From the original article in 2014. Author: Ray Peat.
For every thing that lives is holy, life delights in life....
— W. Blake
Life is a condition alternating between excitation, destruction and unbalance, and reorganization, equilibrium and rest.
— Kurt Goldstein
Oncological pathologists, looking at slices of a tumor, believe they can guess when the cells have an evil intention. However, biologists studying living cells find that cells can do only what they are allowed to do by their environment.
According to the World Health Organization, cancer is now the leading cause of death in the world. Although many "causes" are known, and despite the "War on Cancer," nothing practical has been done to reduce the incidence of cancer. Since Nixon started that war, the number of people dying annually in the US has increased faster than the population. In ancient Rome and Egypt, cancer was rare; cancer has been identified in only one Egyptian mummy. In the US and several other countries, between 2002 and 2005 there was an unprecedented decline (7% in the US) in the incidence of breast cancer, when the medical use of estrogen decreased following the Women's Health Initiative report showing that estrogen caused cancer, dementia, strokes and heart attacks. However, when the public was reassured about estrogen's safety, breast cancer incidence began increasing again each year.
The cancer industry has been flexible and imaginative in ways of presenting "age standardized" death rates to show that they are making progress against cancer, but there are philosophical and scientific problems in "oncology" (i.e., the study or treatment of lumps) that should be considered by anyone who plans to do business with that profession.
In the 19th century (in Johannes Muller's lab), cancers, like other animal tissues, were found to be made up of cells, and by 1858, all diseases were said to be caused by disturbances in cells (Rudolph Virchow). The atomic and molecular theory of matter was becoming accepted at the time that animals were found to be made up of cells, and in both cases the "elementary particles" seemed to have a special power to explain things. This idea of a cellular basis of disease gradually displaced the old idea that diseases were caused by an imbalance of the body fluids, or humors. In 1863, Virchow recognized that inflammation, involving leukocytes, was a common feature of cancer, but that aspect of his work was neglected for a long time.
Recent medical textbooks reveal no major change in the understanding of cancer since Virchow's time, except that "genes" (which weren't known during Virchow's life) gradually became the most important aspect of cells. The typical modern textbook describes the cellular disturbance of cancer as the result of an "initiating" mutation in a gene, which gives it the potential to develop into a cancer, if it subsequently is exposed to a "promoter," which causes it to multiply. In some versions of the theory, a promoter is a second mutation that causes proliferation, but in other versions the promotion is caused by chemicals binding to receptors the way hormones do, to stimulate proliferation. Typically, textbooks (and reports of continuing research) describe subsequent changes in the genes that cause a cancer to progress from a simple excess of cells through stages of increasing malignancy: hyperplasia, dysplasia, carcinoma in situ, invasive cancer.
One of the reasons that the medical understanding of cancer hasn't changed significantly since Virchow's time is that blaming misbehaving cells for causing a tumor fits into the older medical tradition, that has existed at least since the time of Hippocrates, 400 BC, which treated tumors either by cutting them out, or by burning them off with caustics. Virchow's identification of misbehaving cells provided a clear mental image of exactly what the physician must try to destroy. And it's probably hard to get interested in something which could seriously limit your professional activities if it turned out to be true.
The "cellular basis of cancer" was developed simultaneously with the germ theory of disease, and in the case of cancer, the deviant cells came to be considered an alien substance, "not-self," analogous to infective germs. Paul Ehrlich's search for poisons that were specific for bacterial pathogens was quickly extended to the idea of finding poisons that would distinguish between cancer cells and the patient's cells.
Hippocrates' therapeutic approach to cancer may have survived for 2400 years, but the ideas of his younger contemporary, Plato, about order and causation have probably had a greater effect on medicine. Plato believed that the world of experience is inferior and accidental, and that there are timeless "Forms" that are the real substances. In the atomic theory of matter, eternal, unchanging atoms took the place of platonic forms, and there are still molecular biologists who insist that life can only be explained in terms of its constituent atoms ("What else is there but atoms?"). This philosophy of timeless forms was a deep commitment of people like Gregor Mendel and August Weismann, whose ideas dominated the thinking of early 20th century geneticists. Genes were the immutable essence of organisms, and the cells, tissues, and organs that form the organism are merely temporal and accidental. Weismann's "germ plasm" or germ line contained the immortal genes, the rest of the body lacked them, and was essentially mortal.
For most of the 20th century, the official doctrine was that most of the cells of the adult body became stationary once the body reached its adult size, and that aging consisted of the "wearing out" of those mortal cells. When a tumor, containing new cells, would appear and grow, these cells were called "immortal," because they didn't follow the rule for normal, stationary, mortal cells. Their "immortality" is often demonstrated by growing them endlessly in culture dishes. Normal cells, if they can be made to survive in a culture dish, are likely to be "transformed" into cancer, demonstrated by their ability to replicate in dishes.
This is an important ideological point, that developed as biologists were experiencing the extreme difficulty of getting cells to replicate, or even to survive, in culture dishes. It has only recently been realized that cells need more than nutritional and hormonal signals to survive in culture; they require certain textural, structural, even rhythmically repeating conditions that mimic their surroundings in the living body.
Applied to cancer, the gene theory made it seem clear that the changes occurring in tumor cells were irrevocable, and it has seemed self-evident to oncologists that the only hope the cancer patient has is for the physician to destroy every bit of the alien substance. The recurrence of a cancer that has been removed has been evidence to them that fragments had remained, or that the cancer had distributed its seeds into other parts of the body. This seems to be the necessary conclusion if cancer is "caused" by defective genes.
New ideas of causality have grown up in science beside, or within, the science culture that is committed to platonism, reductionism, and genetic determinism. A few biologists, including Ana Soto and Carlos Sonnenschein, are applying more realistic ideas of causality to ecological, developmental, and cancer research. They have said (Soto, et al., 2009) "The ecological developmental biology (eco-devo) movement rejects the notion that development is merely the unfolding of a genetic program." If events such as cancer aren't "caused by genes," understanding the causes of cancer and the appropriate ways to treat it will require more holistic ways of looking at the tumor's relation to the organism, and the organism's relation to the environment.
