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  1. <html>

  2.     <head><title></title></head>

  3.     <body>

  4.         <h1></h1>

  5. 

  6.         <p></p>

  7.         <p>

  8.             <strong><strong>Cataracts: water, energy, light, and aging</strong>&nbsp;</strong>Because of the baby boom

  9.             population bulge, the market for cataract surgery and the little plastic intraocular lenses is growing

  10.             wonderfully. According to the World Health Organization, there were about 20 million cataract surgeries

  11.             performed in 2010, with 32 million expected in 2020. In the US, about 3 million cataract surgeries are

  12.             performed annually. Revenue from sale of the intraocular lenses in the US alone was $775,000,000 in 2010,

  13.             and is expected to reach $965,000,000 by 2017. In 2010, the Alcon company earned $1,200,000,000 from one

  14.             type of intraocular lens. (Market Research.com) To promote the sale of the "premium'" lenses, which cost

  15.             thousands of dollars, patients are told that the more expensive lenses will save them money in the long run,

  16.             by making ordinary glasses unnecessary (sometimes).&nbsp;

  17.         </p>

  18.         <p>

  19.             <span>The lens replacement surgery is now sometimes recommended when a cataract has caused only a slight

  20.                 decrease in visual acuity, or even a suspected decrease in acuity. I haven't known anyone who had the

  21.                 surgery who had been informed of the incidence of complications of the surgery, which result in

  22.                 permanent blindness for thousands of the patients every year.&nbsp;</span>

  23.             <span>Some of the causes of cataracts have been known for many years, but the knowledge is usually ignored

  24.                 by the medical profession. Medical myths about the causes of disease support present practices. Myths

  25.                 about the causes of cancer, heart failure, hypertension, menopause, osteoporosis, sarcopenia,

  26.                 depression, dementia, and cataracts are designed to reinforce each other, forming an interlocking

  27.                 system, an ideology of the organism.&nbsp;</span>

  28.             <span>The conventional ideology identifies pathological cells and defective proteins and bad genes as the

  29.                 causes of organ failure and disease, and "aging" is seen as a dimension in which entropy tends to

  30.                 increase those defects.&nbsp;&nbsp;</span>

  31.             <span>This ideology discourages thoughts of "field" effects in which the function of a molecule, a cell, or

  32.                 an organ affects, and is affected by, things that aren't in direct contact with it. This is why the

  33.                 removal of a lens is treated so casually. There is some knowledge about the effects of systemic disease

  34.                 on the eye, but very little about the effects of particular parts of the eye on systemic physiology, and

  35.                 relatively few physicians are aware of the effects of one part of the eye on the other parts of the eye.

  36.                 A few of these physiological interactions within the eye are very interesting. For example, injury to

  37.                 the lens powerfully stimulates regeneration of nerves in the retina (Fischer, et al., 2000). Things

  38.                 which injure the lens enough to cause cataracts to develop might also be injuring the retina, but the

  39.                 emission of stimulating substances from the lens must be a compensating influence.&nbsp;</span>

  40.             <span>Every normal tissue of the eye is emitting substances that affect other parts of the eye, and probably

  41.                 other parts of the body. Until the 1970s, the literature was dominated by the view that the lens was a

  42.                 lifeless material, like hair and toenails, and even in 2013 there is great reluctance of researchers to

  43.                 recognize its vital cellular activity.</span>

  44.             <span>After an artificial lens has been implanted, there are great changes in the vitreous humor (which

  45.                 fills the space between the retina and the lens), with a reversal of the gradient of viscosity, and with

  46.                 changes in many proteins, including transthyretin, alpha antitrypsin, retinoic acid binding protein,

  47.                 antioxidant proteins, and the enzymes carbonic anhydrase and triosephosphate isomererase (Neal, et al.,

  48.                 2005).&nbsp;</span>

  49.             <span>I haven't seen any recent studies of the effects of lens removal on the nervous system, but a 1953

  50.                 study of 21 patients reported a high percentage of behavioral disturbances following the surgery:

  51.                 "Following the operation 20 patients showed some alteration in behavior including changes in mood,

  52.                 psychomotor disturbances, paranoid and somatic delusions, hallucinations, disorientation and

  53.                 confabulations. In 3 cases the disturbance was characterized as severe." "It is concluded that disturbed

  54.                 behavior is an integral part of the reaction of almost all cataract patients because of a complex

  55.                 interaction of a number of factors" (Linn, et al., 1953).&nbsp;</span>

  56.             <span>In animal studies, when the lens capsule is closed after removal of the lens, within a few weeks a

  57.                 well formed lens has regenerated (Gwon, et al., 1993); cell division is stimulated in the cells

