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  1. <html>

  2.     <head><title>Leakiness, aging, and cancer</title></head>

  3.     <body>

  4.         <h1>

  5.             Leakiness, aging, and cancer

  6.         </h1>

  7. 

  8.         A thin layer of fibrin lining blood vessels provides a filtering barrier that helps to strengthen the wall and

  9.         prevent other proteins from leaking out of the vessels, and it participates in repair processes when the blood

  10.         vessel is broken.<p>

  11.             Cellular energy metabolism is the basis for maintaining the barrier functions. Energy depletion causes the

  12.             endothelial cells lining blood vessels to become excessively permeable.

  13.         </p>

  14.         <p>

  15.             When the organism's resistance is low, proteins and fats that normally remain inside the bloodstream can

  16.             escape into the extracellular matrix and enter cells, contributing to their stress and disorganization, and

  17.             other materials can escape from cells and enter the bloodstream.

  18.         </p>

  19.         <p>

  20.             One of the simplest demonstrations of fibrin leakage is to shine a beam of light into the eye; the presence

  21.             of fibrin and other inappropriate molecules diffuses the light, causing a "flare" in the aqueous

  22.             compartment. Albumin, a small protein from the blood, is often seen in the urine during stress. The effects

  23.             of that sort of leakage vary with each organ.

  24.         </p>

  25.         <p>

  26.             Fibrin is an essential structural and functional part of the organism, but when it escapes from the

  27.             bloodstream it participates in the degenerative processes of inflammation, fibrosis, and tumor formation.

  28.             (Its fragments stimulate secretion of inflammatory mediators: Hamaguchi et al., 1991.)

  29.         </p>

  30.         <p>

  31.             In the hormonal environment dominated by estrogen, mild stresses such as exertion, or even restless sleep,

  32.             allow toxins (and sometimes bacteria) from the intestine to enter the bloodstream, triggering a complex

  33.             chain of events that create a systemic inflammatory state. Although these processes have been observed in

  34.             many simple experiments, their implications are almost always neglected or denied or explained away.

  35.             Incorporation of certain polyunsaturated fats into the tissues increases the leakiness of blood vessels, and

  36.             amplifies the reactions to stresses and inflammatory stimuli.

  37.         </p>

  38.         <p>

  39.             Antioxidants, thyroid hormone, progesterone, and antiinflammatory agents, including glycine or gelatin,

  40.             niacin, and saturated fats, can prevent, and in many cases reverse, these degenerative inflammatory

  41.             processes.

  42.         </p>

  43.         <p>

  44.             Even a single celled organism has to keep its parts separate, and highly differentiated multicelled

  45.             organisms have many special systems that serve to keep their parts separate, so the different tissues and

  46.             organs can maintain their distinct functions.

  47.         </p>

  48.         <p>

  49.             The movement of substances from blood to cell, and from cell to cell, is normally very tightly controlled,

  50.             and when the systems that control those movements of water and its solutes are damaged, the tissues'

  51.             structures and functions are altered. The prevention of inappropriate leakiness can protect against the

  52.             degenerative processes, and against aging itself, which is, among other things, a state of generalized

  53.             leakiness.

  54.         </p>

  55.         <p>

  56.             When cells' energy is depleted, water and various dissolved molecules are allowed to move into the cells,

  57.             out of the cells, and through or around cells inappropriately. The weakened cells can even permit whole

  58.             bacteria and similar particles to pass into and out of the blood stream more easily.

  59.         </p>

  60.         <p>

  61.             One of the earliest investigators of the effects of stress and fatigue on nerves and other cells was A.P.

  62.             Nasonov, in the first half of the 20th century. A.S. Troshin (1956) has reviewed his work in detail. He

  63.             showed that in cells as different as algae and nerve cells, fatigue caused them to take up dyes, and that

  64.             the dyes were extruded, if the cells were able to recover their energy. When nerve cells are excited for a

  65.             fraction of a second, they take up sodium and calcium, but quickly eliminate them. Prolonged excitation,

  66.             leading to fatigue, can gradually shift the balance, allowing more substances to enter, and to stay longer.

  67.         </p>

  68.         <p>

  69.             When nerves or other cells are quickly killed with heavy metals such as osmium, the metals are visible in a

  70.             layer at the surface, which is sometimes taken as evidence of a "cytoplasmic membrane," but if the cells

  71.             have suffered oxygen deprivation or have been injured by X-rays, the metal will be visible as a grey color

  72.             evenly distributed through the cell. The deposition of the metal occurs when it reacts with electrons. In

  73.             the relatively vital cell, the heavy metal stops at the surface, and is mostly reduced there, but the

  74.             devitalized cell presents no structural or chemical barrier to the entry of the metal, and the reactive

  75.             electrons appear to be evenly distributed through the cell. Oxygen deprivation, X-irradiation, and other

  76.             stresses cause the cell to be unable to use electrons to produce energy, and instead the electrons are

  77.             available to react destructively with whatever may be available. While Nasonov showed that dyes and even

  78.             particles enter energetically depleted cells, newer techniques are able to show that the leaky cells are

  79.             structurally disrupted by the excessive reduction of their proteins, by excited electrons and free radicals.