It has been more than 40 years since experimenters demonstrated that cancer cells could be caused to revert to normal, by changing their environment. Harry Rubin (2006) has observed that cells can accumulate hundreds of mutations, and still function normally in the organism, but when separated and grown in a culture dish their differences become obvious. The surrounding cells in the body are causing the defective cells to remain normal in appearance, function, and growth behavior, instead of acting like cancer cells, and can also cause "stem-like" cells to differentiate appropriately.. He says "Intimate contact between the interacting cells is required to induce these changes." When stem cells enter a tumor, they don't find that regulatory, normalizing interaction with normal cells.
Work like Rubin's shows that even "myriad" mutations don't necessarily cause cancer, and another line of research shows that things which don't cause mutations can cause cancer--the "non-mutagenic carcinogens." The presence of mutations is neither sufficient nor necessary for causing cancer, but tumors do eventually accumulate serious damage, which causes most of the tumor cells to die quickly. Biological stress, or excitotoxic energy deprivation, destabilizes the genome; genetic changes develop as a result of prolonged destructive influences. The "non-genotoxic" carcinogens first cause inflammation, excitation, and energy impairment, leading to fibrosis, and atrophy. Cycles of cell injury, death, and repair cause chromosomes to deteriorate as the tissue loses its organization.
When a cell is stimulated, it responds, and the response requires energy. The stronger and more continuous the stimulus, the more energy the cell needs to continue responding. In some conditions, cells can desensitize themselves, to survive in the presence of continuous stimulation or irritation, but otherwise they are killed when they don't have enough energy to keep responding.
When a nerve is stimulated and responds, a wave of negative electrical charge passes through it; the electrical field accompanies a structural change in the cytoplasm of the nerve; similar changes occur in other types of cell. Stimulation of a nerve with negative (cathodal) polarity causes swelling, stimulation with the opposite polarity causes the opposite behavior; when nerve cells are inhibited, they shrink (Tasaki and Byrne, 1980; Tasaki, et al., 1988; Tasaki, 1999).
Swelling, an increase of the water content of an area of tissue, is a general feature of inflammation (Weiss, et al., 1951), whether it's in a lump caused by a bee sting, a bruise, or hives, or a cancer. Besides the instantaneous uptake of water described by Tasaki, there are increases that continue because of metabolic and chemical changes in the irritated cell. Tasaki has used gels of synthetic polymers to demonstrate that an electrical field can cause these changes, without the need for the "chemical osmotic" changes that are customarily assumed to account for the swelling changes caused by stress (Tasaki, 2002). When the pH of a protein gel becomes more alkaline, it swells. The electrical activation of a nerve causes a quick shift towards internal alkalinity (Endres, et al., 1986), followed by a sudden increase in lactic acid production. Although increased lactic acid causes acidity of an irritated or inflamed region, the conversion of pyruvic acid to lactic acid causes the interior of the stressed cell to become more alkaline, causing it to swell. This is the same process that causes the familiar swelling of tired muscles.
If blood vessels swell, the delivery of oxygen may be restricted, and hypoxia causes more intense swelling, because more lactic acid is produced, and less oxidized. This swelling pressure resembles an increase of osmolarity. For over 100 years, it has been customary to treat shock with "isotonic" fluids, which are in balance with well oxygenated tissues, with approximately 290 milliosmoles per liter, but this usually causes edema, swelling, and weight gain. Stressed tissues have been found to be in balance with fluids of much higher osmolarity, for example 372 mOsm/L (Tranum- Jensen, et al., 1981), and sometimes much higher.
Apart from its acidity, lactic acid acts as an excitatory signal. A very slight increase above the normal amount of lactic acid in the body fluids excites sensitive cells, and the amounts reached in inflamed tissues and in cancers will excite even stable cells such as myelinated nerves (Uchida and Murao, 1975).
Cancer cells show all the signs of being intensely stimulated, and this includes a high rate of oxygen consumption (deGroof, et al., 2009). The stimulation increases the energy requirements beyond the ability of the mitochondria's capacity to meet them, leading to the production of lactate even when a normal amount of oxygen is present. Even when both glucose and oxygen are supplied (which they usually aren't), the tumor cells will consume amino acids as fuel, as well as using them as material for growth. Tumors have been called "nitrogen traps" or "glutamine traps," but this has meaning beyond the use of the nitrogen for growth; it is involved in the energetic inefficiency of this process, and the reorganizing effects this wasteful flow of energy has on the tissue structure (Medina, 2001). When glutamine enters the Krebs cycle to be used as fuel, this interferes with the ability to oxidize glucose, causing more lactic acid to be formed, contributing to the excitation and increased energy requirement.
Lactic acid activates the other major mediators of inflammation, including prostaglandins (made from PUFA), free fatty acids (including arachidonate, that forms prostaglandins; Schoonderwoerd, et al., 1989), nitric oxide, carbon monoxide, proteolytic enzymes that degrade the extracellular matrix, TNF (Jensen, et al., 1990), hypoxia inducible factor (Lu, et al., 2002; McFate, et al., 2008), interferon, and interleukins. Arachidonic acid itself can increase lactate production (Meroni, et al., 2003). TNFalpha and interferon gamma activate lactic acid production by increasing prostaglandins (Taylor, et al., 1992).
Most of the present information about cancer cells' behavior, such as reactions to radiation and chemical toxins, has been based on the study of cells in culture dishes. For more than 70 years, it was generally believed that radiation caused mutations and cancer by directly modifying the cells' genetic material. Then, it was discovered that fresh cells that were added to a dish of irradiated cells also developed mutations. The radiation causes cells to emit excitatory, inflammatory, substances such as serotonin and nitric oxide, which injure the cells that are later put near them.
Applying this information to the existing knowledge that radiation induces cancer in animals, the doctrine of genetic determinism inferred that the radiation "bystander effect" is just another mechanism by which radiation produces the "mutant cancer cell" or clone of cancer cells. But the difference between events in vitro and in vivo is that cells which are injured in the organism immediately initiate a process of healing, and in that situation each of the substances emitted by injured cells is acting both locally and systemically to activate repair or regeneration of the damaged tissue. Cells isolated in a culture dish can't call on the organism for the necessary materials, so the responses of the "bystander" cells, leading to mutations and death, seem meaningless. The injured cells are merely toxic, rather than potentially being a stimulus to healing.