  58.                 remaining attached to the capsule, similar to the regeneration of the adrenal cortex after its

  59.                 removal.&nbsp;</span>

  60.             <span>Artificial replacement lenses are designed (with an ultrasharp edge) to block the regenerative

  61.                 migration of cells within the capsule, because the cells can quickly form a new cataract behind the

  62.                 plastic lens; those cataracts commonly form in reaction to the lens. The use of arsenic to kill these

  63.                 cells has been proposed, and probably used (Zhang, et al., 2010).&nbsp;</span>

  64.             <span>The easy money in lens surgery has obviously discouraged professional interest in preventing

  65.                 cataracts, or curing them, or stimulating the regeneration of new lenses. Research in the prevention of

  66.                 cataracts has encountered serious barriers to performing the clinical trials that would be necessary for

  67.                 approval.&nbsp;&nbsp; "… Clinicians have even developed the opinion that lens and cataract research is

  68.                 no longer necessary to overcome cataract blindness." (Sasaki, et al., 2000.) However, it isn't

  69.                 inconceivable that someone could find a way to make prevention, cure, or regeneration significantly

  70.                 remunerative.&nbsp;</span>

  71.             <span>Although the lens has no blood supply, fluid carrying nutrients and oxygen is constantly flowing

  72.                 through it, providing the cells with glucose, amino acids, and ATP, that it uses for maintaining its

  73.                 structure. Its proteins are being renewed continually, broken down and synthesized (Ozaki, et al.,

  74.                 1985). There is clear evidence that some of the core cells retain a nucleus, and that large molecules

  75.                 can move between cells (Lieska, et al., 1992; Shestopalov and Bassnett, 2000; Stewart, 2008; Mathias and

  76.                 Rae, 2004). Despite this evidence, prominent researchers are still promoting the paradigm of inertness,

  77.                 the lens as analogous to a toenail. As in other cells, ATP maintains the proper water content in the

  78.                 cells. Besides providing energy and amino acids, the circulating fluid carries minerals and many

  79.                 hormones and regulatory substances.&nbsp;</span>

  80.             <span>The absence of a blood supply to the lens has kept people from thinking of its pathology in terms of

  81.                 the inflammatory processes that are now recognized in other conditions, for example in dementia, heart

  82.                 disease, and cancer, but the same basic processes can be seen in the development of cataracts. Improved

  83.                 knowledge of lens physiology is very likely to lead to major improvements in therapies for the other

  84.                 conditions. In the lens, the state of water changes before there is any other evidence that a cataract

  85.                 is developing (Mori, 1993); detecting similar water changes in other tissues might improve diagnosis and

  86.                 treatment of other problems. Things that acutely lower the ATP content of cells increase their water

  87.                 content, and in the process, the water functions differently, becoming more randomly

  88.                 arranged.&nbsp;</span>

  89.             <span>The idea that the properties of water change as cell functions change contradicts the common

  90.                 reductionist assumption that water is just the medium in which molecular interactions occur. Since

  91.                 Kelvin's 1858 demonstration that the heat capacity of water changes with its shape, and Drost-Hansen's

  92.                 demonstrations that its density decreases near surfaces, attention to the physical properties of water

  93.                 has made it possible to understand many biological mysteries, such as the decrease of volume (Abbott and

  94.                 Baskin, 1962) when a nerve or muscle cell is excited. Although the invention of the MRI grew directly

  95.                 from Damadian's understanding of water's centrality to biology's most important issues, the technology's

  96.                 most important contributions, related to changes in water structure, haven't been recognized,

  97.                 understood, or assimilated by medicine.&nbsp;</span>

  98.             <span>The electrical properties of the protein framework of a cell interact with the state of the water in

  99.                 the cell, and with the things dissolved in the water, including phosphate, calcium, sodium, and

  100.                 potassium. Actin, one of the major muscle proteins, forms a meshwork in the cytoplasm of lens fiber

  101.                 cells, and myosin, the other major muscle protein, has been found in association with the actin

  102.                 (Al-Ghoul, et al., 2010). ATP (alternating with ADP+inorganic phosphate) is involved in muscle

  103.                 contraction and relaxation, and it is involved in the conversion of actin from a filament into a

  104.                 globular form. Changes in the amount of ATP and ADP are important for influencing the interactions of

  105.                 water and proteins.&nbsp;</span>

  106.             <span>The actin skeleton is involved in the fiber cell's elongation as it develops from a roundish

  107.                 epithelial cell, and it's probably responsible for the ability of lens cells to contract when stimulated

  108.                 (Oppitz, et al., 2003; Andjelica, et al., 2011). These muscle-like effects of actin are believed to be

