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  1. <html>

  2.     <head><title>Stem cells, cell culture, and culture: Issues in regeneration</title></head>

  3.     <body>

  4.         <h1>

  5.             Stem cells, cell culture, and culture: Issues in regeneration

  6.         </h1>

  7. 

  8.         <p>

  9.             Cell renewal is a factor in all aspects of health and disease, not just in aging and the degenerative

  10.             diseases. Many people are doing valid research relating to cell renewal and regeneration, but its usefulness

  11.             is seriously limited by cultural and commercial constraints. By recovering some of our suppressed

  12.             traditional culture, I think regenerative therapies can be developed quickly, by identifying and eliminating

  13.             as far as possible the main factors that interfere with tissue renewal.

  14.         </p>

  15. 

  16.         <p>

  17.             Science grew up in the highly authoritarian cultures of western Europe, and even as it contributed to

  18.             cultural change, it kept an authoritarian mystique. Any culture functions as a system of definitions of

  19.             reality and the limits of possibility, and to a great extent the "laws of nature" are decreed so that they

  20.             will harmonize with the recognized laws of society.

  21.         </p>

  22.         <p>

  23.             The practical success of Newton's "laws" of motion when they were applied to ballistics and "rocket science"

  24.             has led many people to value calculation, based on those laws, over evidence. In biology, the idea that an

  25.             organism is "the information it contains in its DNA blueprint" is an extention of this. The organism is

  26.             turned into something like a deductive expression of the law of DNA. This attitude has been disastrous.

  27.         </p>

  28. 

  29.         <p>

  30.             The old feudal idea of a divine and stable social organization was applied by some people to their idea of

  31.             biological organization, in which each cell (ruled by its nucleus) had its ordained place in the organism,

  32.             with the brain and the "master gland," the pituitary, ruling the subordinate organs, tissues, and cells.

  33.             "Anatomy" was taught from dead specimens, microscope slides, and illustrations in books. Most biologists'

  34.             thoughts about cells in organisms reflect the static imagery of their instruction. (<em>"The histological

  35.                 image of these tissues actually reflects an instantaneous picture of cells in a continuous flux."</em>

  36.             Zajicek, 1981.)

  37.         </p>

  38.         <p>

  39.             When a person has playful and observant interactions with natural things, both regularities and

  40.             irregularities will be noticed, and in trying to understand those events, the richness of the experience

  41.             will suggest an expansive range of possibilities. Perception and experimentation lead to understandings that

  42.             are independent of culture and tradition.

  43.         </p>

  44. 

  45.         <p>

  46.             But the mystique of science easily imposes itself, and distracts our attention from direct interactions with

  47.             things. As we learn to operate lab instruments, we are taught the kinds of results that can be expected, and

  48.             the concepts that will explain and predict the results of our operations. Science, as we learn about it in

  49.             schools and the mass media, is mostly a set of catechisms.

  50.         </p>

  51.         <p>

  52.             Our theories about organisms inform our experiments with cells or tissues that have been isolated from those

  53.             organisms. The conditions for growing cells in dishes are thought of as "physiological," in relation to the

  54.             solution's "physiological osmolarity," "physiological pH," nutrients, oxygenation, temperature, pressure,

  55.             etc. But these concepts of what is physiological derive from the monolithic ideology of the doctrinaire, and

  56.             often fraudulent, mainstream of biological science.

  57.         </p>

  58.         <p>

  59.             The catechismic nature of science has led people to expect some "break-throughs" to occur in certain areas,

  60.             and as authoritarian science has grown into "big science" managed by corporations and governments, those

  61.             break-throughs are generally expected to be produced by the newest and most expensive developments of "high

  62.             technology."

  63.         </p>

  64.         <p>

  65.             But looking closely at the real events and processes in the sciences in the last couple of centuries, it

  66.             turns out that useful advances have been produced mainly by breaking away from authoritarian doctrines, to

  67.             return to common sense and relatively simple direct observations.

  68.         </p>

  69.         <p>

  70.             Although people were cloning animals in the 1960s, it was still widely taught that it was impossible. The

  71.             students of the professors who taught that it was impossible are now saying that it requires high technology

  72.             and new research.

  73.         </p>

  74.         <p>

  75.             For the last 100 years the most authoritative view in biology has been that there are no stem cells in

  76.             adults, that brains, hearts, pancreases and oocytes are absolutely incapable of regeneration. But now,

  77.             people seem to be finding stem cells wherever they look, but there is a mystique of high technology involved

  78.             in finding and using them.

  79.         </p>

  80.         <p>

  81.             Whether it's deliberate or not, the emphasis on stem cell technology has the function of directing attention

  82.             away from traditional knowledge, the way allopathic medicine has de-emphasized the intrinsic ability of

  83.             people to recover from disease.

  84.         </p>

  85. 

  86.         <p>

  87.             This resembles the way that the Mendel-Morgan gene doctrine was used to suppress the knowledge gained from

  88.             centuries of experience of plant and animal breeders, and to belittle the discoveries of Luther Burbank,

  89.             Paul Kammerer, Trofim Lysenko, and Barbara McClintock. The same type of biochemical process that caused the

  90.             hereditary changes those researchers studied are involved in the differentiation and dedifferentiation of

  91.             stem cells that regulate healing and regeneration.

  92.         </p>

  93.         <p>

  94.             In the 1940s, even children discussed the biological discoveries of the 1920s and 1930s, the work in

  95.             regeneration and adaptation, parthenogenesis, and immortalization. The ideas of J. Loeb, T. Boveri, A.

  96.             Gurwitsch, J. Needham, C.M. Child, A. Carrel, et al., had become part of the general culture.

  97.         </p>

  98.         <p>

  99.             But that real biology was killed by a consortium of industry and government that began a little before the

  100.             second world war. In 1940, the government was supporting research in chemical and biological warfare, and

  101.             with the Manhattan Project the role of government became so large that all of the major research

  102.             universities were affected. Shortly after the war, many researchers from the Manhattan Project were

  103.             redeployed into "molecular genetics," where the engineering attitude was applied to organisms.

  104.         </p>

  105.         <p>

  106.             The simplistic genetic dogmas were compatible with the reductionist engineering approach to the organism.

  107.             The role of the government assured that the universities would subscribe to the basic scientific agenda. The

  108.             atmosphere of that time was described by Carl Lindegren as "The Cold War in Biology" (1966).

  109.         </p>

  110. 

  111.         <p>

  112.             The disappearance of the field concept in developmental biology was one of the strangest events in the

  113.             history of science. It didn't just fade away, it was "disappeared," in a massive undertaking of social

  114.             engineering. In its absence, stem cells will seem to be a profitable technological marvel, rather than a

  115.             universal life function, with a central role in everything we are and everything we do and can become.

  116.         </p>

  117.         <p>

  118.             Many people have tried to explain aging as a loss of cells, resulting from an intrinsic inability of any

  119.             cell other than a germ cell to multiply more than a certain number of times. More than 40 years ago Leonard

  120.             Hayflick popularized this doctrine in its most extreme form, saying that no cell can divide more than 50

  121.             times unless it is converted into a cancer cell. He and his followers claimed that they had explained why

  122.             organisms must age and die. At the moment the ovum is fertilized, the clock starts ticking for the

  123.             essentially mortal somatic cells.

  124.         </p>

  125.         <p>

  126.             In 1970, it was being seriously proposed that memory was produced by the death of brain cells, in a manner

  127.             analogous to the holes punched in cards to enter data into computers. The cultural dogma made it impossible

  128.             to consider that learning could be associated with the birth of new cells in the adult brain.

  129.         </p>

  130.         <p>

  131.             With the announcement in 1997 of the cloning of the sheep Dolly from a somatic cell taken from a 6 year old

  132.             sheep, there was renewed interest in the idea made famous by Alexis Carrel that all cells are potentially

  133.             immortal, and in the possibility of preserving the vitality of human cells. Within a few months, Hayflick

  134.             began reminding the public that "In the early 1960's we overthrew this dogma after finding that normal cells

  135.             do have a finite replicative capacity." ("During the first half of this century it was believed that because

  136.             cultured normal cells were immortal, aging must be caused by extra-cellular events.") The way Hayflick

  137.             "overthrew" more than 35 years of work at the Rockefeller Institute was by growing one type of cell, a lung

  138.             fibroblast, in culture dishes, and finding that the cultures deteriorated quickly.

  139.         </p>

  140. 

  141.         <p>

  142.             To draw global conclusions about an organism's development and aging from the degenerative processes seen in

  143.             a single type of cell, grown in isolation from all normal stimuli, would have been treated as nothing but

  144.             wild speculation, except that it occurred within a culture that needed it. No aspect of Hayflick's cell

  145.             culture system could properly be called physiological.

  146.         </p>

  147.         <p>

  148.             Other researchers, simply by changing a single factor, caused great increases in the longevity of the

  149.             cultured cells. Simply using a lower, more natural oxygen concentration, the cells were able to undergo 20

  150.             more divisions. Just by adding niacin, 30 more divisions; vitamin E, 70 more divisions. Excess oxygen is a

  151.             poison requiring constant adaptation.

  152.         </p>

  153.         <p>

  154.             Hayflick also published the observation that, while the cells kept in dishes at approximately body

  155.             temperature deteriorated, cells kept frozen in liquid nitrogen didn't deteriorate, and he concluded that

  156.             "time" wasn't the cause of aging. When I read his comments about the frozen cells, I wondered how anyone of

  157.             normal intelligence could make such stupid statements. Since then, facts that came out because of the

  158.             Freedom of Information Act, cause me to believe that a financial motive guided his thoughts about his

  159.             cultured fibroblasts.

  160.         </p>

  161.         <p>

  162.             Hayflick and his followers have been attacking the idea of anti-aging medicine as quackery. But he is

  163.             closely involved with the Geron corporation, which proposes that genetic alterations relating to telomeres

  164.             may be able to cure cancer and prevent aging. Their claims were reported by CNN as "Scientists discover

  165.             cellular 'fountain of youth'."

  166.         </p>

  167. 

  168.         <p>

  169.             The "wear and tear" doctrine of aging that derived from the ideology of the gene was reinforced and renewed

  170.             by Hayflick's cell culture observations, and it continued to rule the universities and popular culture.

  171.         </p>

  172.         <p>

  173.             But detailed investigation of skin cell growth showed that cells in the lower layer of the skin divide at

  174.             least 10,000 times in a normal lifetime, and similar processes occur in the lining of the intestine. The

  175.             endometrium and other highly renewable tissues just as obviously violated Hayflick's limit. Transplantation

  176.             experiments showed that pieces of mammary tissue or skin tissue could survive through ten normal lifetimes

  177.             of experimental animals without suffering the effects of aging.

  178.         </p>

  179.         <p>

  180.             Even the liver and adrenal gland are now known to be continuously renewed by "cell streaming," though at a

  181.             slower rate than the skin, conjunctiva, and intestine. Neurogenesis in the brain is now not only widely

  182.             accepted, it is even proposed as a mechanism to explain the therapeutic effects of antidepressants

  183.             (Santarelli, et al., 2003).

  184.         </p>

  185. 

  186.         <p>

  187.             August Weismann's most influential doctrine said that "somatic cells are mortal, only the germline cells are

  188.             immortal," but he based the doctrine on his mistaken belief that only the "germline" cells contained all the

  189.             genes of the organism. In 1885, to "refute" Darwin's belief that acquired traits could be inherited, he

  190.             promulgated an absolute "barrier" between "germline" and "soma," and invented facts to show that hereditary

  191.             information can flow only from the germline to the somatic cells, and not the other direction. Shortly after

  192.             DNA became popular in the 1950s as "the genetic material," Weismann's barrier was restated as the Central

  193.             Dogma of molecular genetics, that information flows only from DNA to RNA to protein, and never the other

  194.             direction.

  195.         </p>

  196.         <p>

  197.             It was only in 2003, after the reality of cloning was widely recognized, that a few experimenters began to

  198.             investigate the origin of "germline" cells in the ovary, and to discover that they derive from somatic cells

  199.             (Johnson, et al., 2004). With this discovery, the ancient knowledge that a twig (<em>klon</em>, in Greek)

  200.             cut from a tree could grow into a whole tree, bearing fruit and viable seeds, was readmitted to general

  201.             biology, and the Weismann barrier was seen to be an illusion.

  202.         </p>

  203.         <p>

  204.             Millions of people have "explained" female reproductive aging as the consequence of the ovary "running out

  205.             of eggs." Innumerable publications purported to show the exact ways in which that process occurs, following

  206.             the Weismann doctrine. But now that it is clear that adult ovaries can give birth to new oocytes, a new

  207.             explanation for female reproductive aging is needed. It is likely that the same factors that cause female

  208.             reproductive aging also cause aging of other systems and organs and tissues, and that those factors are

  209.             extrinsic to the cells themselves, as Alexis Carrel and others demonstrated long ago. This is a way of

  210.             saying that all cells are potential stem cells. The "niche" in which new cells are born in the streaming

  211.             organism, and the processes by which damaged cells are removed, are physiological issues that can be

  212.             illuminated by the idea of a morphogenetic field.

  213.         </p>

  214.         <p>

  215.             When the post-war genetic engineers took over biological research, the idea of a biophysical field was

  216.             totally abandoned, but after about 15 years, it became necessary to think of problems beyond those existing

  217.             within a single bacterium, namely, the problem of how an ovum becomes and embryo. Francis Crick, of DNA

  218.             fame, who was educated as a physicist, revived (without a meaningful historical context) the idea of a

  219.             diffusion gradient as a simple integrating factor that wouldn't be too offensive to the reductionists. But

  220.             for events far beyond the scale of the egg's internal structure, for example to explain how a nerve axon can

  221.             travel a very long distance to innervate exactly the right kind of cell, the diffusion of molecules loses

  222.             its simplicity and plausibility. (Early in the history of experimental embryology, it was observed that

  223.             electrical fields affect the direction of growth of nerve fibers.)

