Oils in Context

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http://www.healthythyroid.com/oilsincontext.htm

 

An oil researcher[0] spent 100 days eating what he considered to be

the Eskimo diet, seal blubber and mackerel paste. He observed that

his blood lipid peroxides (measured as malondialdehyde, MDA) reached a

level 50 times higher than normal, and although MDA is teratogenic, he

said he wasn't worried about fathering deformed children, because his

sperm count had gone to zero. Evidently, he didn't have a very

thorough understanding of the Eskimo way of life. In most traditional

cultures, the whole animal is used for food, including the brain and

the endocrine glands. Since unsaturated fats inhibit thyroid

function, and since Eskimos usually have a high caloric intake but are

not typically obese, it seems that` their metabolic rate is being

promoted by something in their diet, which might also be responsible

for protecting them from the effects experienced by the oil

researcher. (According to G. W. Crile, the basal metabolic rate of

Eskimos was 125% of that of people in the United States.)

 

People who eat fish heads (or other animal heads) generally consume

the thyroid gland, as well as the brain. The brain is the body's

richest source of cholesterol, which, with adequate thyroid hormone

and vitamin A, is converted into the steroid hormones pregnenolone,

progesterone, and DHEA, in proportion to the quantity circulating in

blood in low-density lipoproteins. The brain is also the richest

source of these very water-insoluble (hydrophobic) steroid hormones;

it has a concentration about 20 times higher than the serum, for

example. The active thyroid hormone is also concentrated many-fold in

the brain.

 

DHEA (dehydroepiandrosterone) is known to be low in people who are

susceptible to heart disease [1] or cancer, and all three of these

steroids have a broad spectrum of protective actions. Thyroid

hormone, vitamin A, and cholesterol, which are used to produce the

protective steroids, have been found to have a similarly broad range

of protective effects, even when used singly. For example, according

to MacCallum,

 

It has been shown that certain lipoid substances, especially

cholesterine, can act as inhibiting or neutralizing agents toward such

haemolytic poisons as saponin, cobra poison, etc., through forming

with them an innocuous compound. Hanes showed that the relative

immunity of puppies from chloroform poisoning is due to the large

amount of cholesterin esters in their tissues. When artificially

introduced into the tissues of adult animals a similar protection is

conferred.[2]

 

A high level of serum cholesterol is practically diagnostic of

hypothyroidism, and can be seen as an adaptive attempt to maintain

adequate production of the protective steroids. Broda Barnes work

clearly showed that hypothyroid populations are susceptible to

infections, heart disease, and cancer. [3]

 

In the 1940s, some of the toxic effects of fish oil (such as

testicular degeneration, softening of the brain, muscle damage, and

spontaneous cancer) were found to result from an induced vitamin E

deficiency. Unfortunately, there isn't much reason to think that just

supplementing vitamin E will provide general protection against the

unsaturated fats. The half-life of fats in human adipose tissue is

about 600 days, meaning that significant amounts of previously

consumed oils will still be present up to four years after they have

been removed from the diet. [4] According to Draper, et al., [5]

 

, , , enrichment of the tissues with highly unsaturated fatty acids

results in an increase in lipid peroxidation in vivo even in the

presence of normal concentrations of vitamin E. Fasting for more than

24 hours also results in an increase in MDA excretion, implying that

lipolysis is associated with peroxidation of the fatty acids released.

 

According to Lemeshko, et al., it seems that this effect increases

with the age of the animal. [6]

 

Commercial advertising (including medical conferences sponsored by

pharmaceutical companies) and commercially sponsored research are

creating some false impressions about the role of unsaturated oils in

the diet. Like the man who poisoned himself with the Eskimo diet, many

people focus so intently on avoiding one problem that they create

other problems. Since I have discussed the association of unsaturated

fats with aging, lipofuscin, and estrogen elsewhere, I will outline

some of the other problems associated with the oils, especially as

they relate to hormones.

 

Mechanisms and Essentiality: When something is unavoidable, in

ordinary life, talking about essentiality, or the minimum amount

required for life or for optimal health, is more important as an

exploration into the nature of our life than as a practical health

issue. For example, how much oxygen, how many germs (of what kinds),

how many cosmic rays (of what kinds), would produce the nicest human

beings? The fact that we have adapted to something--oxygen at sea

level, microbes, or vegetable fats, for example--doesn't mean that we

are normally exposed to it in ideal amounts.