  80.         </p>

  81.         <p>

  82.             In the 1970s, experimenters found that muscles from vitamin E deficient animals released their enzymes when

  83.             washed in a saline solution, more easily than did the muscles from vitamin E replete animals. Other

  84.             experiments around the same time showed that reducing the ATP of muscles caused a similar loss of their

  85.             ability to retain their proteins.

  86.         </p>

  87.         <p>

  88.             Over the years, many experiments have established, both in vitro and in vivo, that fatigue, stress, aging,

  89.             and inflammation cause cells to lose their normal constituents, but also to allow foreign materials to enter

  90.             more easily.

  91.         </p>

  92.         <p>

  93.             When I was working on my thesis, around 1970, investigating the effects of aging on the metabolism of the

  94.             uterus, I found that the changes occuring during aging were (in all the ways I tested) the same as those

  95.             produced by X-irradiation, excess estrogen, oxygen deprivation, excess polyunsaturated fats, and vitamin E

  96.             deficiency.

  97.         </p>

  98.         <p>

  99.             Although everyone working in the lab was familiar with the appearance of the uterus from old hamsters (they

  100.             are typically large, stiff, and bluish), everyone was surprised when I suggested that the aged uteri seemed

  101.             to function as if they were under the influence of a considerable amount of estrogen. Everyone was familiar

  102.             with the medical textbook doctrine that "menopause is caused by estrogen deficiency." In humans,

  103.             gynecologists know about "Chadwick's sign," the fact that the uterine cervix turns blue or purple during

  104.             pregnancy, and everyone knows that blood is blue when it's deprived of oxygen, so it's surprising that

  105.             estrogen's effect on tissue oxygenation isn't widely recognized.

  106.         </p>

  107.         <p>

  108.             When estrogen is given to an animal, it almost instantly causes capillaries to become leaky, allowing water

  109.             to move out of the blood stream, and at the same time, estrogen causes cells to take up water. Both of these

  110.             processes are the same as the early effects of oxygen deprivation. In the normal reproductive cycle, the

  111.             surge of estrogen lasts only a few hours, and normal permeability is quickly restored by increasing

  112.             progesterone. During those intermittent short exposures to estrogen, there isn't a massive leakage of serum

  113.             proteins into the tissues. During the time of estrogenic influence, all kinds of cells are influenced, with

  114.             the excitatory equilibrium of nerve cells, glandular cells, and immune system cells being shifted, lowering

  115.             the threshold of excitation, or prolonging the excited state.

  116.         </p>

  117.         <p>

  118.             Anything that causes inflammation causes a similar loss of water from the blood, as it is taken up by

  119.             swelling cells. If inflammation is generalized, it causes circulatory shock, because the volume of the blood

  120.             has become insufficient to serve the organism's needs. One of Hans Selye's earliest observations of the

  121.             effect of an overdose of estrogen was that it causes shock.

  122.         </p>

  123.         <p>

  124.             Although water loss causes the blood to become more viscous under the influence of estrogen, the plasma

  125.             becomes hypotonic, meaning that it contains fewer osmotically active solutes than normal; some of the sodium

  126.             that helps to maintain the blood's osmotic balance is lost through the kidneys, and some is taken up by the

  127.             red blood cells and other cells. The osmotic imbalance of the blood causes tissue cells to take up more

  128.             water, contributing to their increased excitability. In many cases, the vascular leakage of inflammation and

  129.             shock can be corrected by using osmotically active substances, such as starch solutions, gelatin, or

  130.             concentrated sodium chloride.

  131.         </p>

  132.         <p>

  133.             The tissue water retention caused by estrogen, hypoxia, and stress is analogous to the swelling of gels and

  134.             colloids, that is, it's governed by the state of the electrons and counterions in the system. Excitation,

  135.             fatigue, or injury can cause a shift of pH toward alkalinity, causing water uptake and swelling.

  136.         </p>

  137.         <p>

  138.             The blue color of the pregnant cervix, or of the uterus in an animal given an overdose of estrogen,

  139.             indicates that the tissue isn't sufficiently oxygenated to maintain its normal red color, even though the

  140.             flow of blood is increased. Some experimenters have noticed that newborn animals sometimes have the postural

  141.             reflex (lordosis) that indicates an estrogenic state, and that suffocation can produce the same reflex.