  224.         </p>

  225.         <p>

  226.             C. M. Child saw a gradient of metabolic activity as an essential component of the morphogenetic field. This

  227.             kind of gradient doesn't deny the existence of diffusion gradients, or other physical components of a field.

  228.             Electrical and osmotic (and electro-osmotic) events are generated by metabolism, and affect other factors,

  229.             including pH, oxidation and reduction, cell motility and cell shape, ionic selectivity and other types of

  230.             cellular selectivity and specificity. Gradients of DNA methylation exist, and affect the expression of

  231.             inherited information.

  232.         </p>

  233.         <p>

  234.             Methylation decreases the expression of particular genes, and during the differention of cells in the

  235.             development of an embryo, genes are methylated and demethylated as the cell adapts to produce the proteins

  236.             that are involved in the structure and function of a particular tissue. Methylation (which increases a

  237.             molecule's affinity for fats) is a widespread process in cells, and for example regulates cellular

  238.             excitability. It is affected by diet and a variety of stresses.

  239.         </p>

  240.         <p>

  241.             DNA methylation patterns are normally fairly stable, and can help to account for the transgenerational

  242.             transmission of acquired adaptations, and for neonatal imprinting that can last a lifetime. But with injury,

  243.             stress, and aging, the methylation patterns of differentiated tissues can be changed, contributing to the

  244.             development of tumors, or to the loss of cellular functions. Even learning can change the methylation of

  245.             specific genes. During <em>in vitro</em> culture, the enzymes of gene methylation are known to be increased,

  246.             relative to their normal activity (Wang, et al., 2005).

  247.         </p>

  248. 

  249.         <p>

  250.             The phenomenon of "gene" methylation in response to environmental and metabolic conditions may eventually

  251.             lead to the extinction of the doctrine that "cells are controlled by their genes."

  252.         </p>

  253.         <p>

  254.             During successful adaptation to stress, cells make adjustments to their metabolic systems (for example with

  255.             a holistic change of the degree of phosphorylation, which increases molecules' affinity for water), and

  256.             their metabolic processes can contribute to changes in their state of differentiation. Some changes may lead

  257.             to successful adaptation (for example by producing biogenic stimulators that stimulate cell functioning and

  258.             regeneration), others to failed adaptation. Even the decomposition of cells can release substances that

  259.             contribute to the adaptation of surrounding cells, for example when sphingosines stimulate the production of

  260.             stem cells.

  261.         </p>

  262.         <p>

  263.             DNA methylation is just one relatively stable event that occurs in relation to a metabolic field.

  264.             Modifications of histones (regulatory proteins in chromosomes, which are acetylated as well as methylated)

  265.             and structural-contractile filaments also contribute to the differentiation of cells, but the pattern of DNA

  266.             methylation seems to guide the methylation of histones and the structure of the chromosomes (Nan, et al.,

  267.             1998).

  268.         </p>

  269.         <p>

  270.             Steroids and phospholipids, neurotransmitters and endorphins, ATP, GTP, other phosphates, retinoids, NO and

  271.             CO2--many materials and processes participate in the coherence of the living state, the living substance.

  272.             Carbon dioxide, for example, by binding to lysine amino groups in the histones, will influence their

  273.             methylation. Carbon dioxide is likely to affect other amino groups in the chromosomes.

  274.         </p>

  275. 

  276.         <p>

  277.             The number and arrangement of mitochondria is an important factor in producing and maintaining the metabolic

  278.             gradients. Things that decrease mitochondrial energy production--nitric oxide, histamine, cytokines,

  279.             cortisol--increase DNA methylation. Decreased gene expression is associated with reduced respiratory energy.

  280.             It seems reasonable to guess that increased gene expression would demand increased availability of energy.

  281.         </p>

  282.         <p>

  283.             As an ovum differentiates into an organism, cells become progressively more specialized, inhibiting the

  284.             expression of many genes. Less energy is needed by stably functioning cells, than by actively adapting

  285.             cells. A.I. Zotin described the process of maturing and differentiating as a decrease of entropy, an

  286.             increase of order accompanying a decreased energy expenditure. The entropic egg develops into a less

  287.             entropic embryo with a great expenditure of energy.

  288.         </p>

  289.         <p>

  290.             The partially differentiated stem cell doesn't go through all the stages of development, but it does expend

  291.             energy intensely as it matures.

  292.         </p>

  293.         <p>

  294.             The restoration of energy is one requirement for the activation of regeneration. When a hormone such as

  295.             noradrenaline or insulin causes a stem cell to differentiate in vitro, it causes new mitochondria to form.

  296.             This is somewhat analogous to the insertion of mitochondria into the ripening oocyte, by the nurse cells

  297.             that surround it. The conditionally decreased entropy of maturation is reversed, and when sufficient

  298.             respiratory energy is available, the renewed and refreshed cell will be able to renew an appropriate degree

  299.             of differentiation.

  300.         </p>

  301.         <p>

  302.             When simple organisms, such as bacteria, fungi, or protozoa are stressed, for example by the absence of

  303.             nutrients or the presence of toxins, they slow their metabolism, and suppress the expression of genes,

  304.             increasing the methylation of DNA, to form resistant and quiescent spores. Our differentiated state doesn't

  305.             go to the metabolic extreme seen in sporulation, but it's useful to look at maturity and aging in this

  306.             context, because it suggests that the wrong kind of stress decreases the ability of the organism to adapt,

  307.             by processes resembling those in the spore-forming organisms.

  308.         </p>

  309. 

  310.         <p>

  311.             Charles Vacanti, who has grown cartilage from cells taken from 100 year old human cartilage, believes our

  312.             tissues contain "spore cells," very small cells with slow metabolism and extreme resistance to heat, cold,

  313.             and starvation.

  314.         </p>

  315.         <p>

  316.             If the slowed metabolism of aging, like that of sporulating cells, is produced by a certain kind of stress

  317.             that lowers cellular energy and functions, it might be useful to think of the other stages of the stress

  318.             reaction in relation to the production of stem cells. Selye divided stress into a first stage of shock,

  319.             followed by a prolonged adaptation, which could sometimes end in exhaustion. If the maturity of

  320.             differentiated functioning is equivalent to the adaptation phase, and cellular decline and disintegration is

  321.             the exhaustion phase, then the shock-like reaction would correspond to the birth of new stem cells.

  322.         </p>

  323.         <p>

  324.             Selye described estrogen's effects as equivalent to the shock-phase of stress. Estrogen's basic action is to

  325.             make oxygen unavailable, lowering the oxygen tension of the tissues, locally and temporarily. Like nitric

  326.             oxide, which is produced by estrogenic stimulation, estrogen interferes with energy production, so if its

  327.             stimulation is prolonged, cells are damaged or killed, rather than being stimulated to regenerate.

  328.         </p>

  329.         <p>

  330.             Extrinsic factors elicit renewal, the way stress can elicit adaptation. While aging cells can't use the

  331.             oxygen that is present, a scarcity of oxygen can serve as a stimulus to maximize the respiratory systems.

  332.             Brief oxygen deprivation excites a cell, causes it to swell, and to begin to divide.

  333.         </p>

  334. 

  335.         <p>

  336.             Oxygen deprivation, as in the normally hypoxic bone marrow, stimulates the formation of stem cells, as well

  337.             as the biogenesis of mitochondria. As the newly formed cells, with abundant mitochondria, get adequate

  338.             oxygen, they begin differentiation.

  339.         </p>

  340.         <p>

  341.             Form, based on cellular differentiation, follows function--a vein transplanted into an artery develops

  342.             anatomically into an artery, a colon attached directly to the anus becomes a new rectum with its appropriate

  343.             innervation, a broken bone restructures to form a normal bone. If the bladder is forced to function more

  344.             than normal, by artificially keeping it filled, its thin wall of smooth muscle develops into a thick wall of

  345.             striated muscle that rhythmically contracts, like the heart. If a tadpole is given a vegetarian diet, the

  346.             absorptive surface of its digestive system will develop to be twice the size of those that are fed meat.

  347.             Pressure, stretching, and pulsation are among the signals that guide cells' differentiation.

  348.         </p>

  349.         <p>

  350.             Very early in the study of embryology it was noticed that the presence of one tissue sometimes induced the

  351.             differentiation of another kind, and also that there were factors in embryonic tissues that would stimulate

  352.             cell division generally, and others that could inhibit the growth of a particular tissue type. Diffusable

  353.             substances and light were among the factors identified as growth regulators.

  354.         </p>

  355.         <p>

  356.             Extracts of particular tissues were found to suppress the multiplication of cells in that type of tissue, in

  357.             adult animals as well as in embryos. In the 1960s, the tissue-specific inhibitors were called chalones.

  358.         </p>

  359.         <p>

  360.             The brain's development is governed by the presence in the organism of the body part to which it

  361.             corresponds, such as the eyes or legs. The number of cells in a particular part of the nervous system is

  362.             governed by the quantity of nervous input, sensory or motor, that it receives. An enriched environment

  363.             causes a bigger brain to grow. Sensory nerve stimulation of a particular region of the brain causes nerve

  364.             cells to migrate to that area (a process called neurobiotaxis; deBeers, 1927), but nerve stimulation also

  365.             causes mitochondria to accumulate in stimulated areas. Nerve activity has a trophic, sustaining influence on

  366.             other organs, as well as on the brain. Nerve stimulation, like mechanical pressure or stretching, is an

  367.             important signal for cellular differentiation.

  368.         </p>

  369. 

  370.         <p>

  371.             When stem cells or progenitor cells are called on to replace cells in an organ, they are said to be

  372.             "recruited" by that organ, or to "home" to that organ, if they are coming from elsewhere. Traditionally, the

  373.             bone marrow has been considered to be the source of circulating stem cells, but it now appears that a

  374.             variety of other less differentiated cells can be recruited when needed. Cells from the blood can repair the

  375.             endothelium of blood vessels, and endothelial cells can become mesenchymal cells, in the heart, for example.

  376.         </p>

  377.         <p>

  378.             The standard doctrine about cancer is that a tumor derives from a single mutant cell, but it has been known

  379.             for a long time that different types of cell, such as phagocytes and mast cells, usually reside in tumors,

  380.             and it is now becoming clear that tumors recruit cells, including apparently normal cells, from other parts

  381.             of the same organ. For example, a brain tumor of glial cells, a glioma, recruits glial cells from

  382.             surrounding areas of the brain, in a process that's analogous to the embryological movement of nerve cells

  383.             to a center of excitation. Each tumor, in a sense, seems to be a center of excitation, and its fate seems to

  384.             depend on the nature of the cells that respond to its signals.

  385.         </p>

  386.         <p>

  387.             To accommodate some of the newer facts about tumors, the cancer establishment has begun speaking of "the

  388.             cancer stem cell" as the real villain, the origin of the tumor, while the bulk of the tumor is seen to be

  389.             made up of defective cells that have a short life-span. But if we recognize that tumors are recruiting cells

  390.             from beyond their boundaries, this process would account for the growth and survival of a tumor even while

  391.             most of its cells are inert and dying, without invoking the invisible cancer stem cell. And this view, that

  392.             it is the field which is defective rather than the cell, is consistent with the evidence which has been

  393.             accumulating for 35 years that tumor cells, given the right environment, can differentiate into healthy

  394.             cells. (Hendrix, et al., 2007)

  395.         </p>

  396. 

  397.         <p>

  398.             Simply stretching an organ (Woo, et al., 2007) is stimulus enough to cause it to recruit cells from the

  399.             bloodstream, and will probably stimulate multiplication in its local resident cells, too. Every "cancer

  400.             field" probably begins as a healing process, and generally the healing and regeneration are at least

  401.             partially successful.

  402.         </p>

  403.         <p>

  404.             When an organ--the brain, heart, liver, or a blood vessel--is inflamed or suffering from an insufficient

  405.             blood supply, stem cells introduced into the blood will migrate specifically to that organ.

  406.         </p>

  407.         <p>

  408.             Organ specific materials (chalones) are known to circulate in the blood, inhibiting cell division in cells

  409.             typical to that organ, but it also seems that organ specific materials are secreted by a damaged organ, that

  410.             help to prepare stem cells for their migration into that organ. When undifferentiated cells are cultured

  411.             with serum from a person with liver failure, they begin to differentiate into liver cells.

  412.         </p>

  413.         <p>

  414.             It is still common to speak of each organ as having a "clonal origin" in the differentiating embryo, as a

  415.             simple expansion of a certain embryonic anlage. The implication of this way of thinking is that

  416.             differentiation is <em>determination</em> in an irreversible sense. This is another case of medical ideas

  417.             being based on images of fixed histological material. Normal cells, including nerve and muscle cells, can

  418.             change type, with connective tissue cells becoming nerve cells, nerve cells becoming muscle and fiber cells,

  419.             fat, fiber, and muscle cells redifferentiating, for example.

  420.         </p>

  421. 

  422.         <p>

  423.             Cell movements in solid tissues aren't limited to the short distances between capillaries and the tissues

  424.             nourished by those capillaries, rather, cells can migrate much greater distances, without entering the

  425.             bloodstream. The speed of a single cell moving by ameboid motion can be measured by watching cells on a

  426.             glass slide as they move toward food, or by watching cells of the slime mold Dictyostelium when they are

  427.             aggregating, or by watching the pigment cells in and around moles or melanomas, under the influence of

  428.             hormones. At body temperature, a single cell can crawl about an inch per day. Waves or spots of brown

  429.             pigment can be seen migrating through the skin away from a mole, preceding the disintegration of the mole

  430.             under the influence of progesterone or DHEA. Under ordinary conditions, pigment cells can sometimes be seen

  431.             migrating into depigmented areas of skin, during the recovery of an area affected by vitiligo. These

  432.             organized movements of masses of cells happen to be easy to see, but there is evidence that other types of

  433.             cell can reconstruct tissues by their ameboid movements, when circumstances are right. Tumors or tissue

  434.             abnormalities can appear or disappear with a suddenness that seems impossible to people who have studied

  435.             only fixed tissue preparations.