 

Animals contain desaturase enzymes, and are able to produce specific

unsaturated fats (from oleic and palmitoleic acids) when deprived of

the ordinary essential fatty acids, [7] so it can be assumed that

these enzymes have a vital purpose. The high concentration of

unsaturated fats in mitochondria--the respiratory organelles where it

seems that these lipids present a special danger of destructive

oxidation--suggests that they are required for mitochondrial

structure, or function, or regulation, or reproduction. Unsaturated

fats have special properties of adsorption, [8] and are more soluble

in water than are saturated fats. The movement and modulation of

proteins and nucleic acids might require these special properties. As

the main site of ATP production, I suspect that their water-retaining

property might be crucial. When a protein solution (even egg-white)

is poured into a high concentration of ATP, it contracts or

superprecipitates. This condensing, water-expelling property of ATP

in protein solutions is similar to the effect of certain

concentrations of salts on any polymer. It would seem appropriate to

have a substance to oppose this condensing effect, to stimulate

swelling [9, 10] and the uptake of precursor substances. Something

that has an intrinsic structure-loosening or water-retaining effect

would be needed. The ideas of chaotropic agents and structural

antioxidants have been proposed by Vladimirov [11] to bring generality

into our understanding of the mitochondria. Lipid peroxides are among

the chaotropic agents, and thyroxin is among the structural

antioxidants. The known oxygen-sparing effects of progesterone [12,

13] would make it appropriate to include it among the structural

antioxidants. The incorporation of the wrong unsaturated fats into

mitochondria would be expected to damage the vital respiratory

functions.

 

Some insects that have been studied have been found not to require the

essential fatty acids. [14]* According to reviewers, hogs and humans

have not been shown to require the essential fatty acids. [15] In

vitro studies indicate that they are not required for human diploid

cells to continue dividing in culture. [16] According to Guarnieri,

[17] EFA-deficient animals don't die from their deficiency. The early

studies showing essentiality of unsaturated fats, by producing skin

problems and an increased metabolic rate, have been criticized [18] in

the light of better nutritional information, e.g., pointing out that

the diets might have been deficient in vitamin B6 and/or biotin. The

similar skin condition produced by vitamin B6 deficiency was found to

be improved by adding unsaturated fats to the diet. A fat-free liver

extract cured the EFA deficiency. I think it would be reasonable to

investigate the question of the increased metabolic rate produced by a

diet lacking unsaturated fats (which inhibit both thyroid function and

protein metabolism) in relation to the biological changes that have

been observed. Since diets rich in protein are known to increase the

requirement for vitamin B6 [19] (which is a co-factor of

transaminases, for example), the increased rate of energy production

and improved digestibility of dietary protein on a diet lacking

unsaturated fats would certainly make it reasonable to provide the

experimental animals with increased amount of other nutrients. With

increasing knowledge, the old experiments indicating the essentiality

of certain oils have lost their ability to convince, and they haven't

been replaced by new and meaningful demonstrations. In the present

state of knowledge, I don't think it would be unreasonable to suggest

that the optional dietary level of the essential fatty acids might be

close to zero, if other dietary factors were also optimized. The

practical question, though, has to do with the dietary choices that

can be made at the present time.

 

 

______________________________

 

*If we followed Linus Paulings reasoning in determining optimal

vitamin C intake, this study of the linoleic acid content of the

tissues of an animal which can synthesize it would suggest that we are

eating about 100 times more EFA than we should.

 

In evaluating dietary fat, it is too often forgotten that the animals

diet (and other factors, including temperature) affect the degree of

saturation of fats in its tissues, or its milk, or eggs. The fat of

wild rabbits or summer-grazing horses, for example, can contain 40%

linolenic acid, about the same as linseed oil. Hogs fed soybeans can

have fat containing over 30% linoleic acid. [20] Considering that

most of our food animals are fed large amounts of grains and soybeans,

it isn't accurate to speak of their fats as " animal fats. " And,

considering the vegetable oil contained in our milk, eggs, and meat,

it would seem logical to select other foods that are not rich in

unsaturated oils.

