary
excretion of proline, hydroxyproline and total amino nitrogen.
International Journal of Vitamin Nutrition Research, 1979, 49, 152-159.
6. Bralley, J. Alexander and Richard S. Lord, Amino Acids in
Laboratory
Evaluations in Nutritional Medicine (Norcross, GA, MetaMetrix, 1999),
4-24
7. Husbkey, RJ, Vitamin C and scurvy, www.people.virginia.edu
8. Richard S. Lord, IAACN Post-Graduate Seminars in Clinical
Nutrition,
Orlando, Florida, June 24, 2000.
9. Nusgens, B and Lapiere, CM, The relationship between proline
and
hydroxyproline urinary excretion in human as an index of collagen
catabolism. Clinica Chimica Acta, 1973, 48, 203-211.
10. Kaddam, IM et al. Comparison of serum osteocalcin with total
and
bone specific alkaline phosphatase and urinary hydroxyproline
creatinine ratio in patients with Paget’s disease of bone, Annals of
Clinical Biochemistry, 1994, 31, 327-330.
11. Secrest, JP and Cunningham, LW, Variations in human urinary
O-hydroxylysyl glycoside levels and their relationship to collagen
metabolism, Journal of Clinical Investigation, 1970, 49, 1497-1509.
12. Chaitow, Leon, Amino Acids in Therapy, (Rochester, VT, Healing
Arts
Press, 1988), p. 103.
13. Miyahara, et al. The effect of age on amino acid composition
of
human skin collagen, Journal of Gerontology, 1978, 33, 4, 498-503.
14. Pauling, L and Rath, M, A unified theory of human
cardiovascular
disease leading the way to the abolition of this disease as a cause for
human mortality, www.orthomed.org.
15. Jackson, AA, et al. Urinary excretion of 5-oxoproline
(pyroglutamic
aciduria) as an index of glycine insufficiency in normal man, British
Journal of Nutrition, 1987, 58, 207-214.
16. Richardson, CT, et al. Studies on the mechanism of
food-stimulated
gastric acid secretion in normal human subjects. Journal of Clinical
Investigation, 1976, 58, 623-631.
17. Wald, A and Adibi, SA, Stimulation of gastric acid secretion
by
glycine and related oligopeptides in humans, American Journal of
Physiology, 1982, 5, 242, G86-G88.
18. Wald.
19. Davis, Adele, Let’s Get Well (Signet, 1972), p. 142.
20. Atkins, Robert, Dr.Atkins’ Vita-Nutrient Solution (Simon &
Schuster, 1998), pp. 234.235.
21. Jackson.
22. Minuskin,M et al. 1981, Nitrogen retention, muscle creatine
and
orotic acid excretion in traumatized rats fed arginine and glycine
enriched diets, Journal of Nutrition, 1981, III, 7, 1265-1274.
23. Jackson.
24. Yu,YM et al. Quantitative asepcts of glycine and alanine
nitrogen
metabolism in postabsorptive young men: effects of level of nitrogen
and dispensable amino acid intake. Journal of Nutrition, 1985, 115,
399-410.
25. Jackson, et al. Optmising amino acid and protein supply and
utilization in the newborn, Proceedings of the Nutrition Society, 1989,
48, 293-301.
26. Persaud, C et al. Glycine: limiting amino acid for rapid
growth,
Proceedings of Nutritional Society, 1987, 46, 236A.
27. Persaud, C et al. The excretion of 5-oxyproline in urine, as
an
index of glycine status during normal pregnancy, British Journal of
Obstetrics and Gynaecology, 1989, 96, 440-444.
28. Tikanogja, T, Plasma amino acids in term neonates after a feed
of
human milk or formula, Acta Paediatrica Scandinavica, 1982, 71, 3,
385-389.
29. Gotthoffer, NR, Gelatin in Nutrition and Medicine (Graylake
IL,
Grayslake Gelatin Company, 1945), pp. 25-37.
30. Gotthoffer, p. 3.
31. Pottenger, FM, Hydrophilic colloid diet, Health and Healing
Wisdom,
Price Pottenger Nutrition Foundation Health Journal, Spring 1997, 21,
1, 17.
32. Gotthoffer, pp. 10-11.
33. Gotthoffer, pp. 25-37.
34. L. E. Hogan quoted in Gotthoffer, p. 26.
35. Carl Voit quoted in Gotthoffer, p. 7.
36. Gotthoffer, pp. 65-68
37. Eric Cohn quoted in Gotthoffer, p. 62.
38. CA Herter quoted in Gotthoffer, p. 63. .
39. Schwick, HG and Heide, K, Immunochemistry and Immunology of
collagen and gelatin, Bibl Haematology, 1969, 33, 111-125.
40. Gotthoffer, pp. 87-111.
41. Prudden, JF, The biological activity of bovine cartilage
preparations, Seminars in Arthritis and Rheumatology, 1974, III, 4,
287-321.