  142.             Irradiating animals with x-rays will also produce the whole range of estrogenic effects.

  143.         </p>

  144.         <p>

  145.             One of the features of the aged uterus that I studied was the age pigment, lipofuscin, a brown waxy material

  146.             that accumulates in old or stressed tissues. Prolonged dosage with estrogen accelerates the formation of

  147.             this pigment, which is largely derived from oxidized polyunsaturated fatty acids. Increased amounts of those

  148.             fats in the diet, or a deficiency of vitamin E, or exposure to ionizing radiation, or oxygen deprivation,

  149.             can also accelerate the formation of the age pigment. The presence of the pigment intensifies the effect of

  150.             estrogen, since the pigment wastes oxygen by functioning as an oxidase enzyme.

  151.         </p>

  152.         <p>

  153.             Other tests that I did on aged, or estrogenized, uterine tissue indicated that several oxidative systems

  154.             were activated; for example, the tissues showed an extremely high activity of the enzyme peroxidase, and a

  155.             very intense reduction of a chemical dye (tetrazolium/formazan) that indicates the presence of reductive and

  156.             oxidative activity, of the sorts caused by radiation and oxygen deprivation. These reductive and oxidative

  157.             processes include the production of some free radicals that are capable of reacting randomly with

  158.             polyunsaturated fatty acids.

  159.         </p>

  160.         <p>

  161.             The interactions between estrogen and the polyunsaturated fats are now coming to be more widely recognized

  162.             as important factors in the inflammatory/hyperpermeable conditions that contribute to the development of

  163.             heart and blood vessel disease, hypertension, cancer, autoimmune diseases, dementia, and other less common

  164.             degenerative conditions.

  165.         </p>

  166.         <p>

  167.             Estrogen increases lipid peroxidation, and maintains a chronically high circulating level of free fatty

  168.             acids, mainly PUFA, activates the phospholipases that release arachidonic acid from cells leading to

  169.             formation of prostaglandins and isoprostanes, and increases the enzymes that form the inflammation-promoting

  170.             platelet activating factor (PAF) while suppressing the enzymes that destroy it, and increases a broad range

  171.             of other inflammatory mediators, interleukins, and NF-kappa B.

  172.         </p>

  173.         <p>

  174.             The leakage of enzymes out of cells and into the blood stream is recognized medically as evidence of damage

  175.             to the organ that is losing them. Different combinations of enzymes are commonly considered to be evidence

  176.             of a heart attack, or skeletal muscle damage, or liver disease, pancreatitis, prostate cancer, etc. But

  177.             often the reason for the leakage isn't understood. Hypothyroidism, for example, causes leakage of enzymes,

  178.             possibly mainly from the liver, but also from other organs. Excess estrogen, intense exercise, starvation,

  179.             anything that increases lipid peroxidation and free radical production, such as drinking alcohol when the

  180.             tissues contain polyunsaturated fats, can cause organs such as heart and liver to leak their components.

  181.         </p>

  182.         <p>

  183.             The loss of enzymes increases the energy needed to stay alive, but it doesn't necessarily change the basic

  184.             functions of the cell. (Though when mitochondrial enzymes leak out into the cytoplasm, the cell's energy

  185.             metabolism is impaired, at least temporarily.) But the entry of catalytic materials from other tissues

  186.             changes the organization of a cell, giving it conflicting instructions. In many situations, as L.V.

  187.             Polezhaev and V. Filatov demonstrated, the substances released during stress and degeneration serve to

  188.             stimulate healing and regeneration. But when the resources aren't available for full repair or regeneration,

  189.             only a scar, or atrophic fibrosis, or a tumor will be formed.

  190.         </p>

  191.         <p>

  192.             In severe stress, intracellular fibrin deposits have been found in the heart and other organs, including the

  193.             prostate gland. Deficiency of testosterone causes vascular leakage into the prostate. Fibrin promotes tumor

  194.             growth, partly by serving as a matrix, partly by releasing stimulatory peptides.

  195.         </p>

  196.         <p>

  197.             Kidney disease, diabetes, pregnancy toxemia and retinal degeneration are probably the best known problems

  198.             involving vascular leakage, but increasingly, cancer and heart disease are being recognized as consequences

  199.             of prolonged permeability defects. Congestive heart failure and pulmonary hypertension commonly cause

  200.             leakage of fluid into the lungs, and shock of any sort causes the lung to get "wet," a waterlogged condition

  201.             called "shock lung." Simply hyperventilating for a couple of minutes will increase leakage from the blood

  202.             into the lungs; hyperventilation decreases carbon dioxide, and increases serotonin and histamine. Hyperoxia

  203.             itself contributes to lung injury, and exacerbates emphysema, though it is common to see patients breathing

  204.             a high concentration of oxygen. Emphysema (which can be caused by hypothyroidism or hyper-estrogenism, and

  205.             often can be cured by thyroid or progesterone) and many other respiratory problems are associated with

  206.             capillary leakage. Cells of the lung and intestine are able to synthesize their own fibrin, apparently

  207.             because of their special problems in preventing leakage. Prolonged systemic inflammation can lead to lung

  208.             fibrosis, and fibrosis increases the likelihood of lung cancer.