 

Temperature and Fat: The fact that saturated fats are dominant in

tropical plants and in warm-blooded animals relates to the stability

of these oils at high temperatures. Coconut oil which had been stored

at room temperature for a year was found to have no measurable

rancidity. Since growing coconuts often experience temperatures

around 100 degrees Fahrenheit, ordinary room temperature isn't an

oxidative challenge. Fish oil or safflower oil, though, can't be

stored long at room temperature, and at 98 degrees F, the spontaneous

oxidation is very fast.

 

Bacteria vary the kind of fat they synthesize, according to

temperature, forming more saturated fats at higher temperatures.[21]

The same thing has been observed in seed oil plants. [22] Although

sheep have highly saturated fat, the superficial fat near their skin

is relatively unsaturated; it would obviously be inconvenient for the

sheep if their surface fat hardened in cool weather, when their skin

temperature drops considerably. Pigs wearing sweaters were found to

have more saturated fat than other pigs.[23] Fish, which often live

in water which is only a few degrees above freezing, couldn't function

with hardened fat. At temperatures which are normal for fish, and for

seeds which germinate in the cold northern springtime, rancidity of

fats isn't a problem, but rigidity would be.

 

Unsaturated Fats Are Essentially Involved In Heart Damage: The

toxicity of unsaturated oils for the heart is well established, [24,

25, 26] though not well known by the public.

 

In 1962, it was found that unsaturated fatty acids are directly toxic

to mitochondria. [27] Since stress increases the amount of free fatty

acids circulating in the blood (as well as lipid peroxides), and since

lack of oxygen increases the intracellular concentration of free fatty

acids, stored unsaturated fats would seem to represent a special

danger to the stressed organism. Meerson and his colleagues [18] have

demonstrated that stress liberates even local tissue fats in the heart

during stress, and that systematic drug treatment, including

antioxidants, can stop the enlargement of stress-induced infarctions.

Recently, it was found that the cardiac necrosis caused by

unsaturated fats (linolenic acid, in particular) could be prevented by

a cocoa butter supplement. [29] The author suggests that this is

evidence for the essentiality of saturated fats, but points out that

animals normally can produce enough saturated fat from dietary

carbohydrate or protein, to prevent cardiac necrosis, unless the diet

provides too much unsaturated fat. A certain proportion of saturated

fat appears to be necessary for stability of the mitochondria.

Several other recent studies show that the essential fatty acids

decrease the P/O ratio, or the phosphorylation efficiency, [30] the

amount of usable energy produced by cellular respiration.

 

There has been some publicity about a certain unsaturated fat,

eicosapentaenoic acid, or EPA, which can have some apparently

protective and anti-inflammatory effects. A study in which butter was

added to the animals diet found that serum EPA was elevated by the

butter. The investigator pointed out that other studies had been able

to show increased serum EPA from an EPA supplement only when the

animals had previously been fed butter. [31]

 

Intense lobbying by the soybean oil industry has created the

widespread belief that tropical oils cause heart disease. In a

comparison of many kinds of oil, including linseed oil, olive oil,

whale oil, etc., palm oil appeared to be the most protective. The

same researcher [32] more recently studied palm oils antithrombotic

effect, in relation to platelet aggregation. It was found that

platelet aggregation was enhanced by sunflowerseed oil, but that palm

oil tended to decrease it.

 

Much current research has concentrated on the factors involved in

arterial clotting. Since the blood moves quickly through the

arteries, rapid processes are of most interest to those workers,

though some people do remember to think in terms of an equilibrium

between formation and removal of clot material. For about 25 years

there was interest in the ability of vitamin E to facilitate clot

removal, apparently by activating proteolytic enzymes.[33]

Unsaturated fats ability to inhibit proteolytic enzymes in the blood

has occasionally been discussed, but seldom in the U.S. The

equilibrium between clotting and clot dissolution is especially

important in the veins, where blood moves more slowly, and spends more

time.

 

. . . the slower blood flows the greater its predisposition to

clotting. However, this intrinsic process, leading to fibrin

production, is slow, taking up to a minute or more to occur.