  436.         </p>

  437.         <p>

  438.             Stimulation is anabolic, building tissue, when the organism is adapting to the stimulation. Unused

  439.             structures in cells and tissues are always being recycled by metabolic processes. When tissues are injured

  440.             and become unable to function, some of their substances stimulate the growth of replacement cells.

  441.         </p>

  442.         <p>

  443.             Some types of injury or irritation can activate regenerative processes. A dermatology journal described the

  444.             case of an old man who had been bald for many years who fell head-first into his fireplace. As his burned

  445.             scalp healed, new hair grew. In the U.S., experimenters (Ito, et al., 2007) have found that injuring the

  446.             skin of mice stimulates the formation of stem cells that are able to become hair follicle cells, supporting

  447.             the regeneration of cells that had been absent. A brief exposure to estrogen, and other stress related

  448.             signals (nitric oxide, endorphin, prostaglandins) can initiate stem cell proliferation.

  449.         </p>

  450.         <p>

  451.             In the years after the first world war, Vladimir Filatov, who developed techniques of reconstructive

  452.             surgery, including corneal transplants, found that cold storage of tissues (for example, corneas from

  453.             cadavers) caused them to function better than fresh tissues, and he found that these stressed tissues would

  454.             often spread a healing influence out into the surrounding tissues. Extracts of stressed tissues produced

  455.             similar effects.

  456.         </p>

  457.         <p>

  458.             L.V. Polezhaev began studying the regenerative capacities of mammals in the late 1940s, and his work showed

  459.             that processes similar to embryonic induction are involved in the organism's responses to damaged tissues.

  460.             For example, when a piece of killed muscle tissue is enclosed in a capsule ("diffusion chamber") that

  461.             permits molecules, but no cells, to diffuse through it, and implanted subcutaneously, it had no inductive

  462.             effect on surrounding cells. But when the pores of the capsule allowed cells to enter, skeletal muscle

  463.             formed where the dead tissue had been, and tissue resembling heart muscle formed outside the capsule.

  464.             Phagocytosis had been essential for the induction to occur.

  465.         </p>

  466. 

  467.         <p>

  468.             Macrophages are ordinarily thought of as "antigen-presenting cells" that help to activate the specific

  469.             immune responses. But apparently phagocytosis is involved in the replacement of damaged tissues, by

  470.             recruiting or inducing the differentiation of replacement cells. The phagocytosis function isn't limited to

  471.             the blood cells commonly called phagocytes; even nerve cells can ingest particles and fragments of damaged

  472.             tissues.

  473.         </p>

  474.         <p>

  475.             Many factors regulate the process of phagocytosis. Stress and lipid peroxidation decrease phagocytosis

  476.             (Izg"t-Uysal, et al., 2004), and also damage mitochondria and inhibit cell renewal.

  477.         </p>

  478.         <p>

  479.             Unsaturated fatty acids inhibit phagocytosis (Guimaraes, et al., 1991, 1992; Costa Rosa, et al., 1996;

  480.             Virella, et al., 1989; Akamatsu, et al., 1990), and suppress mitochondrial function (Gomes, et al., 2006).

  481.             Dietary restriction activates phagocytosis (Moriguchi, et al., 1989), suggesting that normal diets contain

  482.             suppressive materials.

  483.         </p>

  484.         <p>

  485.             Subnormal temperatures cause a shift from phagocytosis to inflammation. Light, especially the red light

  486.             which penetrates easily into tissues, activates the formation of new cells as well as their differentiation.

  487.             It affects energy production, increasing the formation of mitochondria, and the activity of the DNA

  488.             methyltransferase enzymes. Red light accelerates wound healing, and improves the quality of the scar,

  489.             reducing the amount of fibrosis. The daily cycling between darkness and light is probably an important

  490.             factor in regulating the birth and differentiation of cells.

  491.         </p>

  492.         <p>

  493.             Darkness suppresses mitochondrial function, and light activates it. Prolonged darkness increases cortisol,

  494.             and cortisol (which makes cells more susceptible to excitotoxic death) inhibits stem cell proliferation (Li,

  495.             et al., 2006; Liu, et al., 2003). Neurogenesis is suppressed by stress, and increased by spontaneous

  496.             activity, and has a circadian rhythm. Aging and depression both involve a diminished ability to rhythmically

  497.             lower the production of cortisol. Cell renewal requires a rhythmic decrease in the exposure to cortisol..

  498.         </p>

  499. 

  500.         <p>

  501.             In the spring, with increased day length, the brains of song-birds grow, with an increased proliferation of

  502.             cells in the part of the brain involved in singing. The production of progesterone increases in most animals

  503.             in the spring, and it is the main hormone responsible for the birds' brain growth.

  504.         </p>

  505.         <p>

  506.             Progesterone and its metabolites protect brain cells against injury, and improve the brain's ability to

  507.             recover after traumatic injury (Brinton and Wang, 2006). In the 1960s, Marion Diamond's group showed that

  508.             environmental enrichment, or progesterone, caused brains to grow larger, and that these changes were passed

  509.             on to descendants in a cumulative, increasing way. This suggests that the factors that promote neurogenesis

  510.             also cause changes in the apparatus of reproduction and inheritance, that support the development of the

  511.             brain--probably including the methylation system, which is involved in regulating genes, and also mood and

  512.             behavior.

  513.         </p>

  514.         <p>

  515.             Women's monthly cycles, in which a brief estrogen dominance is followed by sustained exposure to

  516.             progesterone, are probably an important factor in the renewal of the cells of the brain and other organs, as

  517.             well as those of the reproductive organs. The daily rhythms of hormones and metabolism are known to be

  518.             involved in the regulation of cell renewal.

  519.         </p>

  520.         <p>

  521.             Environmental enrichment, learning, high altitude, and thyroid hormone promote the formation of new

  522.             mitochondria, and stimulate stem cell proliferation. At least in some laboratories, 20% oxygen,

  523.             approximately the amount as in the atmosphere, suppresses the proliferation of stem cells (He, et al.,

  524.             2007). This was the unphysiologically high concentration of oxygen used in Hayflick's cell cultures. At high

  525.             altitudes, where tissues are exposed to less oxygen, and more carbon dioxide, there is a lower incidence of

  526.             all the degenerative diseases, including cancer, heart disease, and dementia. Improved cellular energy

  527.             production and more active renewal of cells would probably account for those differences.

  528.         </p>

  529. 

  530.         <p>

  531.             For Crick, the idea of a diffusion gradient to explain embryonic development was simply an extension of his

  532.             reductionist orientation, in which diffusing molecules induced or inhibited bacterial genes, and in which

  533.             genes controlled cells. For people with that orientation, the adaptive mutations described by Carl

  534.             Lindegren, and later by John Cairns, or even the stress-induced variability described by Lysenko, Strong,

  535.             and McClintock, were heretical. Polezhaev's demonstration that cells could do something that molecular

  536.             diffusion didn't do, threatened to take biology away from the reductionists. If the organism's adaptation to

  537.             the environment involves changing its own genes, Crick's paradigm fails.

  538.         </p>

  539.         <p>

  540.             Crick's Central Dogma, derived from the ideology that produced Weismann's Barrier, has been invoked by

  541.             generations of professors who wanted to deny the possibility of adaptive tissue renewal and regeneration.

  542.             Without the dogma, new ideas about aging and disease will be needed. If somatic cells can adjust their

  543.             genes, and if they can also differentiate into new eggs and sperms, new ideas about inheritance of acquired

  544.             traits will be needed.

  545.         </p>

  546.         <p>

  547.             The replacement of injured cells means that mutations need not accumulate. Cell renewal with elimination of

  548.             mutant cells has been observed in sun-damaged skin simply by stopping the damage, and mitochondria with

  549.             damaged DNA can be replaced by healthy mitochondria simply by doing the right kind of exercise.

  550.         </p>

  551.         <p>

  552.             The regulation of cell renewal probably involves all of the processes of life, but there are a few simple,

  553.             interacting factors that suppress renewal. The accumulation of polyunsaturated fats, interacting with a high

  554.             concentration of oxygen, damages mitochondria, and causes a chronic excessive exposure to cortisol. With

  555.             mitochondrial damage, cells are unable to produce the progesterone needed to oppose cortisol and to protect

  556.             cells.

  557.         </p>

  558. 

  559.         <p>

  560.             Choosing the right foods, the right atmosphere, the right mental and physical activities, and finding the

  561.             optimal rhythms of light, darkness, and activity, can begin to alter the streaming renewal of cells in all

  562.             the organs. Designing a more perfect environment is going to be much simpler than the schemes of the genetic

  563.             engineers.

  564.         </p>

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  812.         <h1>

  813.             <strong>Stem cells, cell culture, and culture: Issues in regeneration

  814.             </strong>

  815.         </h1>

  816.         <p>

  817.             Cell renewal is a factor in all aspects of health and disease, not just in aging and the degenerative

  818.             diseases. Many people are doing valid research relating to cell renewal and regeneration, but its usefulness

  819.             is seriously limited by cultural and commercial constraints. By recovering some of our suppressed

  820.             traditional culture, I think regenerative therapies can be developed quickly, by identifying and eliminating

  821.             as far as possible the main factors that interfere with tissue renewal.

  822.         </p>

  823. 

  824.         <p>

  825.             Science grew up in the highly authoritarian cultures of western Europe, and even as it contributed to

  826.             cultural change, it kept an authoritarian mystique. Any culture functions as a system of definitions of

  827.             reality and the limits of possibility, and to a great extent the "laws of nature" are decreed so that they

  828.             will harmonize with the recognized laws of society.

  829.         </p>

  830.         <p>

  831.             The practical success of Newton's "laws" of motion when they were applied to ballistics and "rocket science"

  832.             has led many people to value calculation, based on those laws, over evidence. In biology, the idea that an

  833.             organism is "the information it contains in its DNA blueprint" is an extention of this. The organism is

  834.             turned into something like a deductive expression of the law of DNA. This attitude has been disastrous.

  835.         </p>

  836. 

  837.         <p>

  838.             The old feudal idea of a divine and stable social organization was applied by some people to their idea of

  839.             biological organization, in which each cell (ruled by its nucleus) had its ordained place in the organism,

  840.             with the brain and the "master gland," the pituitary, ruling the subordinate organs, tissues, and cells.

  841.             "Anatomy" was taught from dead specimens, microscope slides, and illustrations in books. Most biologists'

  842.             thoughts about cells in organisms reflect the static imagery of their instruction. (<em>"The histological

  843.                 image of these tissues actually reflects an instantaneous picture of cells in a continuous flux."</em>

  844.             Zajicek, 1981.)

  845.         </p>

  846.         <p>

  847.             When a person has playful and observant interactions with natural things, both regularities and

  848.             irregularities will be noticed, and in trying to understand those events, the richness of the experience

  849.             will suggest an expansive range of possibilities. Perception and experimentation lead to understandings that

  850.             are independent of culture and tradition.

  851.         </p>

  852. 

  853.         <p>

  854.             But the mystique of science easily imposes itself, and distracts our attention from direct interactions with

  855.             things. As we learn to operate lab instruments, we are taught the kinds of results that can be expected, and

  856.             the concepts that will explain and predict the results of our operations. Science, as we learn about it in

  857.             schools and the mass media, is mostly a set of catechisms.

  858.         </p>

  859.         <p>

  860.             Our theories about organisms inform our experiments with cells or tissues that have been isolated from those

  861.             organisms. The conditions for growing cells in dishes are thought of as "physiological," in relation to the

  862.             solution's "physiological osmolarity," "physiological pH," nutrients, oxygenation, temperature, pressure,

  863.             etc. But these concepts of what is physiological derive from the monolithic ideology of the doctrinaire, and

  864.             often fraudulent, mainstream of biological science.

  865.         </p>

  866.         <p>

  867.             The catechismic nature of science has led people to expect some "break-throughs" to occur in certain areas,

  868.             and as authoritarian science has grown into "big science" managed by corporations and governments, those

  869.             break-throughs are generally expected to be produced by the newest and most expensive developments of "high

  870.             technology."

  871.         </p>

  872.         <p>

  873.             But looking closely at the real events and processes in the sciences in the last couple of centuries, it

  874.             turns out that useful advances have been produced mainly by breaking away from authoritarian doctrines, to

  875.             return to common sense and relatively simple direct observations.

  876.         </p>

  877.         <p>

  878.             Although people were cloning animals in the 1960s, it was still widely taught that it was impossible. The

  879.             students of the professors who taught that it was impossible are now saying that it requires high technology

  880.             and new research.

  881.         </p>

  882.         <p>

  883.             For the last 100 years the most authoritative view in biology has been that there are no stem cells in

  884.             adults, that brains, hearts, pancreases and oocytes are absolutely incapable of regeneration. But now,

  885.             people seem to be finding stem cells wherever they look, but there is a mystique of high technology involved

  886.             in finding and using them.

  887.         </p>

  888.         <p>

  889.             Whether it's deliberate or not, the emphasis on stem cell technology has the function of directing attention

  890.             away from traditional knowledge, the way allopathic medicine has de-emphasized the intrinsic ability of

  891.             people to recover from disease.

  892.         </p>

  893. 

  894.         <p>

  895.             This resembles the way that the Mendel-Morgan gene doctrine was used to suppress the knowledge gained from

  896.             centuries of experience of plant and animal breeders, and to belittle the discoveries of Luther Burbank,

  897.             Paul Kammerer, Trofim Lysenko, and Barbara McClintock. The same type of biochemical process that caused the

  898.             hereditary changes those researchers studied are involved in the differentiation and dedifferentiation of

  899.             stem cells that regulate healing and regeneration.

  900.         </p>

  901.         <p>

  902.             In the 1940s, even children discussed the biological discoveries of the 1920s and 1930s, the work in

  903.             regeneration and adaptation, parthenogenesis, and immortalization. The ideas of J. Loeb, T. Boveri, A.