When any part of a living organism is injured, for example by x-rays or surgery, the emitted substances affect the endocrine and nervous systems, activating processes that change metabolism and behavior. The injured tissue takes on new functions, for example by locally synthesizing estrogen, cortisol (Vukelic, et al., 2011), and other hormones, as well as stimulating the normal endocrine glands to secrete them. These interactions have been generally disregarded in cancer treatment, because of the gene centered theory of cancer, but they are essential for understanding the "malignancy" of tumors, that property that makes them likely to return after the tumor has been destroyed, and to spread to other tissues. Has anyone ever heard of a radiologist or surgeon who measured estrogen or the various mediators of inflammation before, during, and after their treatments? Long range survival after breast cancer surgery is affected by the time in the menstrual cycle when the surgery is done (Lemon, et al., 1996).
All sorts of stress, inflammation, and tissue injury increase the concentration of estrogen, both locally and systemically. Estrogen in turn produces hypoxia, swelling, lactic acid formation, and stimulates cell multiplication. Even a brief period of hypoxia will cause the secretion of lactate and other chemoattractants (Neumann, et al., 1993), which will cause cells to move into the hypoxic area from the blood stream. Although lactic acid attracts immune cells, it probably reduces their anticancer functions, and it stimulates the formation of new blood vessels, supporting continued growth and expansion of the multiplying cells (Hirschhaeuer, et al., 2011). When a tissue is being repaired normally, the new cells sense a quorum, and stop multiplying. The return of nerves to the damaged area is part of the regenerative process; nerves have inductive and stabilizing effects on differentiating cells.
These complex interactions between tumor cells and the rest of the organism are not considered by the ideology of medical oncologists. The ruling belief is that the malignancy of cells can be determined by examining them microscopically, and that their rate of growth can be determined, and that the tumor's approximate time of origin can be estimated. After surgically removing a tumor, the administration of chemotherapy and/or radiation is governed by mathematical descriptions of the expected behavior of cancer cells.
The mathematical relation of mortality to aging was described by Benjamin Gompertz, an actuary, in 1825, based on the understanding that people become less able to resist dying as they get older. This Gompertzian growth curve, which is realistic when applied to a population of people, flies, or rabbits, was applied to tumor growth (A.K. Laird, in 1964). Gompertz' reasoning that the probability of a person's dying increases with age has nothing to do with cancer cells, and there is very little evidence that his law of growth is useful for describing tumors. Laird's evidence consisted of 19 tumor samples, taken from 10 mice, 8 rats, and a rabbit. Her suggestion that the continuing deceleration of the growth rate might represent a natural growth regulating process wasn't influential, but her use of an actuarial formula, suggesting certain properties of cancer cells, has been extremely influential. It seems to be the profession's great need for justification that has made a Law of Tumor Growth so important to them.
At the time Laird did the tumor growth study, there was considerable interest in the idea that the immune system could be induced to prevent tumor growth. In 1951, Chester Southam, of the Sloan-Kettering Institute, tested his theory of cancer immunity on hundreds of patients and prisoners, and his results were widely reported. He found that pieces of tumor implanted in healthy people caused a local intense inflammation, which healed completely after two or three weeks. In sick people, the rejection of the cancer implant took about twice as long, and in people who already had cancer, the implant was very slow to be destroyed, and sometimes it was still present when they died.
In 1889, Stephen Paget had noticed that cancers metastasize only into certain organs, and compared the cancer cells to seeds that "can only live and grow if they fall on congenial soil." While many people, like Southam, saw a failing "immune system" as part of the congenial soil, and suggested vaccination to activate an immune rejection of the tumor, others have suggested "reducing the soil to dust," making growth impossible in a more general way. Recently, this attitude has taken the form of different ways of "starving" cancer, by reducing sugar in the diet, or by blocking cells' ability to use sugar. The idea of making the "soil" inhospitable to cancer is a variation on the theme of killing the unwanted tissue.
As long as the lump is defined as an alien material, killing it by any means seems reasonable, but if it is seen as the body's attempt to repair itself, then killing it is no more reasonable than it would be to cut the spots out of someone with smallpox. When a cell is dying, it emits growth stimulating signals (Huang, et al., 2011). That's a normal part of tissue renewal. Some of its substance guides the differentiation of new cells, as demonstrated long ago by Polezhaev (discussed in my previous article, "Stem cells, cell culture, and culture: Issues in regeneration"). Anything that injures a tissue enough to require cells to be replaced causes the activation of a regulatory protein, hypoxia-inducible factor, HIF, which inhibits mitochondrial respiration, causing a shift toward glycolytic metabolism, increasing substances needed for growth. HIF is essential to the healing of any wound. Even glucose deprivation can cause the induction of HIF.
Prostaglandins, made from polyunsaturated fatty acids released by stimulation, can cause HIF to increase, but HIF also causes prostaglandins to increase. Lactic acid increases the expression of HIF, while HIF causes cells to shift metabolically to depend on converting glucose to lactic acid, that is, to adopt the "cancer metabolism." HIF is recognized as a fundamental problem in "cancer therapy," since HIF allows the cancer to resist the treatment, but the treatment increases HIF.
Radiation, chemotherapy, and surgery all activate these processes of cell replacement, and unless something has changed to improve the organism's recuperative ability, it isn't clear why the cells which replace the missing part should be more able to satisfactorily complete the recovery process than the original cells were. Even the amount of radiation in a single dental x-ray is enough to activate the excitatory-inflammatory processes, and a "therapeutic" x-ray to any part of the body excites similar, but much greater, processes throughout the body. But the ideology of "the cancer cell," and the Gompertz Growth Law, guide the practice of cancer treatment.
Many years ago, Harry Rubin was impressed by hearing from a pathologist that he had been able to find diagnosable cancer somewhere in the body of every person over the age of 50 that he had autopsied. If everyone has cancer by the age of 50, that means that cancer is harmless for most people, and that small cancers might frequently appear, and be spontaneously removed as part of the body's regular house-cleaning. One of the reasons that spontaneous regression of tumors seems so rare is undoubtedly that most tumors are quickly cut out by surgeons.