  209.         </p>

  210.         <p>

  211.             The inflammatory state that causes exaggerated cellular permeability is very closely related to

  212.             "hyperventilation," the loss of too much carbon dioxide. The release of serotonin during hyperventilation

  213.             isn't the only cause of vascular leakage; the carbon dioxide itself is an essential factor in regulating the

  214.             state of cellular electrons and in maintaining cellular integrity. Hyperventilation, like the shift from

  215.             oxidative to glycolytic energy production that typifies estrogenized or stressed cells or cancer, raises

  216.             intracellular pH. In the case of mast cells, increasing alkalinity causes them to release histamine

  217.             (Alfonso, et al., 2005), but similar "alkaline-induced exocytosis" seems to occur in all stressed tissues.

  218.         </p>

  219.         <p>

  220.             The blood platelets that become incontinent and leak serotonin in the absence of carbon dioxide are

  221.             undergoing the same structural stresses experience by endothelial cells, smooth muscle cells, mast cells and

  222.             all other cells when carbon dioxide is depleted. Although it has been about 70 years since Yandell Henderson

  223.             made it clear that supplemental oxygen should be combined with carbon dioxide, mechanical ventilation in

  224.             hospitals is still causing lung injury resulting from hyperventilation, i.e., the absence of carbon dioxide.

  225.             A similar misunderstanding of biology was involved in the use of dialysis to treat kidney disease. Until

  226.             recently, commercial dialysis fluids contained acetate and/or racemic lactate instead of bicarbonate,

  227.             because of the difficulty of preparing bicarbonate solutions, and the result was that very prolonged

  228.             dialysis would damage the brain and other organs. (Veech and Gitomer, 1988, Veech and Fowler, 1987.)

  229.             Dialysis has been seen to increase lung permeability Bell, et al., 1988).

  230.         </p>

  231.         <p>

  232.             Amyloidosis produced by chronic dialysis affects all organs, but its effects are best known in the brain,

  233.             heart, kidneys, and lungs. Serum amyloid-A is one of the acute phase proteins, like C-reactive protein

  234.             (CRP), that are produced by inflammation. Estrogen, radiation and other stresses increase those

  235.             pro-inflammatory acute phase proteins, and decrease protective albumin, which is called a "negative acute

  236.             phase protein," since it decreases when the other acute phase proteins increase. The liver is the major

  237.             source of the acute phase proteins, and it is constantly burdened by toxins absorbed from the bowel;

  238.             disinfection of the bowel is known to accelerate recovery from stress.

  239.         </p>

  240.         <p>

  241.             Seen from the perspective of the stress-leakage syndrome, any serious injury or sickness damages all organs.

  242.             The exhaled breath is being used to diagnose inflammatory lung disease, since so many of the mediators of

  243.             inflammation are volatile, but systemic diseases such as cancer and arthritis, and relatively minor stress

  244.             can be detected by changes in the chemicals found in the breath. Polyunsaturated fats and their breakdown

  245.             products--aldehydes, prostaglandins, isoprostanes, hydrocarbons, and free radicals--and carbon monoxide,

  246.             nitric oxide, nitrite, and hydrogen peroxide are increased in the breath by most stresses. Both proline and

  247.             glycine (which are major amino acids in gelatin) are very protective for the liver, increasing albumin, and

  248.             stopping oxidative damage.

  249.         </p>

  250.         <p>

  251.             Saturated fats are protective against free radical damage and can reverse liver fibrosis. Thyroid hormone

  252.             protects against excess estrogen, and can prevent or reverse fibrosis of the heart. Antiestrogens are widely

  253.             effective against vascular leakage. Thyroid, progesterone, and testosterone are among the most effective

  254.             natural antiestrogens, and they are curative in many conditions that involve vascular leakage. Progesterone

  255.             and pregnenolone have been called the antifibromatic steroids, and it has been used to treat many

  256.             inflammatory and fibrotic diseases, including cancer.

  257.         </p>

  258.         <p>

  259.             The antiserotonin drugs are being increasingly used to treat fibrotic diseases, and other problems related

  260.             to vascular leakage.

  261.         </p>

  262.         <p>

  263.             Antiinflammatory and anticoagulant things, especially aspirin and vitamin E, protect against the accelerated

  264.             turnover of fibrinogen/fibrin caused by estrogen and the various inflammatory states.

  265.         </p>

  266.         <p>

  267.             © Ray Peat 2006. All Rights Reserved. www.RayPeat.com

  268.         </p>

  269.     </body>

  270. </html>