  904.             Gurwitsch, J. Needham, C.M. Child, A. Carrel, et al., had become part of the general culture.

  905.         </p>

  906.         <p>

  907.             But that real biology was killed by a consortium of industry and government that began a little before the

  908.             second world war. In 1940, the government was supporting research in chemical and biological warfare, and

  909.             with the Manhattan Project the role of government became so large that all of the major research

  910.             universities were affected. Shortly after the war, many researchers from the Manhattan Project were

  911.             redeployed into "molecular genetics," where the engineering attitude was applied to organisms.

  912.         </p>

  913.         <p>

  914.             The simplistic genetic dogmas were compatible with the reductionist engineering approach to the organism.

  915.             The role of the government assured that the universities would subscribe to the basic scientific agenda. The

  916.             atmosphere of that time was described by Carl Lindegren as "The Cold War in Biology" (1966).

  917.         </p>

  918. 

  919.         <p>

  920.             The disappearance of the field concept in developmental biology was one of the strangest events in the

  921.             history of science. It didn't just fade away, it was "disappeared," in a massive undertaking of social

  922.             engineering. In its absence, stem cells will seem to be a profitable technological marvel, rather than a

  923.             universal life function, with a central role in everything we are and everything we do and can become.

  924.         </p>

  925.         <p>

  926.             Many people have tried to explain aging as a loss of cells, resulting from an intrinsic inability of any

  927.             cell other than a germ cell to multiply more than a certain number of times. More than 40 years ago Leonard

  928.             Hayflick popularized this doctrine in its most extreme form, saying that no cell can divide more than 50

  929.             times unless it is converted into a cancer cell. He and his followers claimed that they had explained why

  930.             organisms must age and die. At the moment the ovum is fertilized, the clock starts ticking for the

  931.             essentially mortal somatic cells.

  932.         </p>

  933.         <p>

  934.             In 1970, it was being seriously proposed that memory was produced by the death of brain cells, in a manner

  935.             analogous to the holes punched in cards to enter data into computers. The cultural dogma made it impossible

  936.             to consider that learning could be associated with the birth of new cells in the adult brain.

  937.         </p>

  938.         <p>

  939.             With the announcement in 1997 of the cloning of the sheep Dolly from a somatic cell taken from a 6 year old

  940.             sheep, there was renewed interest in the idea made famous by Alexis Carrel that all cells are potentially

  941.             immortal, and in the possibility of preserving the vitality of human cells. Within a few months, Hayflick

  942.             began reminding the public that "In the early 1960's we overthrew this dogma after finding that normal cells

  943.             do have a finite replicative capacity." ("During the first half of this century it was believed that because

  944.             cultured normal cells were immortal, aging must be caused by extra-cellular events.") The way Hayflick

  945.             "overthrew" more than 35 years of work at the Rockefeller Institute was by growing one type of cell, a lung

  946.             fibroblast, in culture dishes, and finding that the cultures deteriorated quickly.

  947.         </p>

  948. 

  949.         <p>

  950.             To draw global conclusions about an organism's development and aging from the degenerative processes seen in

  951.             a single type of cell, grown in isolation from all normal stimuli, would have been treated as nothing but

  952.             wild speculation, except that it occurred within a culture that needed it. No aspect of Hayflick's cell

  953.             culture system could properly be called physiological.

  954.         </p>

  955.         <p>

  956.             Other researchers, simply by changing a single factor, caused great increases in the longevity of the

  957.             cultured cells. Simply using a lower, more natural oxygen concentration, the cells were able to undergo 20

  958.             more divisions. Just by adding niacin, 30 more divisions; vitamin E, 70 more divisions. Excess oxygen is a

  959.             poison requiring constant adaptation.

  960.         </p>

  961.         <p>

  962.             Hayflick also published the observation that, while the cells kept in dishes at approximately body

  963.             temperature deteriorated, cells kept frozen in liquid nitrogen didn't deteriorate, and he concluded that

  964.             "time" wasn't the cause of aging. When I read his comments about the frozen cells, I wondered how anyone of

  965.             normal intelligence could make such stupid statements. Since then, facts that came out because of the

  966.             Freedom of Information Act, cause me to believe that a financial motive guided his thoughts about his

  967.             cultured fibroblasts.

  968.         </p>

  969.         <p>

  970.             Hayflick and his followers have been attacking the idea of anti-aging medicine as quackery. But he is

  971.             closely involved with the Geron corporation, which proposes that genetic alterations relating to telomeres

  972.             may be able to cure cancer and prevent aging. Their claims were reported by CNN as "Scientists discover

  973.             cellular 'fountain of youth'."

  974.         </p>

  975. 

  976.         <p>

  977.             The "wear and tear" doctrine of aging that derived from the ideology of the gene was reinforced and renewed

  978.             by Hayflick's cell culture observations, and it continued to rule the universities and popular culture.

  979.         </p>

  980.         <p>

  981.             But detailed investigation of skin cell growth showed that cells in the lower layer of the skin divide at

  982.             least 10,000 times in a normal lifetime, and similar processes occur in the lining of the intestine. The

  983.             endometrium and other highly renewable tissues just as obviously violated Hayflick's limit. Transplantation

  984.             experiments showed that pieces of mammary tissue or skin tissue could survive through ten normal lifetimes

  985.             of experimental animals without suffering the effects of aging.

  986.         </p>

  987.         <p>

  988.             Even the liver and adrenal gland are now known to be continuously renewed by "cell streaming," though at a

  989.             slower rate than the skin, conjunctiva, and intestine. Neurogenesis in the brain is now not only widely

  990.             accepted, it is even proposed as a mechanism to explain the therapeutic effects of antidepressants

  991.             (Santarelli, et al., 2003).

  992.         </p>

  993. 

  994.         <p>

  995.             August Weismann's most influential doctrine said that "somatic cells are mortal, only the germline cells are

  996.             immortal," but he based the doctrine on his mistaken belief that only the "germline" cells contained all the

  997.             genes of the organism. In 1885, to "refute" Darwin's belief that acquired traits could be inherited, he

  998.             promulgated an absolute "barrier" between "germline" and "soma," and invented facts to show that hereditary

  999.             information can flow only from the germline to the somatic cells, and not the other direction. Shortly after

  1000.             DNA became popular in the 1950s as "the genetic material," Weismann's barrier was restated as the Central

  1001.             Dogma of molecular genetics, that information flows only from DNA to RNA to protein, and never the other

  1002.             direction.

  1003.         </p>

  1004.         <p>

  1005.             It was only in 2003, after the reality of cloning was widely recognized, that a few experimenters began to

  1006.             investigate the origin of "germline" cells in the ovary, and to discover that they derive from somatic cells

  1007.             (Johnson, et al., 2004). With this discovery, the ancient knowledge that a twig (<em>klon</em>, in Greek)

  1008.             cut from a tree could grow into a whole tree, bearing fruit and viable seeds, was readmitted to general

  1009.             biology, and the Weismann barrier was seen to be an illusion.

  1010.         </p>

  1011.         <p>

  1012.             Millions of people have "explained" female reproductive aging as the consequence of the ovary "running out

  1013.             of eggs." Innumerable publications purported to show the exact ways in which that process occurs, following

  1014.             the Weismann doctrine. But now that it is clear that adult ovaries can give birth to new oocytes, a new

  1015.             explanation for female reproductive aging is needed. It is likely that the same factors that cause female

  1016.             reproductive aging also cause aging of other systems and organs and tissues, and that those factors are

  1017.             extrinsic to the cells themselves, as Alexis Carrel and others demonstrated long ago. This is a way of

  1018.             saying that all cells are potential stem cells. The "niche" in which new cells are born in the streaming

  1019.             organism, and the processes by which damaged cells are removed, are physiological issues that can be

  1020.             illuminated by the idea of a morphogenetic field.

  1021.         </p>

  1022.         <p>

  1023.             When the post-war genetic engineers took over biological research, the idea of a biophysical field was

  1024.             totally abandoned, but after about 15 years, it became necessary to think of problems beyond those existing

  1025.             within a single bacterium, namely, the problem of how an ovum becomes and embryo. Francis Crick, of DNA

  1026.             fame, who was educated as a physicist, revived (without a meaningful historical context) the idea of a

  1027.             diffusion gradient as a simple integrating factor that wouldn't be too offensive to the reductionists. But

  1028.             for events far beyond the scale of the egg's internal structure, for example to explain how a nerve axon can

  1029.             travel a very long distance to innervate exactly the right kind of cell, the diffusion of molecules loses

  1030.             its simplicity and plausibility. (Early in the history of experimental embryology, it was observed that

  1031.             electrical fields affect the direction of growth of nerve fibers.)

  1032.         </p>

  1033.         <p>

  1034.             C. M. Child saw a gradient of metabolic activity as an essential component of the morphogenetic field. This

  1035.             kind of gradient doesn't deny the existence of diffusion gradients, or other physical components of a field.

  1036.             Electrical and osmotic (and electro-osmotic) events are generated by metabolism, and affect other factors,

  1037.             including pH, oxidation and reduction, cell motility and cell shape, ionic selectivity and other types of

  1038.             cellular selectivity and specificity. Gradients of DNA methylation exist, and affect the expression of

  1039.             inherited information.

  1040.         </p>

  1041.         <p>

  1042.             Methylation decreases the expression of particular genes, and during the differention of cells in the

  1043.             development of an embryo, genes are methylated and demethylated as the cell adapts to produce the proteins

  1044.             that are involved in the structure and function of a particular tissue. Methylation (which increases a

  1045.             molecule's affinity for fats) is a widespread process in cells, and for example regulates cellular

  1046.             excitability. It is affected by diet and a variety of stresses.

  1047.         </p>

  1048.         <p>

  1049.             DNA methylation patterns are normally fairly stable, and can help to account for the transgenerational

  1050.             transmission of acquired adaptations, and for neonatal imprinting that can last a lifetime. But with injury,

  1051.             stress, and aging, the methylation patterns of differentiated tissues can be changed, contributing to the

  1052.             development of tumors, or to the loss of cellular functions. Even learning can change the methylation of

  1053.             specific genes. During <em>in vitro</em> culture, the enzymes of gene methylation are known to be increased,

  1054.             relative to their normal activity (Wang, et al., 2005).

  1055.         </p>

  1056. 

  1057.         <p>

  1058.             The phenomenon of "gene" methylation in response to environmental and metabolic conditions may eventually

  1059.             lead to the extinction of the doctrine that "cells are controlled by their genes."

  1060.         </p>

  1061.         <p>

  1062.             During successful adaptation to stress, cells make adjustments to their metabolic systems (for example with

  1063.             a holistic change of the degree of phosphorylation, which increases molecules' affinity for water), and

  1064.             their metabolic processes can contribute to changes in their state of differentiation. Some changes may lead

  1065.             to successful adaptation (for example by producing biogenic stimulators that stimulate cell functioning and

  1066.             regeneration), others to failed adaptation. Even the decomposition of cells can release substances that

  1067.             contribute to the adaptation of surrounding cells, for example when sphingosines stimulate the production of

  1068.             stem cells.

  1069.         </p>

  1070.         <p>

  1071.             DNA methylation is just one relatively stable event that occurs in relation to a metabolic field.

  1072.             Modifications of histones (regulatory proteins in chromosomes, which are acetylated as well as methylated)

  1073.             and structural-contractile filaments also contribute to the differentiation of cells, but the pattern of DNA

  1074.             methylation seems to guide the methylation of histones and the structure of the chromosomes (Nan, et al.,

  1075.             1998).

  1076.         </p>

  1077.         <p>

  1078.             Steroids and phospholipids, neurotransmitters and endorphins, ATP, GTP, other phosphates, retinoids, NO and

  1079.             CO2--many materials and processes participate in the coherence of the living state, the living substance.

  1080.             Carbon dioxide, for example, by binding to lysine amino groups in the histones, will influence their

  1081.             methylation. Carbon dioxide is likely to affect other amino groups in the chromosomes.

  1082.         </p>

  1083. 

  1084.         <p>

  1085.             The number and arrangement of mitochondria is an important factor in producing and maintaining the metabolic

  1086.             gradients. Things that decrease mitochondrial energy production--nitric oxide, histamine, cytokines,

  1087.             cortisol--increase DNA methylation. Decreased gene expression is associated with reduced respiratory energy.

  1088.             It seems reasonable to guess that increased gene expression would demand increased availability of energy.

  1089.         </p>

  1090.         <p>

  1091.             As an ovum differentiates into an organism, cells become progressively more specialized, inhibiting the

  1092.             expression of many genes. Less energy is needed by stably functioning cells, than by actively adapting

  1093.             cells. A.I. Zotin described the process of maturing and differentiating as a decrease of entropy, an

  1094.             increase of order accompanying a decreased energy expenditure. The entropic egg develops into a less

  1095.             entropic embryo with a great expenditure of energy.

  1096.         </p>

  1097.         <p>

  1098.             The partially differentiated stem cell doesn't go through all the stages of development, but it does expend

  1099.             energy intensely as it matures.

  1100.         </p>

  1101.         <p>

  1102.             The restoration of energy is one requirement for the activation of regeneration. When a hormone such as

  1103.             noradrenaline or insulin causes a stem cell to differentiate in vitro, it causes new mitochondria to form.

  1104.             This is somewhat analogous to the insertion of mitochondria into the ripening oocyte, by the nurse cells

  1105.             that surround it. The conditionally decreased entropy of maturation is reversed, and when sufficient

  1106.             respiratory energy is available, the renewed and refreshed cell will be able to renew an appropriate degree

  1107.             of differentiation.

  1108.         </p>

  1109.         <p>

  1110.             When simple organisms, such as bacteria, fungi, or protozoa are stressed, for example by the absence of

  1111.             nutrients or the presence of toxins, they slow their metabolism, and suppress the expression of genes,

  1112.             increasing the methylation of DNA, to form resistant and quiescent spores. Our differentiated state doesn't

  1113.             go to the metabolic extreme seen in sporulation, but it's useful to look at maturity and aging in this

  1114.             context, because it suggests that the wrong kind of stress decreases the ability of the organism to adapt,

  1115.             by processes resembling those in the spore-forming organisms.