Preventing injury should be a basic consideration, but the medical slogan, "first do no harm," just doesn't apply to the cancer treatment industry, and this results from the doctrine of "the cancer cell," which is something to be destroyed or kept from multiplying. In the process of diagnosing a cancer, and during the course of treating it, the patient is usually subjected to multiple x-ray examinations, sometimes given radioactive drugs that supposedly concentrate in hidden tumors to emit positrons, and often has toxic contrast agents injected even for MRI examinations. These procedures, even before the destructive "therapies" begin, are adding to the body's inflammatory burden, interfering with the body's ability to complete a healing process. Decisions about pain control usually disregard the effects of the drugs on tumor growth and general vitality--for example, the opiates stimulate histamine release, which increases inflammation and tumor growth.
In 1927, Bernstein and Elias found that rats eating a fat free diet had almost no spontaneous cancer, and many studies since then in animals and people have shown a close association between polyunsaturated fatty acids and cancer. The polyunsaturated fatty acids in themselves, and their breakdown products, are excitatory and destabilizing to normal cells, but by modifying the sensitivity and energy production of cells, they limit cells' ability to respond to stimulation and destabilizing influences. Although they aren't essential for wound healing (Porras-Reyes, et al., 1992), they and their metabolites, the prostaglandins, are very conspicuous in wounds and tumors, and their proportion generally increases with aging. The prostaglandins are involved in several vicious cycles, including that with HIF mentioned above. This makes the PUFA and prostaglandins important to consider in relation to optimizing wound healing, and decreasing cancerization. Aspirin's protective and therapeutic effects in cancer are starting to be recognized, but there are several other things that can synergize with aspirin to reduce the circulation of free fatty acids and their conversion to prostaglandins. Niacinamide, progesterone, sugar, carbon dioxide, and red light protect against both free fatty acids and prostaglandins.
Since excitation leads to intracellular alkalinity and swelling, reducing the excitation seems reasonable, and many things which protect cells against excitation also have demonstrated anticancer effects. Local anesthetics, antihistamines, and antiinflammatory substances and some anesthetics such as xenon (Weigt, et al., 2009) are safe. Inhibitory substances related to GABA are being investigated for their ability to stop tumor growth. Simply stopping excessive excitation tends to restore the dominance of oxidative respiration over glycolysis.
To restore the supply of oxygen, sugar, and nutrients, swelling must be stopped. Hyperosmotic fluids act directly on swollen cells, removing water. Stopping excitation allows a return to efficient metabolism and reduces the injury potential, allowing the pH to decrease; with lower pH, the cell releases some of its water.
Increasing carbon dioxide lowers the intracellular pH, as well as inhibiting lactic acid formation, and restoring the oxidation of glucose increases CO2. Inhibiting carbonic anhydrase, to allow more CO2 to stay in the cell, contributes to intracellular acidification, and by systemically increasing carbon dioxide this inhibition has a broad range of protective anti-excitatory effects. The drug industry is now looking for chemicals that will specifically inhibit the carbonic anhydrase enzymes that are active in tumors. Existing carbonic anhydrase inhibitors, such as acetazolamide, will inhibit those enzymes, without harming other tissues. Aspirin has some effect as an inhibitor of carbonic anhydrase (Bayram, et al., 2008). Since histamine, serotonin (Vullo, et al., 2007), and estrogen (Barnett, et al., 2008; Garg, 1975) are carbonic anhydrase activators, their antagonists would help to acidify the hypoxic cells. Testosterone (Suzuki, et al., 1996) and progesterone are estrogen antagonists that inhibit carbonic anhydrase.
With aging, cells have less ability to produce energy, and are often more easily stimulated. The accumulation of polyunsaturated fats is one of the factors that reduce the ability of mitochondria to produce energy (Zhang, et al., 2006, 2009; Yazbeck, et al., 1989). Increased estrogen exposure, decreased thyroid hormone, an increased ratio of iron to copper, and lack of light, are other factors that impair the cytochrome oxidase enzyme.
The increased intracellular alkalinity and intracellular calcium that result from the combination of those factors increase the tendency of cells to be overstimulated, leading to aerobic glycolysis, the cancer metabolism. Improving any part of the system tends to increase carbon dioxide and decrease lactate, permitting differentiated functioning.
There are many people currently recommending fish oil (or other highly unsaturated oils) for preventing or treating cancer, and it has become almost as common to recommend a sugar free diet, "because sugar feeds cancer." This is often, incorrectly, said to be the meaning of Warburg's demonstration that cancer cells have a respiratory defect that causes them to produce lactic acid from glucose even in the presence of oxygen. Cancer cells use glucose and the amino acid glutamine primarily for synthetic purposes, and use fats as their energy source;the growth stimulating effect of the "essential fatty acids" (Sueyoshi and Nagao, 1962a; Holley, et al., 1974) shows that depriving a tumor of those fats retards its growth. The great energetic inefficiency of the cancer metabolism, which causes it to produce a large amount of heat and to cause systemic stress, failure of immunity, and weight loss, is because it synthesizes fat from glucose and amino acids, and then oxidizes the fat as if it were diabetic.
Estrogen, which is responsible for the fact that women burn fatty acids more easily than men, is centrally involved in this metabolic inefficiency. When a tissue is exposed to estrogen, within minutes it takes up water, and begins to synthesize fat, with a tendency to produce lactic acid at the same time. The alkalizing effect of lactic acid production is apparently what accounts for the uptake of water. Since it takes longer, at least 30 minutes, to produce a significant amount of new enzymes, these early changes are explained by the activation of existing enzymes by estrogen.
The transhydrogenases, or the transhydrogenase function of the steroid dehydrogenases, which shift metabolic energy between glycolytic and oxidative systems, have been shown to explain these effects of estrogen, but the transhydrogenases can be activated by many stressors. The biological function of the transhydrogenases seems to be to allow cells to continue growth and repair processes in a hypoxic environment. Estrogen can start the process by creating new pathways for electrons, and will promote processes that are started by something else, and progesterone is estrogen's natural antagonist, terminating the process.