Thrombosis as a result of stasis, therefore, occurs in the venous

circulation; typically in the legs where venous return is slowest. In

fact, many thousands of small thrombi are formed each day in the lower

body. These pass via the vena cava into the lungs where thrombolysis

occurs, this being a normal metabolic function of the organ. [34]

 

In the Shutes research in the 1930s and 1940s, vitamin E and estrogen

acted in opposite directions on the clot-removing enzymes.[33] Since

estrogen increases blood lipids, and increases the incidence of

strokes and heart attacks, it would be interesting to expand the

Shutes work by considering the degree of saturation of blood lipids in

relation to the effects of vitamin E and estrogen on clot removal.

Estrogen's effect on clotting is very complex, since it increases the

ratio of unsaturated to saturated fatty acids in the body, and

increases the tendency of blood to pool in the large veins, in

addition to its direct effects on the clotting factors.

 

Immunodeficiency and Unsaturated Fats: Intravenous feeding with

unsaturated fats is powerfully immunosuppressive [35] (though it often

was used to give more calories to cancer patients) and is now

advocated as a way to prevent graft rejection. The deadly effect of

the long-chain unsaturated fats on the immune system has led to the

development of new products containing short and medium-chain

saturated fats for intravenous feeding. [36] It was recently reported

that the anti-inflammatory effect of n-3 fatty acids (fish oil) might

be related to the observed suppression of interleukin-1 and tumor

necrosis factor by those fats. [37] The suppression of these

anti-tumor immune factors persists after the fish oil treatment is

stopped.

 

As mentioned above, stress and hypoxia can cause cells to take up

large amounts of fatty acids. Cortisols ability to kill white blood

cells (which can be inhibited by extra glucose) is undoubtedly an

important part of its immunosuppressive effect, and this killing is

mediated by causing the cells to take up unsaturated fats. [38]

 

Several aspects of the immune system are improved by short-chain

saturated fats. Their anti-histamine action [39] is probably

important, because of histamines immunosuppressive effects.[40]

Unsaturated fats have been found to cause degranulation of mast

cells.[41] The short-chain fatty acids normally produced by bacteria

in the bowel apparently have a local anti-inflammatory action.[42]

 

A recent discussion of tissue destruction by neutrophils mentions a

fascinating series of experiments performed between 1888 and 1906, in

which German and American scientists established the importance of

neutrophil proteinases and plasma antiproteinases in the evolution of

tissue damage in vivo. [43] MacCallums Pathology described some

related work:

 

. . . Jobling has shown that the decomposition products of some

fats-- unsaturated fatty acids and their soaps--have the most decisive

inhibiting action upon proteolytic ferments, their power being in a

sense proportional to the degree of unsaturation of the fatty acid.

So universally is it true that such unsaturated fatty acids can impede

the action of proteolytic ferments that many pathological conditions

(such as the persistence of caseous tuberculous material in its solid

form) can be shown to be due to their presence. If they are rendered

impotent by saturation of their unsaturated group with iodine, the

proteolysis goes on rapidly and the caseous tubercle or gumma rapidly

softens.[44]

 

Another comment by MacCallum suggests one way in which unsaturated

fats could block the action of cytotoxic cells:

 

 

 

This function of the wandering cells is, of course, of immediate

importance in connection with their task of cleaning up the injured

area to prepare it for repair. While the proteases thus produced are

active in the solution of undesirable material, their unbridled action

might be detrimental. As a matter of fact, it is shown by Jobling and

Petersen that the anti-ferment known to be present in the serum and to

restrict the action of the ferment is a recognizable chemical

substance, usually a soap or other combination of an unsaturated fatty

acid. It is possible to remove or decompose this substance or to

saturate the fatty acid with iodine and thus release the ferment to

its full activity. [45]

 

Unsaturated Fats Are Essential For Cancer: The inhibition of

proteolytic enzymes by unsaturated fats will act at many sites:

digestion of protein, digestion of clots, digestion of the colloid in

the thyroid gland which releases the hormones, the activity of white

cells mentioned above, and the normal digestion of cytoplasmic

proteins involved in maintaining a steady state as new proteins are

formed and added to the cytoplasm. It has been suggested that

inhibition of the destruction of intracellular proteins would shift

the balance toward growth.[46] Cancer cells are known to have a high

level of unsaturated fats,[47] yet they have a low level of lipid

peroxidation;[48] lipid peroxidation inhibits growth, and is often

mentioned as a normal growth restraining factor.[49]