  1116.         </p>

  1117. 

  1118.         <p>

  1119.             Charles Vacanti, who has grown cartilage from cells taken from 100 year old human cartilage, believes our

  1120.             tissues contain "spore cells," very small cells with slow metabolism and extreme resistance to heat, cold,

  1121.             and starvation.

  1122.         </p>

  1123.         <p>

  1124.             If the slowed metabolism of aging, like that of sporulating cells, is produced by a certain kind of stress

  1125.             that lowers cellular energy and functions, it might be useful to think of the other stages of the stress

  1126.             reaction in relation to the production of stem cells. Selye divided stress into a first stage of shock,

  1127.             followed by a prolonged adaptation, which could sometimes end in exhaustion. If the maturity of

  1128.             differentiated functioning is equivalent to the adaptation phase, and cellular decline and disintegration is

  1129.             the exhaustion phase, then the shock-like reaction would correspond to the birth of new stem cells.

  1130.         </p>

  1131.         <p>

  1132.             Selye described estrogen's effects as equivalent to the shock-phase of stress. Estrogen's basic action is to

  1133.             make oxygen unavailable, lowering the oxygen tension of the tissues, locally and temporarily. Like nitric

  1134.             oxide, which is produced by estrogenic stimulation, estrogen interferes with energy production, so if its

  1135.             stimulation is prolonged, cells are damaged or killed, rather than being stimulated to regenerate.

  1136.         </p>

  1137.         <p>

  1138.             Extrinsic factors elicit renewal, the way stress can elicit adaptation. While aging cells can't use the

  1139.             oxygen that is present, a scarcity of oxygen can serve as a stimulus to maximize the respiratory systems.

  1140.             Brief oxygen deprivation excites a cell, causes it to swell, and to begin to divide.

  1141.         </p>

  1142. 

  1143.         <p>

  1144.             Oxygen deprivation, as in the normally hypoxic bone marrow, stimulates the formation of stem cells, as well

  1145.             as the biogenesis of mitochondria. As the newly formed cells, with abundant mitochondria, get adequate

  1146.             oxygen, they begin differentiation.

  1147.         </p>

  1148.         <p>

  1149.             Form, based on cellular differentiation, follows function--a vein transplanted into an artery develops

  1150.             anatomically into an artery, a colon attached directly to the anus becomes a new rectum with its appropriate

  1151.             innervation, a broken bone restructures to form a normal bone. If the bladder is forced to function more

  1152.             than normal, by artificially keeping it filled, its thin wall of smooth muscle develops into a thick wall of

  1153.             striated muscle that rhythmically contracts, like the heart. If a tadpole is given a vegetarian diet, the

  1154.             absorptive surface of its digestive system will develop to be twice the size of those that are fed meat.

  1155.             Pressure, stretching, and pulsation are among the signals that guide cells' differentiation.

  1156.         </p>

  1157.         <p>

  1158.             Very early in the study of embryology it was noticed that the presence of one tissue sometimes induced the

  1159.             differentiation of another kind, and also that there were factors in embryonic tissues that would stimulate

  1160.             cell division generally, and others that could inhibit the growth of a particular tissue type. Diffusable

  1161.             substances and light were among the factors identified as growth regulators.

  1162.         </p>

  1163.         <p>

  1164.             Extracts of particular tissues were found to suppress the multiplication of cells in that type of tissue, in

  1165.             adult animals as well as in embryos. In the 1960s, the tissue-specific inhibitors were called chalones.

  1166.         </p>

  1167.         <p>

  1168.             The brain's development is governed by the presence in the organism of the body part to which it

  1169.             corresponds, such as the eyes or legs. The number of cells in a particular part of the nervous system is

  1170.             governed by the quantity of nervous input, sensory or motor, that it receives. An enriched environment

  1171.             causes a bigger brain to grow. Sensory nerve stimulation of a particular region of the brain causes nerve

  1172.             cells to migrate to that area (a process called neurobiotaxis; deBeers, 1927), but nerve stimulation also

  1173.             causes mitochondria to accumulate in stimulated areas. Nerve activity has a trophic, sustaining influence on

  1174.             other organs, as well as on the brain. Nerve stimulation, like mechanical pressure or stretching, is an

  1175.             important signal for cellular differentiation.

  1176.         </p>

  1177. 

  1178.         <p>

  1179.             When stem cells or progenitor cells are called on to replace cells in an organ, they are said to be

  1180.             "recruited" by that organ, or to "home" to that organ, if they are coming from elsewhere. Traditionally, the

  1181.             bone marrow has been considered to be the source of circulating stem cells, but it now appears that a

  1182.             variety of other less differentiated cells can be recruited when needed. Cells from the blood can repair the

  1183.             endothelium of blood vessels, and endothelial cells can become mesenchymal cells, in the heart, for example.

  1184.         </p>

  1185.         <p>

  1186.             The standard doctrine about cancer is that a tumor derives from a single mutant cell, but it has been known

  1187.             for a long time that different types of cell, such as phagocytes and mast cells, usually reside in tumors,

  1188.             and it is now becoming clear that tumors recruit cells, including apparently normal cells, from other parts

  1189.             of the same organ. For example, a brain tumor of glial cells, a glioma, recruits glial cells from

  1190.             surrounding areas of the brain, in a process that's analogous to the embryological movement of nerve cells

  1191.             to a center of excitation. Each tumor, in a sense, seems to be a center of excitation, and its fate seems to

  1192.             depend on the nature of the cells that respond to its signals.

  1193.         </p>

  1194.         <p>

  1195.             To accommodate some of the newer facts about tumors, the cancer establishment has begun speaking of "the

  1196.             cancer stem cell" as the real villain, the origin of the tumor, while the bulk of the tumor is seen to be

  1197.             made up of defective cells that have a short life-span. But if we recognize that tumors are recruiting cells

  1198.             from beyond their boundaries, this process would account for the growth and survival of a tumor even while

  1199.             most of its cells are inert and dying, without invoking the invisible cancer stem cell. And this view, that

  1200.             it is the field which is defective rather than the cell, is consistent with the evidence which has been

  1201.             accumulating for 35 years that tumor cells, given the right environment, can differentiate into healthy

  1202.             cells. (Hendrix, et al., 2007)

  1203.         </p>

  1204. 

  1205.         <p>

  1206.             Simply stretching an organ (Woo, et al., 2007) is stimulus enough to cause it to recruit cells from the

  1207.             bloodstream, and will probably stimulate multiplication in its local resident cells, too. Every "cancer

  1208.             field" probably begins as a healing process, and generally the healing and regeneration are at least

  1209.             partially successful.

  1210.         </p>

  1211.         <p>

  1212.             When an organ--the brain, heart, liver, or a blood vessel--is inflamed or suffering from an insufficient

  1213.             blood supply, stem cells introduced into the blood will migrate specifically to that organ.

  1214.         </p>

  1215.         <p>

  1216.             Organ specific materials (chalones) are known to circulate in the blood, inhibiting cell division in cells

  1217.             typical to that organ, but it also seems that organ specific materials are secreted by a damaged organ, that

  1218.             help to prepare stem cells for their migration into that organ. When undifferentiated cells are cultured

  1219.             with serum from a person with liver failure, they begin to differentiate into liver cells.

  1220.         </p>

  1221.         <p>

  1222.             It is still common to speak of each organ as having a "clonal origin" in the differentiating embryo, as a

  1223.             simple expansion of a certain embryonic anlage. The implication of this way of thinking is that

  1224.             differentiation is <em>determination</em> in an irreversible sense. This is another case of medical ideas

  1225.             being based on images of fixed histological material. Normal cells, including nerve and muscle cells, can

  1226.             change type, with connective tissue cells becoming nerve cells, nerve cells becoming muscle and fiber cells,

  1227.             fat, fiber, and muscle cells redifferentiating, for example.

  1228.         </p>

  1229. 

  1230.         <p>

  1231.             Cell movements in solid tissues aren't limited to the short distances between capillaries and the tissues

  1232.             nourished by those capillaries, rather, cells can migrate much greater distances, without entering the

  1233.             bloodstream. The speed of a single cell moving by ameboid motion can be measured by watching cells on a

  1234.             glass slide as they move toward food, or by watching cells of the slime mold Dictyostelium when they are

  1235.             aggregating, or by watching the pigment cells in and around moles or melanomas, under the influence of

  1236.             hormones. At body temperature, a single cell can crawl about an inch per day. Waves or spots of brown

  1237.             pigment can be seen migrating through the skin away from a mole, preceding the disintegration of the mole

  1238.             under the influence of progesterone or DHEA. Under ordinary conditions, pigment cells can sometimes be seen

  1239.             migrating into depigmented areas of skin, during the recovery of an area affected by vitiligo. These

  1240.             organized movements of masses of cells happen to be easy to see, but there is evidence that other types of

  1241.             cell can reconstruct tissues by their ameboid movements, when circumstances are right. Tumors or tissue

  1242.             abnormalities can appear or disappear with a suddenness that seems impossible to people who have studied

  1243.             only fixed tissue preparations.

  1244.         </p>

  1245.         <p>

  1246.             Stimulation is anabolic, building tissue, when the organism is adapting to the stimulation. Unused

  1247.             structures in cells and tissues are always being recycled by metabolic processes. When tissues are injured

  1248.             and become unable to function, some of their substances stimulate the growth of replacement cells.

  1249.         </p>

  1250.         <p>

  1251.             Some types of injury or irritation can activate regenerative processes. A dermatology journal described the

  1252.             case of an old man who had been bald for many years who fell head-first into his fireplace. As his burned

  1253.             scalp healed, new hair grew. In the U.S., experimenters (Ito, et al., 2007) have found that injuring the

  1254.             skin of mice stimulates the formation of stem cells that are able to become hair follicle cells, supporting

  1255.             the regeneration of cells that had been absent. A brief exposure to estrogen, and other stress related

  1256.             signals (nitric oxide, endorphin, prostaglandins) can initiate stem cell proliferation.

  1257.         </p>

  1258.         <p>

  1259.             In the years after the first world war, Vladimir Filatov, who developed techniques of reconstructive

  1260.             surgery, including corneal transplants, found that cold storage of tissues (for example, corneas from

  1261.             cadavers) caused them to function better than fresh tissues, and he found that these stressed tissues would

  1262.             often spread a healing influence out into the surrounding tissues. Extracts of stressed tissues produced

  1263.             similar effects.

  1264.         </p>

  1265.         <p>

  1266.             L.V. Polezhaev began studying the regenerative capacities of mammals in the late 1940s, and his work showed

  1267.             that processes similar to embryonic induction are involved in the organism's responses to damaged tissues.

  1268.             For example, when a piece of killed muscle tissue is enclosed in a capsule ("diffusion chamber") that

  1269.             permits molecules, but no cells, to diffuse through it, and implanted subcutaneously, it had no inductive

  1270.             effect on surrounding cells. But when the pores of the capsule allowed cells to enter, skeletal muscle

  1271.             formed where the dead tissue had been, and tissue resembling heart muscle formed outside the capsule.

  1272.             Phagocytosis had been essential for the induction to occur.

  1273.         </p>

  1274. 

  1275.         <p>

  1276.             Macrophages are ordinarily thought of as "antigen-presenting cells" that help to activate the specific

  1277.             immune responses. But apparently phagocytosis is involved in the replacement of damaged tissues, by

  1278.             recruiting or inducing the differentiation of replacement cells. The phagocytosis function isn't limited to

  1279.             the blood cells commonly called phagocytes; even nerve cells can ingest particles and fragments of damaged

  1280.             tissues.

  1281.         </p>

  1282.         <p>

  1283.             Many factors regulate the process of phagocytosis. Stress and lipid peroxidation decrease phagocytosis

  1284.             (Izg"t-Uysal, et al., 2004), and also damage mitochondria and inhibit cell renewal.

  1285.         </p>

  1286.         <p>

  1287.             Unsaturated fatty acids inhibit phagocytosis (Guimaraes, et al., 1991, 1992; Costa Rosa, et al., 1996;

  1288.             Virella, et al., 1989; Akamatsu, et al., 1990), and suppress mitochondrial function (Gomes, et al., 2006).

  1289.             Dietary restriction activates phagocytosis (Moriguchi, et al., 1989), suggesting that normal diets contain

  1290.             suppressive materials.

  1291.         </p>

  1292.         <p>

  1293.             Subnormal temperatures cause a shift from phagocytosis to inflammation. Light, especially the red light

  1294.             which penetrates easily into tissues, activates the formation of new cells as well as their differentiation.

  1295.             It affects energy production, increasing the formation of mitochondria, and the activity of the DNA

  1296.             methyltransferase enzymes. Red light accelerates wound healing, and improves the quality of the scar,

  1297.             reducing the amount of fibrosis. The daily cycling between darkness and light is probably an important

  1298.             factor in regulating the birth and differentiation of cells.

  1299.         </p>

  1300.         <p>

  1301.             Darkness suppresses mitochondrial function, and light activates it. Prolonged darkness increases cortisol,

  1302.             and cortisol (which makes cells more susceptible to excitotoxic death) inhibits stem cell proliferation (Li,

  1303.             et al., 2006; Liu, et al., 2003). Neurogenesis is suppressed by stress, and increased by spontaneous

  1304.             activity, and has a circadian rhythm. Aging and depression both involve a diminished ability to rhythmically

  1305.             lower the production of cortisol. Cell renewal requires a rhythmic decrease in the exposure to cortisol..

  1306.         </p>

  1307. 

  1308.         <p>

  1309.             In the spring, with increased day length, the brains of song-birds grow, with an increased proliferation of

  1310.             cells in the part of the brain involved in singing. The production of progesterone increases in most animals

  1311.             in the spring, and it is the main hormone responsible for the birds' brain growth.