Recently, a group at Johns Hopkins University (Le, et al., 2012) has been working out the implications of this ability to change the metabolism under hypoxia: Using an isotope-labeled amino acid, ". . . glutamine import and metabolism through the TCA cycle persisted under hypoxia, and glutamine contributed significantly to citrate carbons. Under glucose deprivation, glutamine-derived fumarate, malate, and citrate were significantly increased." The implication of this is that if the tumor isn't supplied with sugar, it will increase the rate at which it consumes the host's proteins. Forty years ago the work of Shapot and Blinov was showing the same effect, except that they demonstrated the involvement of the whole organism, especially the liver, in interaction with the tumor (Blinov and Shapot, 1975).
The alkaline cancer cell surrounds itself by the acid that it emits, and this extracellular acidity increases the ability of fatty acids to enter the cell (Spector, 1969); cancer cells, although they are synthesizing fat, also avidly take it up from their environment (Sueyoshi and Nagao, 1962b). This fat avidity is so extreme that cancer cells in vitro will eat enough polyunsaturated fat to kill themselves. This has been offered as proof that fish oil kills cancer. Saturated fats, however, have a calming effect on cancer cells, inhibiting their aerobic glycolysis (Marchut, et al., 1986) while permitting them to resume the respiratory production of energy.
The foods that nourish the patient well enough to support healing while permitting energy reserves to be built up are also the foods that don't interfere with the hormones, that don't cause spurious excitation of the tissues. The polyunsaturated fats directly stimulate the stress hormones, activate the excitatory amino acid signals, and directly excite cells, while the saturated fats have opposite effects, and are anti-inflammatory, and also don't interfere with mitochondrial function. When we eat more carbohydrate than can be oxidized, some of it will be turned into saturated fats and omega-9 fats, and these will support mitochondrial energy production. Carbohydrates in the diet also help to decrease the mobilization of fatty acids from storage; niacinamide and aspirin support that effect. Sugars are probably more favorable than starches for the immune system (Harris, et al., 1999), and failure of the immune system is a common feature of cancer. Polyunsaturated fats are generally known to suppress the immune system. Foods that provide generous amounts of sodium, calcium, magnesium, and potassium, help to minimize stress. Trace minerals and vitamins are important, but can be harmful if used excessively--iron excess is important to avoid.
Emodin, an anti-inflammatory substance found in cascara sagrada bark and other plants, is similar to other molecules that have been used for treating cancer, and one of its effects is to lower HIF: "Consistently, emodin attenuated the expression of cyclooxygenase 2 (COX-2), VEGF, hypoxia inducible factor 1 alpha (HIF-1!), MMP-1 and MMP-13 at mRNA level in IL-1"and LPS-treated synoviocytes under hypoxia" (Ha, et al., 2011). MMP-1 and MMP-13 are collagenase enzymes involved in metastasis. When cells are fully nourished, supplied with protective hormones, and properly illuminated, their ability to communicate should be able to govern their movements, preventing--and possibly reversing--metastatic migration.
Cancer Res. 2008 May 1;68(9):3505-15. Estrogen receptor regulation of carbonic anhydrase XII through a distal enhancer in breast cancer.Barnett DH, Sheng S, Charn TH, Waheed A, Sly WS, Lin CY, Liu ET, Katzenellenbogen BS.
Bioorg Med Chem. 2008 Oct 15;16(20):9101-5.In vitro inhibition of salicylic acid derivatives on human cytosolic carbonic anhydrase isozymes I and II. Bayram E, Senturk M, Kufrevioglu OI, Supuran CT.
Int J Cancer. 1984 Oct 15;34(4):529-33. Effect of dietary stearic acid on the genesis of spontaneous mammary adenocarcinomas in strain A/ST mice. Bennett AS. Zeitschr. Krebsforsch. 28(1), 1-14, 1. Lipoids and carcinoma growth, Bernstein, S. and Elias, H.
Vopr Onkol. 1974;20(12):60-5. [Role of gluconeogenesis in the maintenance of normoglycemia in the body of animals with transplanted tumors]. [Article in Russian] Blinov VA, Shapot VS.
Bull Exp Biol Med. 1975 Jan;77(7):770-2. Hyperglycemia and gluconeogenesis in the liver of mice with tumors. Blinov VA, Shapot VS. Gluconeogenesis, when sharply stimulated by exhaustion of the liver glycogen reserves, is one of the factors maintaining the normal blood sugar level in mice with tumors. Hyperglycemia induce by glucose leads to an increase in the liver glycogen content and a decrease in the intensity of gluconeogenesis in control mice with tumors. Only in the latter, however, does glycogen synthesis from noncarbohydrate compounds rise again steadily after the injections of glucose are discontinued.
Minerva Ginecol. 2010 Dec;62(6):573-83. Extranuclear signaling by estrogen: role in breast cancer progression and metastasis. Cortez V, Mann M, Brann DW, Vadlamudi RK.
J Steroid Biochem. 1987 Jun;26(6):679-85. Cooxidation of steroidal and nonsteroidal estrogens by purified prostaglandin synthase results in a stimulation of prostaglandin formation. Degen GH, McLachlan JA, Eling TE, Sivarajah K.
Mol Cancer. 2009 Jul 31;8:54. Increased OXPHOS activity precedes rise in glycolytic rate in H-RasV12/E1A transformed fibroblasts that develop a Warburg phenotype. de Groof AJ, te Lindert MM, van Dommelen MM, Wu M, Willemse M, Smift AL, Winer M, Oerlemans F, Pluk H, Fransen JA, Wieringa B.
Can J Biochem. 1972 May;50(5):447-56. Pyridine-adenine dinucleotide transhydrogenase activity in cells cultured from rat hepatoma. De Luca C, Gioeli RP.
J Clin Invest. 1966 Aug;45(8):1268-72. Pyridine nucleotide transhydrogenase in normal human and leukemic leukocytes. Evans AE, Kaplan NO.
J Pharmacol Exp Ther. 1975 Feb;192(2):297-302. Induction of hepatic carbonic anhydrase by estrogen. Garg LC.