 

In 1927, it was observed that a diet lacking fats prevented the

development of spontaneous tumors.[50] Many subsequent investigators

have observed that the unsaturated fats are essential for the

development of tumors. [51, 52, 53] Tumors secrete a factor which

mobilizes fats from storage, [54] presumably guaranteeing their supply

in abundance until the adipose tissues are depleted. Saturated fats,

coconut oil and butter, for example do not promote tumor growth.[55]

Olive oil is not a strong tumor promoter, but in some experiments it

does have a slightly permissive effect on tumor growth. [56, 57] In

some experiments, the carcinogenic action of unsaturated fats could be

offset by added thyroid, [57] an observation which might suggest that

at least part of the effect of the oil is to inhibit thyroid. Adding

cystine to the diet (cysteine, the reduced form of cystine, is a

thyroid antagonist) also increases the tumor incidence.[58] In a

hyperthyroid state, the ability to quickly oxidize larger amounts of

the toxic oils would very likely have a protective effect, preventing

storage and subsequent peroxidation, and reducing the oils ability to

synergize with estrogen.

 

Consumption of unsaturated fat has been associated with both skin

aging and with the sensitivity of the skin to ultraviolet damage,

Ultraviolet light-induced skin cancer seems to be mediated by

unsaturated fats and lipid peroxidation.[59]

 

In a detailed study of the carcinogenicity of different quantities of

unsaturated fat, Ip, et al., tested levels ranging from 0.5% to 10%,

and found that the cancer incidence varied with the amount of

essential oils in the diet. Some of their graphs make the point very

clearly: [52}

 

This suggests that the optimal EFA intake might be 0.5% or less.

 

Butter and coconut oil contain significant amounts of the short and

medium-chain saturated fatty acids, which are very easily

metabolized,[60] inhibit the release of histamine,[39] promote

differentiation of cancer cells,[61] tend to counteract the

stress-induced proteins,[62] decrease the expression of prolactin

receptors, and promote the expression of the T3 (thyroid) receptor.

[63] (A defect of the thyroid receptor molecule has been identified

as an oncogene, responsible for some cancers, as has a defect in the

progesterone receptor.)

 

Besides inhibiting the thyroid gland, the unsaturated fats impair

intercellular communication,[64] suppress several immune functions

that relate to cancer, and are present at high concentrations in

cancer cells, where their antiproteolytic action would be expected to

interfere with the proteolytic enzymes and to shift the equilibrium

toward growth. In the free fatty acid form, the unsaturated fats are

toxic to the mitochondria, but cancer cells are famous for their

compensatory glycolysis.

 

By using lethargic connective tissue cells known to have a very low

propensity to take up unsaturated fats [65] as controls in comparison

with, e.g., breast cancer cells, with a high affinity for fats, it is

possible to show a selective toxicity of oils for cancer cells.

However, an in vivo test of an alph-linolenic acid ester showed it to

have a stimulating effect on breast cancer.[66] Given a choice, skin

fibroblasts demonstrate a very specific preference for oleic acid,

over a polyunsaturated fat.[67]

 

Even if unsaturated fats were (contrary to the best evidence)

selectively toxic for cancer cells, their use in cancer chemotherapy

would have to deal with the issues of their tendency to cause

pulmonary embolism,their suppression of immunity including factors

specifically involved in cancer resistance, and their carcinogenicity.

 

Brain Damage And Lipid Peroxidation: When pregnant mice were fed

either coconut oil or unsaturated seed oil, the mice that got coconut

oil had babies with normal brains and intelligence, but the mice

exposed to the unsaturated oil had smaller brains, and had inferior

intelligence. In another experiment, radioactively labeled soy oil

was given to nursing rats, and it was shown to be massively

incorporated into brain cells, and to cause visible structural changes

in the cells. In 1980, shortly after this study was published in

Europe, the U.S. Department of Agriculture issued a recommendation

against the use of soy oil in infant formulas. More recently, [68]

pregnant rats and their offspring were given soy lecithin with their

food, and the exposed offspring developed sensorimotor defects.