  1312.         </p>

  1313.         <p>

  1314.             Progesterone and its metabolites protect brain cells against injury, and improve the brain's ability to

  1315.             recover after traumatic injury (Brinton and Wang, 2006). In the 1960s, Marion Diamond's group showed that

  1316.             environmental enrichment, or progesterone, caused brains to grow larger, and that these changes were passed

  1317.             on to descendants in a cumulative, increasing way. This suggests that the factors that promote neurogenesis

  1318.             also cause changes in the apparatus of reproduction and inheritance, that support the development of the

  1319.             brain--probably including the methylation system, which is involved in regulating genes, and also mood and

  1320.             behavior.

  1321.         </p>

  1322.         <p>

  1323.             Women's monthly cycles, in which a brief estrogen dominance is followed by sustained exposure to

  1324.             progesterone, are probably an important factor in the renewal of the cells of the brain and other organs, as

  1325.             well as those of the reproductive organs. The daily rhythms of hormones and metabolism are known to be

  1326.             involved in the regulation of cell renewal.

  1327.         </p>

  1328.         <p>

  1329.             Environmental enrichment, learning, high altitude, and thyroid hormone promote the formation of new

  1330.             mitochondria, and stimulate stem cell proliferation. At least in some laboratories, 20% oxygen,

  1331.             approximately the amount as in the atmosphere, suppresses the proliferation of stem cells (He, et al.,

  1332.             2007). This was the unphysiologically high concentration of oxygen used in Hayflick's cell cultures. At high

  1333.             altitudes, where tissues are exposed to less oxygen, and more carbon dioxide, there is a lower incidence of

  1334.             all the degenerative diseases, including cancer, heart disease, and dementia. Improved cellular energy

  1335.             production and more active renewal of cells would probably account for those differences.

  1336.         </p>

  1337. 

  1338.         <p>

  1339.             For Crick, the idea of a diffusion gradient to explain embryonic development was simply an extension of his

  1340.             reductionist orientation, in which diffusing molecules induced or inhibited bacterial genes, and in which

  1341.             genes controlled cells. For people with that orientation, the adaptive mutations described by Carl

  1342.             Lindegren, and later by John Cairns, or even the stress-induced variability described by Lysenko, Strong,

  1343.             and McClintock, were heretical. Polezhaev's demonstration that cells could do something that molecular

  1344.             diffusion didn't do, threatened to take biology away from the reductionists. If the organism's adaptation to

  1345.             the environment involves changing its own genes, Crick's paradigm fails.

  1346.         </p>

  1347.         <p>

  1348.             Crick's Central Dogma, derived from the ideology that produced Weismann's Barrier, has been invoked by

  1349.             generations of professors who wanted to deny the possibility of adaptive tissue renewal and regeneration.

  1350.             Without the dogma, new ideas about aging and disease will be needed. If somatic cells can adjust their

  1351.             genes, and if they can also differentiate into new eggs and sperms, new ideas about inheritance of acquired

  1352.             traits will be needed.

  1353.         </p>

  1354.         <p>

  1355.             The replacement of injured cells means that mutations need not accumulate. Cell renewal with elimination of

  1356.             mutant cells has been observed in sun-damaged skin simply by stopping the damage, and mitochondria with

  1357.             damaged DNA can be replaced by healthy mitochondria simply by doing the right kind of exercise.

  1358.         </p>

  1359.         <p>

  1360.             The regulation of cell renewal probably involves all of the processes of life, but there are a few simple,

  1361.             interacting factors that suppress renewal. The accumulation of polyunsaturated fats, interacting with a high

  1362.             concentration of oxygen, damages mitochondria, and causes a chronic excessive exposure to cortisol. With

  1363.             mitochondrial damage, cells are unable to produce the progesterone needed to oppose cortisol and to protect

  1364.             cells.

  1365.         </p>

  1366. 

  1367.         <p>

  1368.             Choosing the right foods, the right atmosphere, the right mental and physical activities, and finding the

  1369.             optimal rhythms of light, darkness, and activity, can begin to alter the streaming renewal of cells in all

  1370.             the organs. Designing a more perfect environment is going to be much simpler than the schemes of the genetic

  1371.             engineers.

  1372.         </p>

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  1621.         <h1>

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  1623.             </strong>

  1624.         </h1>

  1625.         <p>

  1626.             Cell renewal is a factor in all aspects of health and disease, not just in aging and the degenerative

  1627.             diseases. Many people are doing valid research relating to cell renewal and regeneration, but its usefulness

  1628.             is seriously limited by cultural and commercial constraints. By recovering some of our suppressed

  1629.             traditional culture, I think regenerative therapies can be developed quickly, by identifying and eliminating

  1630.             as far as possible the main factors that interfere with tissue renewal.

  1631.         </p>

  1632.         <p>

  1633.             Science grew up in the highly authoritarian cultures of western Europe, and even as it contributed to

  1634.             cultural change, it kept an authoritarian mystique. Any culture functions as a system of definitions of

  1635.             reality and the limits of possibility, and to a great extent the "laws of nature" are decreed so that they

  1636.             will harmonize with the recognized laws of society.

  1637.         </p>

  1638. 

  1639.         <p>

  1640.             The practical success of Newton's "laws" of motion when they were applied to ballistics and "rocket science"

  1641.             has led many people to value calculation, based on those laws, over evidence. In biology, the idea that an

  1642.             organism is "the information it contains in its DNA blueprint" is an extention of this. The organism is

  1643.             turned into something like a deductive expression of the law of DNA. This attitude has been disastrous.

  1644.         </p>

  1645.         <p>

  1646.             The old feudal idea of a divine and stable social organization was applied by some people to their idea of

  1647.             biological organization, in which each cell (ruled by its nucleus) had its ordained place in the organism,

  1648.             with the brain and the "master gland," the pituitary, ruling the subordinate organs, tissues, and cells.

  1649.             "Anatomy" was taught from dead specimens, microscope slides, and illustrations in books. Most biologists'

  1650.             thoughts about cells in organisms reflect the static imagery of their instruction. (<em>"The histological

  1651.                 image of these tissues actually reflects an instantaneous picture of cells in a continuous flux."</em>

  1652.             Zajicek, 1981.)

  1653.         </p>

  1654. 

  1655.         <p>

  1656.             When a person has playful and observant interactions with natural things, both regularities and

  1657.             irregularities will be noticed, and in trying to understand those events, the richness of the experience

  1658.             will suggest an expansive range of possibilities. Perception and experimentation lead to understandings that

  1659.             are independent of culture and tradition.

  1660.         </p>

  1661.         <p>

  1662.             But the mystique of science easily imposes itself, and distracts our attention from direct interactions with

  1663.             things. As we learn to operate lab instruments, we are taught the kinds of results that can be expected, and

  1664.             the concepts that will explain and predict the results of our operations. Science, as we learn about it in

  1665.             schools and the mass media, is mostly a set of catechisms.

  1666.         </p>

  1667.         <p>

  1668.             Our theories about organisms inform our experiments with cells or tissues that have been isolated from those

  1669.             organisms. The conditions for growing cells in dishes are thought of as "physiological," in relation to the

  1670.             solution's "physiological osmolarity," "physiological pH," nutrients, oxygenation, temperature, pressure,

  1671.             etc. But these concepts of what is physiological derive from the monolithic ideology of the doctrinaire, and

  1672.             often fraudulent, mainstream of biological science.

  1673.         </p>

  1674. 

  1675.         <p>

  1676.             The catechismic nature of science has led people to expect some "break-throughs" to occur in certain areas,

  1677.             and as authoritarian science has grown into "big science" managed by corporations and governments, those

  1678.             break-throughs are generally expected to be produced by the newest and most expensive developments of "high

  1679.             technology."

  1680.         </p>

  1681.         <p>

  1682.             But looking closely at the real events and processes in the sciences in the last couple of centuries, it

  1683.             turns out that useful advances have been produced mainly by breaking away from authoritarian doctrines, to

  1684.             return to common sense and relatively simple direct observations.

  1685.         </p>

  1686.         <p>

  1687.             Although people were cloning animals in the 1960s, it was still widely taught that it was impossible. The

  1688.             students of the professors who taught that it was impossible are now saying that it requires high technology

  1689.             and new research.

  1690.         </p>

  1691. 

  1692.         <p>

  1693.             For the last 100 years the most authoritative view in biology has been that there are no stem cells in

  1694.             adults, that brains, hearts, pancreases and oocytes are absolutely incapable of regeneration. But now,

  1695.             people seem to be finding stem cells wherever they look, but there is a mystique of high technology involved

  1696.             in finding and using them.

  1697.         </p>

  1698.         <p>

  1699.             Whether it's deliberate or not, the emphasis on stem cell technology has the function of directing attention

  1700.             away from traditional knowledge, the way allopathic medicine has de-emphasized the intrinsic ability of

  1701.             people to recover from disease.

  1702.         </p>

  1703.         <p>

  1704.             This resembles the way that the Mendel-Morgan gene doctrine was used to suppress the knowledge gained from

  1705.             centuries of experience of plant and animal breeders, and to belittle the discoveries of Luther Burbank,

  1706.             Paul Kammerer, Trofim Lysenko, and Barbara McClintock. The same type of biochemical process that caused the

  1707.             hereditary changes those researchers studied are involved in the differentiation and dedifferentiation of

  1708.             stem cells that regulate healing and regeneration.

  1709.         </p>

  1710.         <p>

  1711.             In the 1940s, even children discussed the biological discoveries of the 1920s and 1930s, the work in

  1712.             regeneration and adaptation, parthenogenesis, and immortalization. The ideas of J. Loeb, T. Boveri, A.

  1713.             Gurwitsch, J. Needham, C.M. Child, A. Carrel, et al., had become part of the general culture.

  1714.         </p>

  1715.         <p>

  1716.             But that real biology was killed by a consortium of industry and government that began a little before the

  1717.             second world war. In 1940, the government was supporting research in chemical and biological warfare, and

  1718.             with the Manhattan Project the role of government became so large that all of the major research

  1719.             universities were affected. Shortly after the war, many researchers from the Manhattan Project were

  1720.             redeployed into "molecular genetics," where the engineering attitude was applied to organisms.

  1721.         </p>

  1722. 

  1723.         <p>

  1724.             The simplistic genetic dogmas were compatible with the reductionist engineering approach to the organism.

  1725.             The role of the government assured that the universities would subscribe to the basic scientific agenda. The

  1726.             atmosphere of that time was described by Carl Lindegren as "The Cold War in Biology" (1966).

  1727.         </p>

  1728.         <p>

  1729.             The disappearance of the field concept in developmental biology was one of the strangest events in the

  1730.             history of science. It didn't just fade away, it was "disappeared," in a massive undertaking of social

  1731.             engineering. In its absence, stem cells will seem to be a profitable technological marvel, rather than a

  1732.             universal life function, with a central role in everything we are and everything we do and can become.

  1733.         </p>

  1734.         <p>

  1735.             Many people have tried to explain aging as a loss of cells, resulting from an intrinsic inability of any

  1736.             cell other than a germ cell to multiply more than a certain number of times. More than 40 years ago Leonard

  1737.             Hayflick popularized this doctrine in its most extreme form, saying that no cell can divide more than 50

  1738.             times unless it is converted into a cancer cell. He and his followers claimed that they had explained why

  1739.             organisms must age and die. At the moment the ovum is fertilized, the clock starts ticking for the

  1740.             essentially mortal somatic cells.

  1741.         </p>

  1742.         <p>

  1743.             In 1970, it was being seriously proposed that memory was produced by the death of brain cells, in a manner

  1744.             analogous to the holes punched in cards to enter data into computers. The cultural dogma made it impossible

  1745.             to consider that learning could be associated with the birth of new cells in the adult brain.

  1746.         </p>

  1747. 

  1748.         <p>

  1749.             With the announcement in 1997 of the cloning of the sheep Dolly from a somatic cell taken from a 6 year old

  1750.             sheep, there was renewed interest in the idea made famous by Alexis Carrel that all cells are potentially

  1751.             immortal, and in the possibility of preserving the vitality of human cells. Within a few months, Hayflick

  1752.             began reminding the public that "In the early 1960's we overthrew this dogma after finding that normal cells

  1753.             do have a finite replicative capacity." ("During the first half of this century it was believed that because

  1754.             cultured normal cells were immortal, aging must be caused by extra-cellular events.") The way Hayflick

  1755.             "overthrew" more than 35 years of work at the Rockefeller Institute was by growing one type of cell, a lung

  1756.             fibroblast, in culture dishes, and finding that the cultures deteriorated quickly.

  1757.         </p>

  1758.         <p>

  1759.             To draw global conclusions about an organism's development and aging from the degenerative processes seen in

  1760.             a single type of cell, grown in isolation from all normal stimuli, would have been treated as nothing but

  1761.             wild speculation, except that it occurred within a culture that needed it. No aspect of Hayflick's cell

  1762.             culture system could properly be called physiological.

  1763.         </p>

  1764. 

  1765.         <p>

  1766.             Other researchers, simply by changing a single factor, caused great increases in the longevity of the

  1767.             cultured cells. Simply using a lower, more natural oxygen concentration, the cells were able to undergo 20

  1768.             more divisions. Just by adding niacin, 30 more divisions; vitamin E, 70 more divisions. Excess oxygen is a

  1769.             poison requiring constant adaptation.

  1770.         </p>

  1771.         <p>

  1772.             Hayflick also published the observation that, while the cells kept in dishes at approximately body

  1773.             temperature deteriorated, cells kept frozen in liquid nitrogen didn't deteriorate, and he concluded that

  1774.             "time" wasn't the cause of aging. When I read his comments about the frozen cells, I wondered how anyone of

  1775.             normal intelligence could make such stupid statements. Since then, facts that came out because of the

  1776.             Freedom of Information Act, cause me to believe that a financial motive guided his thoughts about his

  1777.             cultured fibroblasts.