Biol Pharm Bull. 2011;34(9):1432-7. Emodin inhibits proinflammatory responses and inactivates histone deacetylase 1 in hypoxic rheumatoid synoviocytes. Ha MK, Song YH, Jeong SJ, Lee HJ, Jung JH, Kim B, Song HS, Huh JE, Kim SH.
Eur J Cancer. 1977 Aug;13(8):793-800. Alkalotic disequilibrium in patients with solid tumors: rediscovery of an old finding. Harguindey S, Speir WA, Kolbeck RC, Bransome ED.
J Surg Res. 1999 Apr;82(2):339-45. Diet-induced protection against lipopolysaccharide includes increased hepatic NO production. Harris HW, Rockey DC, Young DM, Welch WJ.
J Biol Chem. 2011 Dec 23;286(51):44177-86. A dormant state modulated by osmotic pressure controls clonogenicity of prostate cancer cells. Havard M, Dautry F, Tchenio T.
Biochem Biophys Res Commun. 2007 Jan 12;352(2):437-43. Non-hypoxic induction of HIF-3alpha by 2-deoxy-D-glucose and insulin. Heidbreder M, Qadri F, Johren O, Dendorfer A, Depping R, Frohlich F, Wagner KF, Dominiak P.
Surg Forum. 1958;9:614-9. An estradiol sensitive transhydrogenase in normal and malignant breast tissue. Hershey FB.
Cancer Res. 2011 Nov 15;71(22):6921-5. Lactate: a metabolic key player in cancer.Hirschhaeuser F, Sattler UG, Mueller-Klieser W.
Am J Physiol Cell Physiol May 2000 vol. 278 no. 5, Hypertonic perfusion inhibits intracellular Na and Ca accumulation in hypoxic myocardium. Ho HS, Liu H, Cala PM, and Anderson SE.
Proc Natl Acad Sci U S A. 1974 Oct;71(10):3976-8. Control of growth of a tumor cell by linoleic acid. Holley RW, Baldwin JH, Kiernan JA. "The growth of mouse myeloma XS 63.5 cells in cell culture is dependent on serum. Among the several growth factors present in serum, the lipid fraction is highly active. The growth factor(s) provided by the serum lipid fraction can be replaced by unsaturated fatty acids."
Nat Med. 2011 Jul 3;17(7):860-6. Caspase 3-medxiated stimulation of tumor cell repopulation during cancer radiotherapy. Huang Q, Li F, Liu X, Li W, Shi W, Liu FF, O'Sullivan B, He Z, Peng Y, Tan AC, Zhou L, Shen J, Han G, Wang XJ, Thorburn J, Thorburn A, Jimeno A, Raben D, Bedford JS, Li CY. "In cancer treatment, apoptosis is a well-recognized cell death mechanism through which cytotoxic agents kill tumor cells. Here we report that dying tumor cells use the apoptotic process to generate potent growth-stimulating signals to stimulate the repopulation of tumors undergoing radiotherapy."
J Surg Res. 1990 Oct;49(4):350-3. Lactic acidosis increases tumor necrosis factor secretion and transcription in vitro. Jensen JC, Buresh C, Norton JA.
J Biol Chem. 1969 Aug 25;244(16):4413-21. Human placental 17 beta-estradiol dehydrogenase. IV. Differentiation of 17 beta-estradiol-activated transhydrogenase from the transhydrogenase function of 17 beta-estradiol dehydrogenase. Karavolas HJ, Orr JC, Engel LL.
Neuro Endocrinol Lett. 2011;32(4):380-8. Immunotherapy of cervical cancer as a biological dissipative structure. Klimek R, Klimek M, Jasiczek D.
BMC Cancer. 2010 Jun 7;10:263. The microenvironment determines the breast cancer cells' phenotype: organization of MCF7 cells in 3D cultures. Krause S, Maffini MV, Soto AM, Sonnenschein C.
Biosci Rep. 2012 Feb;32(1):91-104. Anti-neoplastic action of aspirin against a T-cell lymphoma involves an alteration in the tumour microenvironment and regulation of tumour cell survival. Kumar A, Vishvakarma NK, Tyagi A, Bharti AC, Singh SM.
ANL Rep. 1963 May:216-22. Dynamics of tumor growth. ANL-6723. Laird AK.
Br J Cancer. 1964 Sep;13:490-502. Dynamics of tumor growth. Laird AK.
Cell Metab. 2012 Jan 4;15(1):110-21. Glucose-independent glutamine metabolism via TCA cycling for proliferation and survival in B cells. Le A, Lane AN, Hamaker M, Bose S, Gouw A, Barbi J, Tsukamoto T, Rojas CJ, Slusher BS, Zhang H, Zimmerman LJ, Liebler DC, Slebos RJ, Lorkiewicz PK, Higashi RM, Fan TW, Dang CV. "Using [U- (13)C,(15)N]-glutamine as the tracer, glutamine import and metabolism through the TCA cycle persisted under hypoxia, and glutamine contributed significantly to citrate carbons. Under glucose deprivation, glutamine-derived fumarate, malate, and citrate were significantly increased."
Steroids. 2012 Jan 28. Calcium-induced activation of estrogen receptor alpha--New insight.Leclercq G.
Nebr Med J. 1996 Apr;81(4):110-5. Timing of breast cancer surgery during the luteal menstrual phase may improve prognosis. Lemon HM, Rodriguez-Sierra JF.
Oncogene. 2012 Jan 23. RhoA triggers a specific signaling pathway that generates transforming microvesicles in cancer cells. Li B, Antonyak MA, Zhang J, Cerione RA. Ralph SJ: ; Milsom C; Chang YW.
J Biol Chem. 2002 Dec 20;277(51):50081-6. Prostaglandin E2 induces hypoxiainducible factor-1alpha stabilization and nuclear localization in a human prostate cancer cell line. Liu XH, Kirschenbaum A, Lu M, Yao S, Dosoretz A, Holland JF, Levine AC.
Cancer Res. 2007 Oct 1;67(19):9013-7. Loss of the mitochondrial bioenergetic capacity underlies the glucose avidity of carcinomas.López-Ríos F, Sánchez-Aragó M, García-García E, Ortega AD, Berrendero JR, Pozo-Rodríguez F, L ópez-Encuentra A, Ballestín C, Cuezva JM.