 

Many other studies have demonstrated that excessive unsaturated

dietary fats interfere with learning and behavior, [70, 71] and the

fact that some of the effects can be reduced with antioxidants

suggests that lipid peroxidation causes some of the damage. Other

studies are investigating the involvement of lipid peroxidation in

seizures.[72]

 

The past use of soy oil in artificial milk (and in maternal diets) has

probably caused some brain damage. The high incidence of neurological

defects (e.g., 90%) that has been found among violent criminals

suggests that it might be worthwhile to look for unusual patterns of

brain lipids in violent people.

 

There have been a series of claims that babies brains or eyes develop

better when their diets are supplemented with certain unsaturated

oils, based on the idea that diets may be deficient in certain types

of oil, Some experimenters claim that the supplements have improved

the mental development of babies, but other researchers find that the

supplemented babies have poorer mental development. But the oils that

are added to the babies diets are derived from fish or algae, and

contain a great variety of substances (such as vitamins) other than

the unsaturated fatty acids, and the researchers consistently fail to

control for the effects of such substances.

 

It has shown that it is probably impossible to experience a detectable

deficiency of linoleic acid outside of the laboratory setting,[69] but

the real issue is probably whether the amount in the normal diet is

harmful to development. Until the research with animals has produced

a better understanding of the effects of unsaturated oils,

experimenting on human babies seems hard to justify.

 

Marion Diamond, who has studied the improved brain growth in rats

given a stimulating environment (which, like prenatal progesterone,

produced improved intelligence and larger brains), observed that in

old age the enriched rats brains contained less lipofuscin (age

pigment).[73] It is generally agreed that the unsaturated oils

promote the formation of age pigment. The discovery that stress or

additional cortisone (which, by blocking the use of glucose, forces

cells to take up more fat) causes accelerated aging of the brain[74]

should provide new motivation to investigate the antistress properties

of substances such as the protective steroids mentioned above, and the

short-chain saturated fats.

 

Essential for Liver Damage: Both experimental and epidemiological

studies have shown that dietary linoleic acid is required for the

development of alcoholic liver damage.[75] Animals fed tallow and

ethanol had no liver injury, but even 0.7% or 2.5% linoleic acid with

ethanol caused fatty liver, necrosis, and inflammation. Dietary

cholesterol at a level of 2% was found to cause no harm,[76] but

omitting it entirely from the diet caused leakage of amino-transferase

enzymes. This effect of the absence of cholesterol was very similar

to the effects of the presence of linoleic acid with ethanol.

 

Obesity: For many years studies have been demonstrating that dietary

coconut oil causes decreased fat synthesis and storage, when compared

with diets containing unsaturated fats. More recently, this effect

has been discussed as a possible treatment for obesity.[77] The

short-chain fats in coconut oil probably improve tissue response to

the thyroid hormone (T3), and its low content of unsaturated fats

might allow a more nearly optimal function of the thyroid gland and of

mitochondria. A survey of other tropical fruits content of short and

medium chain fatty acids might be useful, to find lower calorie foods

which contain significant amounts of the shorter-chain fats.

 

Other Problem Areas: The presence of palmitate in the lung surfactant

phospholipids[78] suggests that maternal overload with unsaturated

fats might interfere with the formation of these important substances,

causing breathing problems in the newborn. The bone-calcium

mobilizing effect of prostaglandins suggests that dietary fats might

affect osteoporosis; the absence of osteoporosis in some tropical

populations might relate to their consumption of coconut oil and other

saturated tropical oils. The steroids which occur in association with

some seed oils might be nutritionally significant, in the way animal

hormones in foods undoubtedly are. For example, soy steroids can be

converted by bowel bacteria into estrogens. R. Marker, et al., found

diosgenin (the material in the Mexican yam from which progesterone,

etc., are derived) in a palm kernel, Balanites aegyptica (Wall).[79]

Another palm fruit also contains sterols with anti-androgenic and

anti-edematous actions.[80, 81]

 

If the amount of ingested unsaturated fats (inhibitors of protein

digestion) were lower, protein requirements might be lower.

 

The similar effects of estrogen and of polyunsaturated fats (PUFA) are

numerous. They include antagonism to vitamin E and thyroid, to

respiration and proteolysis; promotion of lipofuscin formation and of

clot formation, promotion of seizure activity, impairment of brain

development and learning; and involvement in positive or negative

regulation of cell division, depending on cell type.