  1778.         </p>

  1779.         <p>

  1780.             Hayflick and his followers have been attacking the idea of anti-aging medicine as quackery. But he is

  1781.             closely involved with the Geron corporation, which proposes that genetic alterations relating to telomeres

  1782.             may be able to cure cancer and prevent aging. Their claims were reported by CNN as "Scientists discover

  1783.             cellular 'fountain of youth'."

  1784.         </p>

  1785. 

  1786.         <p>

  1787.             The "wear and tear" doctrine of aging that derived from the ideology of the gene was reinforced and renewed

  1788.             by Hayflick's cell culture observations, and it continued to rule the universities and popular culture.

  1789.         </p>

  1790.         <p>

  1791.             But detailed investigation of skin cell growth showed that cells in the lower layer of the skin divide at

  1792.             least 10,000 times in a normal lifetime, and similar processes occur in the lining of the intestine. The

  1793.             endometrium and other highly renewable tissues just as obviously violated Hayflick's limit. Transplantation

  1794.             experiments showed that pieces of mammary tissue or skin tissue could survive through ten normal lifetimes

  1795.             of experimental animals without suffering the effects of aging.

  1796.         </p>

  1797.         <p>

  1798.             Even the liver and adrenal gland are now known to be continuously renewed by "cell streaming," though at a

  1799.             slower rate than the skin, conjunctiva, and intestine. Neurogenesis in the brain is now not only widely

  1800.             accepted, it is even proposed as a mechanism to explain the therapeutic effects of antidepressants

  1801.             (Santarelli, et al., 2003).

  1802.         </p>

  1803. 

  1804.         <p>

  1805.             August Weismann's most influential doctrine said that "somatic cells are mortal, only the germline cells are

  1806.             immortal," but he based the doctrine on his mistaken belief that only the "germline" cells contained all the

  1807.             genes of the organism. In 1885, to "refute" Darwin's belief that acquired traits could be inherited, he

  1808.             promulgated an absolute "barrier" between "germline" and "soma," and invented facts to show that hereditary

  1809.             information can flow only from the germline to the somatic cells, and not the other direction. Shortly after

  1810.             DNA became popular in the 1950s as "the genetic material," Weismann's barrier was restated as the Central

  1811.             Dogma of molecular genetics, that information flows only from DNA to RNA to protein, and never the other

  1812.             direction.

  1813.         </p>

  1814.         <p>

  1815.             It was only in 2003, after the reality of cloning was widely recognized, that a few experimenters began to

  1816.             investigate the origin of "germline" cells in the ovary, and to discover that they derive from somatic cells

  1817.             (Johnson, et al., 2004). With this discovery, the ancient knowledge that a twig (<em>klon</em>, in Greek)

  1818.             cut from a tree could grow into a whole tree, bearing fruit and viable seeds, was readmitted to general

  1819.             biology, and the Weismann barrier was seen to be an illusion.

  1820.         </p>

  1821.         <p>

  1822.             Millions of people have "explained" female reproductive aging as the consequence of the ovary "running out

  1823.             of eggs." Innumerable publications purported to show the exact ways in which that process occurs, following

  1824.             the Weismann doctrine. But now that it is clear that adult ovaries can give birth to new oocytes, a new

  1825.             explanation for female reproductive aging is needed. It is likely that the same factors that cause female

  1826.             reproductive aging also cause aging of other systems and organs and tissues, and that those factors are

  1827.             extrinsic to the cells themselves, as Alexis Carrel and others demonstrated long ago. This is a way of

  1828.             saying that all cells are potential stem cells. The "niche" in which new cells are born in the streaming

  1829.             organism, and the processes by which damaged cells are removed, are physiological issues that can be

  1830.             illuminated by the idea of a morphogenetic field.

  1831.         </p>

  1832.         <p>

  1833.             When the post-war genetic engineers took over biological research, the idea of a biophysical field was

  1834.             totally abandoned, but after about 15 years, it became necessary to think of problems beyond those existing

  1835.             within a single bacterium, namely, the problem of how an ovum becomes and embryo. Francis Crick, of DNA

  1836.             fame, who was educated as a physicist, revived (without a meaningful historical context) the idea of a

  1837.             diffusion gradient as a simple integrating factor that wouldn't be too offensive to the reductionists. But

  1838.             for events far beyond the scale of the egg's internal structure, for example to explain how a nerve axon can

  1839.             travel a very long distance to innervate exactly the right kind of cell, the diffusion of molecules loses

  1840.             its simplicity and plausibility. (Early in the history of experimental embryology, it was observed that

  1841.             electrical fields affect the direction of growth of nerve fibers.)

  1842.         </p>

  1843.         <p>

  1844.             C. M. Child saw a gradient of metabolic activity as an essential component of the morphogenetic field. This

  1845.             kind of gradient doesn't deny the existence of diffusion gradients, or other physical components of a field.

  1846.             Electrical and osmotic (and electro-osmotic) events are generated by metabolism, and affect other factors,

  1847.             including pH, oxidation and reduction, cell motility and cell shape, ionic selectivity and other types of

  1848.             cellular selectivity and specificity. Gradients of DNA methylation exist, and affect the expression of

  1849.             inherited information.

  1850.         </p>

  1851.         <p>

  1852.             Methylation decreases the expression of particular genes, and during the differention of cells in the

  1853.             development of an embryo, genes are methylated and demethylated as the cell adapts to produce the proteins

  1854.             that are involved in the structure and function of a particular tissue. Methylation (which increases a

  1855.             molecule's affinity for fats) is a widespread process in cells, and for example regulates cellular

  1856.             excitability. It is affected by diet and a variety of stresses.

  1857.         </p>

  1858.         <p>

  1859.             DNA methylation patterns are normally fairly stable, and can help to account for the transgenerational

  1860.             transmission of acquired adaptations, and for neonatal imprinting that can last a lifetime. But with injury,

  1861.             stress, and aging, the methylation patterns of differentiated tissues can be changed, contributing to the

  1862.             development of tumors, or to the loss of cellular functions. Even learning can change the methylation of

  1863.             specific genes. During <em>in vitro</em> culture, the enzymes of gene methylation are known to be increased,

  1864.             relative to their normal activity (Wang, et al., 2005).

  1865.         </p>

  1866. 

  1867.         <p>

  1868.             The phenomenon of "gene" methylation in response to environmental and metabolic conditions may eventually

  1869.             lead to the extinction of the doctrine that "cells are controlled by their genes."

  1870.         </p>

  1871.         <p>

  1872.             During successful adaptation to stress, cells make adjustments to their metabolic systems (for example with

  1873.             a holistic change of the degree of phosphorylation, which increases molecules' affinity for water), and

  1874.             their metabolic processes can contribute to changes in their state of differentiation. Some changes may lead

  1875.             to successful adaptation (for example by producing biogenic stimulators that stimulate cell functioning and

  1876.             regeneration), others to failed adaptation. Even the decomposition of cells can release substances that

  1877.             contribute to the adaptation of surrounding cells, for example when sphingosines stimulate the production of

  1878.             stem cells.

  1879.         </p>

  1880.         <p>

  1881.             DNA methylation is just one relatively stable event that occurs in relation to a metabolic field.

  1882.             Modifications of histones (regulatory proteins in chromosomes, which are acetylated as well as methylated)

  1883.             and structural-contractile filaments also contribute to the differentiation of cells, but the pattern of DNA

  1884.             methylation seems to guide the methylation of histones and the structure of the chromosomes (Nan, et al.,

  1885.             1998).

  1886.         </p>

  1887.         <p>

  1888.             Steroids and phospholipids, neurotransmitters and endorphins, ATP, GTP, other phosphates, retinoids, NO and

  1889.             CO2--many materials and processes participate in the coherence of the living state, the living substance.

  1890.             Carbon dioxide, for example, by binding to lysine amino groups in the histones, will influence their

  1891.             methylation. Carbon dioxide is likely to affect other amino groups in the chromosomes.

  1892.         </p>

  1893. 

  1894.         <p>

  1895.             The number and arrangement of mitochondria is an important factor in producing and maintaining the metabolic

  1896.             gradients. Things that decrease mitochondrial energy production--nitric oxide, histamine, cytokines,

  1897.             cortisol--increase DNA methylation. Decreased gene expression is associated with reduced respiratory energy.

  1898.             It seems reasonable to guess that increased gene expression would demand increased availability of energy.

  1899.         </p>

  1900.         <p>

  1901.             As an ovum differentiates into an organism, cells become progressively more specialized, inhibiting the

  1902.             expression of many genes. Less energy is needed by stably functioning cells, than by actively adapting

  1903.             cells. A.I. Zotin described the process of maturing and differentiating as a decrease of entropy, an

  1904.             increase of order accompanying a decreased energy expenditure. The entropic egg develops into a less

  1905.             entropic embryo with a great expenditure of energy.

  1906.         </p>

  1907.         <p>

  1908.             The partially differentiated stem cell doesn't go through all the stages of development, but it does expend

  1909.             energy intensely as it matures.

  1910.         </p>

  1911.         <p>

  1912.             The restoration of energy is one requirement for the activation of regeneration. When a hormone such as

  1913.             noradrenaline or insulin causes a stem cell to differentiate in vitro, it causes new mitochondria to form.

  1914.             This is somewhat analogous to the insertion of mitochondria into the ripening oocyte, by the nurse cells

  1915.             that surround it. The conditionally decreased entropy of maturation is reversed, and when sufficient

  1916.             respiratory energy is available, the renewed and refreshed cell will be able to renew an appropriate degree

  1917.             of differentiation.

  1918.         </p>

  1919.         <p>

  1920.             When simple organisms, such as bacteria, fungi, or protozoa are stressed, for example by the absence of

  1921.             nutrients or the presence of toxins, they slow their metabolism, and suppress the expression of genes,

  1922.             increasing the methylation of DNA, to form resistant and quiescent spores. Our differentiated state doesn't

  1923.             go to the metabolic extreme seen in sporulation, but it's useful to look at maturity and aging in this

  1924.             context, because it suggests that the wrong kind of stress decreases the ability of the organism to adapt,

  1925.             by processes resembling those in the spore-forming organisms.

  1926.         </p>

  1927. 

  1928.         <p>

  1929.             Charles Vacanti, who has grown cartilage from cells taken from 100 year old human cartilage, believes our

  1930.             tissues contain "spore cells," very small cells with slow metabolism and extreme resistance to heat, cold,

  1931.             and starvation.

  1932.         </p>

  1933.         <p>

  1934.             If the slowed metabolism of aging, like that of sporulating cells, is produced by a certain kind of stress

  1935.             that lowers cellular energy and functions, it might be useful to think of the other stages of the stress

  1936.             reaction in relation to the production of stem cells. Selye divided stress into a first stage of shock,

  1937.             followed by a prolonged adaptation, which could sometimes end in exhaustion. If the maturity of

  1938.             differentiated functioning is equivalent to the adaptation phase, and cellular decline and disintegration is

  1939.             the exhaustion phase, then the shock-like reaction would correspond to the birth of new stem cells.

  1940.         </p>

  1941.         <p>

  1942.             Selye described estrogen's effects as equivalent to the shock-phase of stress. Estrogen's basic action is to

  1943.             make oxygen unavailable, lowering the oxygen tension of the tissues, locally and temporarily. Like nitric

  1944.             oxide, which is produced by estrogenic stimulation, estrogen interferes with energy production, so if its

  1945.             stimulation is prolonged, cells are damaged or killed, rather than being stimulated to regenerate.

  1946.         </p>

  1947.         <p>

  1948.             Extrinsic factors elicit renewal, the way stress can elicit adaptation. While aging cells can't use the

  1949.             oxygen that is present, a scarcity of oxygen can serve as a stimulus to maximize the respiratory systems.

  1950.             Brief oxygen deprivation excites a cell, causes it to swell, and to begin to divide.

  1951.         </p>

  1952. 

  1953.         <p>

  1954.             Oxygen deprivation, as in the normally hypoxic bone marrow, stimulates the formation of stem cells, as well

  1955.             as the biogenesis of mitochondria. As the newly formed cells, with abundant mitochondria, get adequate

  1956.             oxygen, they begin differentiation.

  1957.         </p>

  1958.         <p>

  1959.             Form, based on cellular differentiation, follows function--a vein transplanted into an artery develops

  1960.             anatomically into an artery, a colon attached directly to the anus becomes a new rectum with its appropriate

  1961.             innervation, a broken bone restructures to form a normal bone. If the bladder is forced to function more

  1962.             than normal, by artificially keeping it filled, its thin wall of smooth muscle develops into a thick wall of

  1963.             striated muscle that rhythmically contracts, like the heart. If a tadpole is given a vegetarian diet, the

  1964.             absorptive surface of its digestive system will develop to be twice the size of those that are fed meat.

  1965.             Pressure, stretching, and pulsation are among the signals that guide cells' differentiation.

  1966.         </p>

  1967.         <p>

  1968.             Very early in the study of embryology it was noticed that the presence of one tissue sometimes induced the

  1969.             differentiation of another kind, and also that there were factors in embryonic tissues that would stimulate

  1970.             cell division generally, and others that could inhibit the growth of a particular tissue type. Diffusable

  1971.             substances and light were among the factors identified as growth regulators.

  1972.         </p>

  1973.         <p>

  1974.             Extracts of particular tissues were found to suppress the multiplication of cells in that type of tissue, in

  1975.             adult animals as well as in embryos. In the 1960s, the tissue-specific inhibitors were called chalones.

  1976.         </p>

  1977.         <p>

  1978.             The brain's development is governed by the presence in the organism of the body part to which it

  1979.             corresponds, such as the eyes or legs. The number of cells in a particular part of the nervous system is

  1980.             governed by the quantity of nervous input, sensory or motor, that it receives. An enriched environment

  1981.             causes a bigger brain to grow. Sensory nerve stimulation of a particular region of the brain causes nerve

  1982.             cells to migrate to that area (a process called neurobiotaxis; deBeers, 1927), but nerve stimulation also

  1983.             causes mitochondria to accumulate in stimulated areas. Nerve activity has a trophic, sustaining influence on

  1984.             other organs, as well as on the brain. Nerve stimulation, like mechanical pressure or stretching, is an

  1985.             important signal for cellular differentiation.