J Biol Chem. 2002 Jun 28;277(26):23111-5. Hypoxia-inducible factor 1 activation by aerobic glycolysis implicates the Warburg effect in carcinogenesis. Lu H, Forbes RA, Verma A.
Acta Biochimica Polonica (1986) 33(1), 7-16. The inhibitory effect of various fatty acids on aerobic glycolysis in Ehrlich ascites tumour cells. Marchut E, Gumińska M, Kedryna T.
J Biol Chem. 2008 Aug 15;283(33):22700-8. Pyruvate dehydrogenase complex activity controls metabolic and malignant phenotype in cancer cells. McFate T, Mohyeldin A, Lu H, Thakar J, Henriques J, Halim ND, Wu H, Schell MJ, Tsang TM, Teahan O, Zhou S, Califano JA, Jeoung NH, Harris RA, Verma A.
Lasers Surg Med. 2010 Aug;42(6):489-93. Effect of Ga-Al-As laser irradiation on COX-2 and cPLA2-alpha expression in compressed human periodontal ligament cells. Mayahara K, Yamaguchi A, Sakaguchi M, Igarashi Y, Shimizu N.
Circ Shock. 1990 Aug;31(4):407-18. Capillary narrowing in hemorrhagic shock is rectified by hyperosmotic saline-dextran reinfusion. Mazzoni MC, Borgstrom P, Intaglietta M, Arfors KE.
Journal of Nutrition. 2001;131:2539S-2542S. Glutamine and Cancer, Medina MÃ.
Int J Androl. 2003 Oct;26(5):310-7. Possible role of arachidonic acid in the regulation of lactate production in rat Sertoli cells. Meroni SB, Riera MF, Pellizzari EH, Schteingart HF, Cigorraga SB.
Biofizika. 1967 Nov-Dec;12(6):1085-6. [Increase in unsaturated fatty acids during tumor growth]. [Article in Russian] NeÄfakh EA, Lankin VZ.
Br Heart J. 1993 Jul;70(1):27-34. Cardiac release of chemoattractants after ischaemia induced by coronary balloon angioplasty. Neumann FJ, Richardt G, Schneider M, Ott I, Haupt HM, Tillmanns H, Schömig A, Rauch B.
J Steroid Biochem 1986 May;24(5):1033-9. Aromatase activity and concentrations of cortisol, progesterone and testosterone in breast and abdominal adipose tissue. Newton CJ, Samuel DL, James VH.
J Gerontol A Biol Sci Med Sci. 2005 Aug;60(8):970-5. Coenzyme Q10 protects from aging-related oxidative stress and improves mitochondrial function in heart of rats fed a polyunsaturated fatty acid (PUFA)-rich diet. Ochoa JJ, Quiles JL, Huertas JR, Mataix J.
J Gerontol A Biol Sci Med Sci. 2007 Nov;62(11):1211-8. Effect of lifelong coenzyme Q10 supplementation on age-related oxidative stress and mitochondrial function in liver and skeletal muscle of rats fed on a polyunsaturated fatty acid (PUFA)-rich diet. Ochoa JJ, Quiles JL, Lopez-Frias M, Huertas JR, Mataix J.
Br J Cancer. 2007 Dec 3;97(11):1505-12. In vitro irradiation of basement membrane enhances the invasiveness of breast cancer cells. Paquette B, Baptiste C, Therriault H, Arguin G, Plouffe B, Lemay R.
Br J Cancer. 2011 Aug 9;105(4):534-41. Radiation-enhancement of MDA-MB-231 breast cancer cell invasion prevented by a cyclooxygenase-2 inhibitor. Paquette B, Therriault H, Desmarais G, Wagner R, Royer R, Bujold R.
Prostaglandins Leukot Essent Fatty Acids. 1992 Apr;45(4):293-8. Essential fatty acids are not required for wound healing. Porras-Reyes BH, Schreiner GF, Lefkowith JB, Mustoe TA.
Cancer Res. 1957 Dec;17(11):1112-9. Comparison of transhydrogenase and pyridine nucleotide-cytochrome c reductase activities in rat liver and Novikoff hepatoma. Reynafarje B, Potter VR.
Bioessays. 2006 May;28(5):515-24. What keeps cells in tissues behaving normally in the face of myriad mutations? Rubin H.
Enzymologia. 1966 Apr 30;30(4):237-42. [Occurrence of pyridine nucleotide transhydrogenase in mitochondria of various ascites tumors] [Article in German] Salvenmoser F, Kramar R, Seelich F.
Basic Res Cardiol. 1989 Mar-Apr;84(2):165-73. Enhanced lipolysis of myocardial triglycerides during low-flow ischemia and anoxia in the isolated rat heart. Schoonderwoerd K, Broekhoven-Schokker S, Hulsmann WC, Stam H.
Naturwissenschaften. 1965 Jun;52:307-8. On the effect of NADPH2-NADtranshydrogenase on direct oxidation of glucose; experiments with the use of Ehrlich ascites tumor homogenates. Seelich F, Salvenmoser F, Kramar R.
J Endocrinol 1998 Sep;158(3):401-7. Progesterone inhibits glucocorticoiddependent aromatase induction in human adipose fibroblasts. Schmidt M, Renner C, Loffler G.
Cancer Res. 1974 Aug;34(8):1827-32. Blood glucose levels and gluconeogenesis in animals bearing transplantable tumors. Shapot VS, Blinov VA.
EMBO J. 2007 Mar 21;26(6):1713-25. Structures and physiological roles of 13 integral lipids of bovine heart cytochrome c oxidase. Shinzawa-Itoh K, Aoyama H, Muramoto K, Terada H, Kurauchi T, Tadehara Y, Yamasaki A, Sugimura T, Kurono S, Tsujimoto K, Mizushima T, Yamashita E, Tsukihara T, Yoshikawa S.
Semin Cancer Biol. 2008 Oct;18(5):372-7. Theories of carcinogenesis: an emerging perspective. Sonnenschein C, Soto AM.