 

These parallels suggest that the role of PUFA in reproduction might be

similar to that of estrogen, namely, the promotion of uterine and

breast cell proliferation, water uptake, etc. Such parallels should

be a caution in generalizing from the conditions which are essential

for reproduction to the conditions which are compatible with full

development and full functional capacity. If a certain small amount

of dietary PUFA is essential for reproduction, but for no other life

function, then it is analogous to the brief estrogen surge, which must

quickly be balanced by opposing hormones. The present approach to

contraception through estrogen-induced miscarriage might give way to

fertility regulation by diet. A self-actualizing pro-longevity diet,

low in PUFA, might prolong our characteristically human condition of

delayed reproductive maturity, and, if PUFA are really essential for

reproduction, unsaturated vegetable oils could temporarily be added to

the diet when reproduction is desired.

 

Conclusions: Polyunsaturated fats are nearly ubiquitous, but if they

are essential nutrients, in the way vitamin A, or lysine, is

essential, that has not been demonstrated. It seems clear that they

are essential for cancer, and that they have other properties which

cause them to be toxic at certain levels. It might be time to direct

research toward determining whether there is a threshold of toxicity,

or whether they are, like ionizing radiation, toxic at any level.

 

Note:

 

A possible mitochondrial site for toxicity: In 1971 I was trying to

combine some of the ideas of Albert Szent-Gyorgyi, Otto Warburg, W. F.

Koch, and L. C. Strong. I was interested in the role of ubiquinone in

mitochondrial respiration. In one experiment, I was using paper

chromatography to compare oils that I had extracted from liver with

vitamin E and with commercially purified ubiquinone. Besides using

the pure substances, I decided to combine vitamin E with ubiquinone

for another test spot. As soon as I combined the two oils, their

amber and orange colors turned to an inky, greenish black color. I

tested both bacterial and mammalian ubiquinone, and benzoquinone, and

they all produced similar colors with vitamin E. When I ran the

solvent up the paper, the vitamin E and the ubiquinone traveled at

slightly different speeds. The black spot, containing the mixture,

also moved, but each substance moved at its own speed, and as the

materials separated, their original lighter colors reappeared.

Charge-transfer bonds, which characteristically produce dark colors,

are very weak bonds. I think this must have been that kind of bond.

Years later, I tried to repeat the experiment, using ubiquinone from

various capsules that were sold for medical use. Instead of the waxy

yellow-orange material I had used before, these capsules contained a

liquid oil with a somewhat yellow color. Very likely, the ubiquinone

was dissolved in vegetable oil. At the time, I was puzzled that the

color reaction didn't occur, but later I realized that a solvent

containing double bonds (e.g., soy oil or other oil containing PUFA)

would very likely prevent the close association between vitamin E and

ubiquinone which is necessary for charge-transfer to occur. Since I

think Koch and Szent-Gyorgyi were right in believing that electronic

activation is the most important feature of the living state, I think

the very specific electronic interaction between vitamin E and

ubiquinone must play an important role in the respiratory function of

ubiquinone. Ubiquinone is known to be a part of the electron

transport chain which can leak electrons, so this might be one of the

ways in which vitamin E can prevent the formation of toxic

free-radicals. If it can prevent the leakage of electrons, then this

in itself would improve respiratory efficiency. If unsaturated oils

interfere with this very specific but delicate bond, then this could

explain, at least partly, their toxicity for mitochondria. [Electron

leak reference: B. Halliwell, in Age Pigments (R. S. Sohal, ed.), pp.

1-62, Elsevier, Amsterdam, 1981.]

 

REFERENCES

 

 

 

0. Sinclair, H., Prog. Lipid Res. 25: 667-72, History of EFA &

their prostanoids: some personal reminiscences.

 

1. E. Barrett-Connor, N. Engl. J. Med., Dec. 11, 1986, and R.

D. Bulbrook (London Imperial Cancer Research Fund, discussed in a

review by H. G. Schwartz.

 

2. MacCallum, W. G., A Text-Book of Pathology, W. B. Saunders

Co., Phila., 1937, pp. 85-86.

 

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Raymond Peat, Ph.D.

 

Copyright 2001

 

 

 

raypeat

 

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