42. Samonina G, et al. Protection of gastric mucosal integrity by
gelatin and simple proline-containing peptides, Pathophysiology, 2000,
7, 1, 69-73.
43. Gotthoffer, p. 66.
44. Pottenger.
45. Eauclaire Osborne, Sally, Eat right for your type hype, Health
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Healing Wisdom, Journal of the Price Pottenger Nutrition Foundation,
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47. Mein, Eric A. Edgar Cayce’s Wisdom for the New Age Series,
Keys to
Health: The Promise and Challenge of Holism (San Francisco, Harper
& Row, 1989), pp. 88-9
48. Ottenberg, R, Painless jaundice, Journal of the American
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Association, 1935, 104, 9, 1681-1687
49. Gotthoffer. p. 131
50. Medline abstract of Koyama, et al. Ingestion of gelatin has
differential effect on bone mineral density and bodyweight in protein
undernutrition, Journal of Nutrition and Science of Vitaminology, 2000,
47, 1, 84-86.)
51. Oesser, S, et al. Oral administration of (14) C labeled
gelatin
hydrolysate leads to an accumulation of radioactivity in cartilage of
mice (C57/BL), Journal of Nutrition, 1999, 10, 1891-1895.
52. Moskowitz, W, Role of collagen hydrolysate in bone and joint
disease, Seminars in Arthritis and Rheumatism, 2000, 30, 2, 87-99.
53. Gotthoffer, pp. 156-159.
54. Pottenger. 55 Lubec, G, et al. Amino acid isomerisation and
microwave exposure, Lancet, 1989, 2, 8676, 1392-1393.
56. Cherkin, A and Van Harreveld, A, L-Proline and related
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57. Bralley, 4-24.
58. Bralley, 4-16.
59. Gotthoffer, 1-6.
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Better Than Pills and Potions - Broth
Many studies now confirm what Grandma always knew-that broth made
from
bones is a great remedy, a tonic for the sick, a strengthener for
athletes, a digestive aid, a healing elixir. And unlike bitter
medicines, broth can be incorporated into delicious soups, stews and
sauces. In fact, broth is the basis of all gourmet cuisines. “Without
broth,” said Escoffier, “one can do nothing.”
The basic method is simple. Soak bones (chicken, duck, turkey,
beef,
lamb, fish, etc.) in water plus a little vinegar for an hour or two. If
you are using beef or lamb bones, a better color and flavor will result
by first roasting the bones in the oven. Bring the water to a boil
slowly and skim any scum that rises to the top. Add a variety of
vegetables and herbs and allow to simmer several hours or overnight.
Remove the bones (your dog will love them) and strain out the
vegetables. You can use the stock as is, or chill to remove the fat
that congeals on the top. (There is nothing wrong with the fat, but
culinary purists point out the clearest sauces are achieved with stock
from which the fat has been removed.) The stock may be kept in the
refrigerator for several days or in the freezer for several months.
If you have a large enough pot, you can use whole carcasses of
birds or
fish, and large knuckle bones (full of cartilage) of beef. Our local
supplier of farm products prepares broth in a cauldron large enough for
the cow’s head-the result is a fantastic, gelatinous broth.
The substitute for broth is MSG, which food manufacturers use to
achieve the taste of meat in canned and dehydrated soups and in
imitation sauces. MSG is toxic to the nervous system but broth-rich in
calcium-is protective. One of the most important things you can do to
improve your health is to use real broth and avoid imitation foods.
A Recipe for Strong Cartilage, Limber Joints and Beautiful Skin
From our friends in Australia promoting the “Optimal Diet,”
developed
by Polish doctor Jan Kwasniewski, comes this recipe for joint and
cartilage health, as well as for beautiful skin. Boil a piece of pig
skin for at least 3 hours until it becomes very soft. Eat it as is,
with mustard or horseradish, or put it through a mincer and add it to
other food. The important thing is regular use-a tablespoon or more
every day, along with a diet that contains adequate animal protein and
lots of nourishing animal fats.
Connective tissue is regenerated very slowly, so this is a remedy
that
requires some patience. However amazing results have been
reported-healing of joints that had been completely stiff and frozen
and the gradual disappearance of arthritis. Best of all is the
improvement in skin quality, with wrinkles smoothing out and even
disappearing completely.
This article appeared in Wise Traditions in Food, Farming and the
Healing Arts, the quarterly magazine of the Weston A. Price Foundation,
SPRING 2003.
The material on this site is copyrighted by the Weston A. Price
Foundation.
Please contact the Foundation for permission if you wish to use
the
material for any purpose.
The Weston A. Price Foundation, PMB 106-380,
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Phone: (202) 363-4394 | Fax: (202) 363-4396 | Web:
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This page was posted on 18 JUNE 2003.