Cancer Res. 2011 Jul 1;71(13):4334-7. The death of the cancer cell. Sonnenschein C, Soto AM.
J Lipid Res. 1969 Mar;10(2):207-15. Influence of pH of the medium on free fatty acid utilization by isolated mammalian cells. Spector AA.
Cancer Biol Ther. 2009 Jan;8(1):31-5. Inflammation, but not hypoxia, mediated HIF-1alpha activation depends on COX-2. Stasinopoulos I, O'Brien DR, Bhujwalla ZM.
Cancer Res. 1965 Aug;25(7):957-61. Hepatic lipids in tumor-bearing (glioma) mice. Stein AA, Opalka E, Rosenblum I.
Adv Exp Med Biol. 2004;559:325-30. Cell swelling-induced peptide hormone secretion. Strbak V, Benicky J, Greer SE, Bacova Z, Najvirtova M, Greer MA.
Allergy. 2011 Mar;66(3):341-50. Treatment of mast cells with carbon dioxide suppresses degranulation via a novel mechanism involving repression of increased intracellular calcium levels. Strider JW, Masterson CG, Durham PL.
Keio J Med. 1962 Dec;11:223-5. The influence of linoleum acid upon the growth of transplanted sarcoma, Sueyoshi Y and Nagao Y.
Keio J. Med. 1962;11(1):25-32. Studies on the linoleum acid contents in the phospholipids of the sarcoma, Sueyoshi Y and Nagao Y.
Comp Biochem Physiol C Pharmacol Toxicol Endocrinol. 1996 Jun;114(2): 105-12. Effect of testosterone on carbonic anhydrase and MG(2+)-dependent HCO3-stimulated ATPase activities in rat kidney: comparison with estradiol effect. Suzuki S, Yoshida J, Takahashi T.
Arch Biochem Biophys. 1991 Aug 15;289(1):33-8. A possible mechanism of mitochondrial dysfunction during cerebral ischemia: inhibition of mitochondrial respiration activity by arachidonic acid. Takeuchi Y, Morii H, Tamura M, Hayaishi O, Watanabe Y.
Int J Cancer. 2012 Jan 1;130(1):159-69. doi: 10.1002/ijc.25990. Sugars in diet and risk of cancer in the NIH-AARP Diet and Health Study. Tasevska N, Jiao L, Cross AJ, Kipnis V, Subar AF, Hollenbeck A, Schatzkin A, Potischman N.
Circ Shock. 1992 Jun;37(2):105-10. Inflammatory cytokines stimulate glucose uptake and glycolysis but reduce glucose oxidation in human dermal fibroblasts in vitro. Taylor DJ, Faragher EB, Evanson JM.
Acta Biol Med Ger. 1966;16(4):364-71. [The effect of higher fatty acids on the energy metabolism of Ehrlich-ascites tumor cells. I. The effect of saturated and transconfigurated unsaturated fatty acids on anaerobic glycolysis]. [Article in German] Theise H.
Am J Physiol. 1975 Jan;228(1):27-33. Acid-induced excitation of afferent cardiac sympathetic nerve fibers. Uchida Y, Murao S.
J Biol Chem. 2011 Mar 25;286(12):10265-75. Cortisol synthesis in epidermis is induced by IL-1 and tissue injury. Vukelic S, Stojadinovic O, Pastar I, Rabach M, Krzyzanowska A, Lebrun E, Davis SC, Resnik S, Brem H, Tomic-Canic M. Bioorg Med Chem Lett. 2007 Aug 1;17(15):4107-12. Carbonic anhydrase activators: activation of the human isoforms VII (cytosolic) and XIV (transmembrane) with amino acids and amines. Vullo D, Innocenti A, Nishimori I, Scozzafava A, Kaila K, Supuran CT.
Mol Nutr Food Res. 2011 Dec;55(12):1745-58. GABA (ÎÑ-aminobutyric acid), a nonprotein amino acid counters the ÎÇ-adrenergic cascade-activated oncogenic signaling in pancreatic cancer: a review of experimental evidence. Al-Wadei HA, Ullah MF, Al-Wadei M.
Cold Spring Harb Symp Quant Biol. 2011 Dec 22. Bioenergetic Origins of Complexity and Disease. Wallace DC. "The organizing power of energy flow is hypothesized to be the origin of biological complexity and its decline the basis of "complex" diseases and aging."
Acta Neurobiol Exp (Wars). 2009;69(4):429-40. Xenon blocks AMPA and NMDA receptor channels by different mechanisms. Weigt HU, Fohr KJ, Georgieff M, Georgieff EM, Senftleben U, Adolph O.
Neuroscience. 2010 Dec 15;171(3):859-68. Low energy laser light (632.8 nm) suppresses amyloid-ÎÇ peptide-induced oxidative and inflammatory responses in astrocytes. Yang X, Askarova S, Sheng W, Chen JK, Sun AY, Sun GY, Yao G, Lee JC. Comp Biochem Physiol A. 1989;94(2):273-6. The effects of essential fatty acid deficiency on brown adipose tissue activity in rats maintained at thermal neutrality. Yazbeck J, Goubern M, Senault C, Chapey MF, Portet R.
Am J Physiol Cell Physiol. 2006 May;290(5):C1321-33. Polyunsaturated fatty acids mobilize intracellular Ca2+ in NT2 human teratocarcinoma cells by causing release of Ca2+ from mitochondria.Zhang BX, Ma X, Zhang W, Yeh CK, Lin A, Luo J, Sprague EA, Swerdlow RH, Katz MS.
PLoS One. 2009 Jun 26;4(6):e6048. Linoleic acid-induced mitochondrial Ca(2+) efflux causes peroxynitrite generation and protein nitrotyrosylation. Zhang HM, Dang H, Yeh CK, Zhang BX.
Am J Physiol Heart Circ Physiol. 2011 Nov;301(5):H1882-90. Dihydrotestosterone attenuates hypoxia inducible factor-1α and cyclooxygenase-2 in cerebral arteries during hypoxia or hypoxia with glucose deprivation. Zuloaga KL, Gonzales RJ.
Library of Chadnet | wiki.chadnet.org