  1986.         </p>

  1987. 

  1988.         <p>

  1989.             When stem cells or progenitor cells are called on to replace cells in an organ, they are said to be

  1990.             "recruited" by that organ, or to "home" to that organ, if they are coming from elsewhere. Traditionally, the

  1991.             bone marrow has been considered to be the source of circulating stem cells, but it now appears that a

  1992.             variety of other less differentiated cells can be recruited when needed. Cells from the blood can repair the

  1993.             endothelium of blood vessels, and endothelial cells can become mesenchymal cells, in the heart, for example.

  1994.         </p>

  1995.         <p>

  1996.             The standard doctrine about cancer is that a tumor derives from a single mutant cell, but it has been known

  1997.             for a long time that different types of cell, such as phagocytes and mast cells, usually reside in tumors,

  1998.             and it is now becoming clear that tumors recruit cells, including apparently normal cells, from other parts

  1999.             of the same organ. For example, a brain tumor of glial cells, a glioma, recruits glial cells from

  2000.             surrounding areas of the brain, in a process that's analogous to the embryological movement of nerve cells

  2001.             to a center of excitation. Each tumor, in a sense, seems to be a center of excitation, and its fate seems to

  2002.             depend on the nature of the cells that respond to its signals.

  2003.         </p>

  2004.         <p>

  2005.             To accommodate some of the newer facts about tumors, the cancer establishment has begun speaking of "the

  2006.             cancer stem cell" as the real villain, the origin of the tumor, while the bulk of the tumor is seen to be

  2007.             made up of defective cells that have a short life-span. But if we recognize that tumors are recruiting cells

  2008.             from beyond their boundaries, this process would account for the growth and survival of a tumor even while

  2009.             most of its cells are inert and dying, without invoking the invisible cancer stem cell. And this view, that

  2010.             it is the field which is defective rather than the cell, is consistent with the evidence which has been

  2011.             accumulating for 35 years that tumor cells, given the right environment, can differentiate into healthy

  2012.             cells. (Hendrix, et al., 2007)

  2013.         </p>

  2014. 

  2015.         <p>

  2016.             Simply stretching an organ (Woo, et al., 2007) is stimulus enough to cause it to recruit cells from the

  2017.             bloodstream, and will probably stimulate multiplication in its local resident cells, too. Every "cancer

  2018.             field" probably begins as a healing process, and generally the healing and regeneration are at least

  2019.             partially successful.

  2020.         </p>

  2021.         <p>

  2022.             When an organ--the brain, heart, liver, or a blood vessel--is inflamed or suffering from an insufficient

  2023.             blood supply, stem cells introduced into the blood will migrate specifically to that organ.

  2024.         </p>

  2025.         <p>

  2026.             Organ specific materials (chalones) are known to circulate in the blood, inhibiting cell division in cells

  2027.             typical to that organ, but it also seems that organ specific materials are secreted by a damaged organ, that

  2028.             help to prepare stem cells for their migration into that organ. When undifferentiated cells are cultured

  2029.             with serum from a person with liver failure, they begin to differentiate into liver cells.

  2030.         </p>

  2031.         <p>

  2032.             It is still common to speak of each organ as having a "clonal origin" in the differentiating embryo, as a

  2033.             simple expansion of a certain embryonic anlage. The implication of this way of thinking is that

  2034.             differentiation is <em>determination</em> in an irreversible sense. This is another case of medical ideas

  2035.             being based on images of fixed histological material. Normal cells, including nerve and muscle cells, can

  2036.             change type, with connective tissue cells becoming nerve cells, nerve cells becoming muscle and fiber cells,

  2037.             fat, fiber, and muscle cells redifferentiating, for example.

  2038.         </p>

  2039. 

  2040.         <p>

  2041.             Cell movements in solid tissues aren't limited to the short distances between capillaries and the tissues

  2042.             nourished by those capillaries, rather, cells can migrate much greater distances, without entering the

  2043.             bloodstream. The speed of a single cell moving by ameboid motion can be measured by watching cells on a

  2044.             glass slide as they move toward food, or by watching cells of the slime mold Dictyostelium when they are

  2045.             aggregating, or by watching the pigment cells in and around moles or melanomas, under the influence of

  2046.             hormones. At body temperature, a single cell can crawl about an inch per day. Waves or spots of brown

  2047.             pigment can be seen migrating through the skin away from a mole, preceding the disintegration of the mole

  2048.             under the influence of progesterone or DHEA. Under ordinary conditions, pigment cells can sometimes be seen

  2049.             migrating into depigmented areas of skin, during the recovery of an area affected by vitiligo. These

  2050.             organized movements of masses of cells happen to be easy to see, but there is evidence that other types of

  2051.             cell can reconstruct tissues by their ameboid movements, when circumstances are right. Tumors or tissue

  2052.             abnormalities can appear or disappear with a suddenness that seems impossible to people who have studied

  2053.             only fixed tissue preparations.

  2054.         </p>

  2055.         <p>

  2056.             Stimulation is anabolic, building tissue, when the organism is adapting to the stimulation. Unused

  2057.             structures in cells and tissues are always being recycled by metabolic processes. When tissues are injured

  2058.             and become unable to function, some of their substances stimulate the growth of replacement cells.

  2059.         </p>

  2060.         <p>

  2061.             Some types of injury or irritation can activate regenerative processes. A dermatology journal described the

  2062.             case of an old man who had been bald for many years who fell head-first into his fireplace. As his burned

  2063.             scalp healed, new hair grew. In the U.S., experimenters (Ito, et al., 2007) have found that injuring the

  2064.             skin of mice stimulates the formation of stem cells that are able to become hair follicle cells, supporting

  2065.             the regeneration of cells that had been absent. A brief exposure to estrogen, and other stress related

  2066.             signals (nitric oxide, endorphin, prostaglandins) can initiate stem cell proliferation.

  2067.         </p>

  2068.         <p>

  2069.             In the years after the first world war, Vladimir Filatov, who developed techniques of reconstructive

  2070.             surgery, including corneal transplants, found that cold storage of tissues (for example, corneas from

  2071.             cadavers) caused them to function better than fresh tissues, and he found that these stressed tissues would

  2072.             often spread a healing influence out into the surrounding tissues. Extracts of stressed tissues produced

  2073.             similar effects.

  2074.         </p>

  2075.         <p>

  2076.             L.V. Polezhaev began studying the regenerative capacities of mammals in the late 1940s, and his work showed

  2077.             that processes similar to embryonic induction are involved in the organism's responses to damaged tissues.

  2078.             For example, when a piece of killed muscle tissue is enclosed in a capsule ("diffusion chamber") that

  2079.             permits molecules, but no cells, to diffuse through it, and implanted subcutaneously, it had no inductive

  2080.             effect on surrounding cells. But when the pores of the capsule allowed cells to enter, skeletal muscle

  2081.             formed where the dead tissue had been, and tissue resembling heart muscle formed outside the capsule.

  2082.             Phagocytosis had been essential for the induction to occur.

  2083.         </p>

  2084. 

  2085.         <p>

  2086.             Macrophages are ordinarily thought of as "antigen-presenting cells" that help to activate the specific

  2087.             immune responses. But apparently phagocytosis is involved in the replacement of damaged tissues, by

  2088.             recruiting or inducing the differentiation of replacement cells. The phagocytosis function isn't limited to

  2089.             the blood cells commonly called phagocytes; even nerve cells can ingest particles and fragments of damaged

  2090.             tissues.

  2091.         </p>

  2092.         <p>

  2093.             Many factors regulate the process of phagocytosis. Stress and lipid peroxidation decrease phagocytosis

  2094.             (Izg"t-Uysal, et al., 2004), and also damage mitochondria and inhibit cell renewal.

  2095.         </p>

  2096.         <p>

  2097.             Unsaturated fatty acids inhibit phagocytosis (Guimaraes, et al., 1991, 1992; Costa Rosa, et al., 1996;

  2098.             Virella, et al., 1989; Akamatsu, et al., 1990), and suppress mitochondrial function (Gomes, et al., 2006).

  2099.             Dietary restriction activates phagocytosis (Moriguchi, et al., 1989), suggesting that normal diets contain

  2100.             suppressive materials.

  2101.         </p>

  2102.         <p>

  2103.             Subnormal temperatures cause a shift from phagocytosis to inflammation. Light, especially the red light

  2104.             which penetrates easily into tissues, activates the formation of new cells as well as their differentiation.

  2105.             It affects energy production, increasing the formation of mitochondria, and the activity of the DNA

  2106.             methyltransferase enzymes. Red light accelerates wound healing, and improves the quality of the scar,

  2107.             reducing the amount of fibrosis. The daily cycling between darkness and light is probably an important

  2108.             factor in regulating the birth and differentiation of cells..

  2109.         </p>

  2110.         <p>

  2111.             Darkness suppresses mitochondrial function, and light activates it. Prolonged darkness increases cortisol,

  2112.             and cortisol (which makes cells more susceptible to excitotoxic death) inhibits stem cell proliferation (Li,

  2113.             et al., 2006; Liu, et al., 2003). Neurogenesis is suppressed by stress, and increased by spontaneous

  2114.             activity, and has a circadian rhythm. Aging and depression both involve a diminished ability to rhythmically

  2115.             lower the production of cortisol. Cell renewal requires a rhythmic decrease in the exposure to cortisol..

  2116.         </p>

  2117. 

  2118.         <p>

  2119.             In the spring, with increased day length, the brains of song-birds grow, with an increased proliferation of

  2120.             cells in the part of the brain involved in singing. The production of progesterone increases in most animals

  2121.             in the spring, and it is the main hormone responsible for the birds' brain growth.

  2122.         </p>

  2123.         <p>

  2124.             Progesterone and its metabolites protect brain cells against injury, and improve the brain's ability to

  2125.             recover after traumatic injury (Brinton and Wang, 2006). In the 1960s, Marion Diamond's group showed that

  2126.             environmental enrichment, or progesterone, caused brains to grow larger, and that these changes were passed

  2127.             on to descendants in a cumulative, increasing way. This suggests that the factors that promote neurogenesis

  2128.             also cause changes in the apparatus of reproduction and inheritance, that support the development of the

  2129.             brain--probably including the methylation system, which is involved in regulating genes, and also mood and

  2130.             behavior.

  2131.         </p>

  2132.         <p>

  2133.             Women's monthly cycles, in which a brief estrogen dominance is followed by sustained exposure to

  2134.             progesterone, are probably an important factor in the renewal of the cells of the brain and other organs, as

  2135.             well as those of the reproductive organs. The daily rhythms of hormones and metabolism are known to be

  2136.             involved in the regulation of cell renewal.

  2137.         </p>

  2138.         <p>

  2139.             Environmental enrichment, learning, high altitude, and thyroid hormone promote the formation of new

  2140.             mitochondria, and stimulate stem cell proliferation. At least in some laboratories, 20% oxygen,

  2141.             approximately the amount as in the atmosphere, suppresses the proliferation of stem cells (He, et al.,

  2142.             2007). This was the unphysiologically high concentration of oxygen used in Hayflick's cell cultures. At high

  2143.             altitudes, where tissues are exposed to less oxygen, and more carbon dioxide, there is a lower incidence of

  2144.             all the degenerative diseases, including cancer, heart disease, and dementia. Improved cellular energy

  2145.             production and more active renewal of cells would probably account for those differences.

  2146.         </p>

  2147. 

  2148.         <p>

  2149.             For Crick, the idea of a diffusion gradient to explain embryonic development was simply an extension of his

  2150.             reductionist orientation, in which diffusing molecules induced or inhibited bacterial genes, and in which

  2151.             genes controlled cells. For people with that orientation, the adaptive mutations described by Carl

  2152.             Lindegren, and later by John Cairns, or even the stress-induced variability described by Lysenko, Strong,

  2153.             and McClintock, were heretical. Polezhaev's demonstration that cells could do something that molecular

  2154.             diffusion didn't do, threatened to take biology away from the reductionists. If the organism's adaptation to

  2155.             the environment involves changing its own genes, Crick's paradigm fails.

  2156.         </p>

  2157.         <p>

  2158.             Crick's Central Dogma, derived from the ideology that produced Weismann's Barrier, has been invoked by

  2159.             generations of professors who wanted to deny the possibility of adaptive tissue renewal and regeneration.

  2160.             Without the dogma, new ideas about aging and disease will be needed. If somatic cells can adjust their

  2161.             genes, and if they can also differentiate into new eggs and sperms, new ideas about inheritance of acquired

  2162.             traits will be needed.

  2163.         </p>

  2164.         <p>

  2165.             The replacement of injured cells means that mutations need not accumulate. Cell renewal with elimination of

  2166.             mutant cells has been observed in sun-damaged skin simply by stopping the damage, and mitochondria with

  2167.             damaged DNA can be replaced by healthy mitochondria simply by doing the right kind of exercise.

  2168.         </p>

  2169.         <p>

  2170.             The regulation of cell renewal probably involves all of the processes of life, but there are a few simple,

  2171.             interacting factors that suppress renewal. The accumulation of polyunsaturated fats, interacting with a high

  2172.             concentration of oxygen, damages mitochondria, and causes a chronic excessive exposure to cortisol. With

  2173.             mitochondrial damage, cells are unable to produce the progesterone needed to oppose cortisol and to protect

  2174.             cells.

  2175.         </p>

  2176. 

  2177.         <p>

  2178.             Choosing the right foods, the right atmosphere, the right mental and physical activities, and finding the

  2179.             optimal rhythms of light, darkness, and activity, can begin to alter the streaming renewal of cells in all

  2180.             the organs. Designing a more perfect environment is going to be much simpler than the schemes of the genetic

  2181.             engineers.

  2182.         </p>

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  2431.         © Ray Peat Ph.D. 2007. All Rights Reserved. www.RayPeat.com

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