  109.                 responsible for the movement of organelles and other cell motion, such as cytoplasmic streaming. But, as

  110.                 a major part of the cell's structure, it could also be expected to act as the framework for

  111.                 electroosmotic flow of water, accounting for the circulation that maintains the cell's energy. The

  112.                 observed static electrical properties of lens cell fragments could account for a complete daily renewal

  113.                 of the fluid (Pasquale, et al., 1990), but the metabolic gradients in whole cells would probably cause

  114.                 faster flow.&nbsp;</span>

  115.             <span>With oxidative energy production occurring in the surface cells, an electrical gradient will be

  116.                 created, causing water to flow away from the site of respiration. (Electroosmosis probably also accounts

  117.                 for the somewhat mysterious exit of water from the eyeball and brain, in perivascular flow.) The flow of

  118.                 water through these cells is very fast, but Ichiji Tasaki has demonstrated similarly fast movement of

  119.                 water in nerves and artificial polymers in association with electrical activity (2002; Tasaki and Iwasa,

  120.                 1981, 1982; Iwasa, et al., 1980).&nbsp;</span>

  121.             <span>At least since Gullstrand's unfounded assertions in his 1911 Nobel lecture, it has been assumed that

  122.                 the lens, like a water-filled balloon, keeps the same volume when it flattens, for distant focus.

  123.                 Zamudio, et al. (2008), have shown that "…the lens volume decreases as the lens flattens during

  124.                 unaccommodation." "The lens volume always decreases as the lens flattens." They determined that "…the

  125.                 changes in lens volume, as reflected by the speed of the equatorial diameter recovery in&nbsp;</span>

  126.             <em>in vitro&nbsp;</em>

  127.             <span>cow and rabbit lenses during simulated accommodation, occurred within a physiologically relevant time

  128.                 frame (200 ms), implying a rapid movement of fluid to and from the lens during accommodation." This is

  129.                 the duration of the action potential of healthy heart muscle, though it's probably not as fast as the

  130.                 very superficial changes that Tasaki saw in nerves. It's the sort of change rate that could be expected

  131.                 in an organ whose change of shape is the result of stimulation. Accommodation, with this immediate

  132.                 hydration, is produced by cholinergic stimulation, and in the healthy lens this hydration is rapidly

  133.                 reversible, as the stimulating acetylcholine disappears and the lens flattens.&nbsp;</span>

  134.             <span>The failing heart muscle, unable to relax fully, becomes harder as its water content increases, and

  135.                 cancer cells, locked into a contracted excited state, become stiffer as their water content increases.

  136.                 Similarly, cataracts have been described as more rigid than normal lens tissue (Heys and Truscott, 2008;

  137.                 Hu, et al., 2000), yet their water content is higher (Racz, et al., 2000). Along with the increased

  138.                 water, the stressed cells take up very large amounts of calcium, and sodium increases while potassium

  139.                 decreases. Inorganic phosphate increases in the stressed cells, some of it entering with the circulating

  140.                 fluid, but some of it produced from the ATP which is decreasing. Serotonin, iron, lipid peroxidation

  141.                 products, nitric oxide, and prostaglandin are also increased. The increased calcium activates

  142.                 proteolytic enzymes that break down protein.&nbsp;</span>

  143.             <span>In the failing heart and growing tumors, there is an increase in the quantity and the cross-linking of

  144.                 collagen in the extracellular matrix, contributing to the overall hardness, besides the contracted state

  145.                 of the cells themselves. In the cataract, cross-linking of various proteins, including collagen, also

  146.                 seems to be involved in the problem, along with the altered state of the water (Mishra, et al., 1997;

  147.                 Eldred, et al., 2011). The cross-linking enzyme transglutaminase is induced by stressors such as

  148.                 ultraviolet light which produce cataracts.&nbsp;</span>

  149.             <span>When the available energy doesn't meet the cell's energy requirements, if the cell isn't quickly

  150.                 killed by the stress it will use some adaptive mechanisms, stopping some repair processes to reduce

  151.                 energy expenditure, possibly stopping specialized functions to reduce energy needs. Fibrotic changes

  152.                 occur as a result of defensive reactions in stressed cells, usually following long periods of fatigue

  153.                 and inflammation. Cortisol generally protects cells by blocking over-stimulation and providing increased

  154.                 material for energy and repair, but it can kill cells (nerve cells and thymus cells) that depend on

  155.                 glucose oxidation, leading to immunodeficiency and excitotoxic brain damage. The glucose-dependent lens

  156.                 fiber cells express the same glucose transporters, GLUT1 and GLUT3, as the brain, and the "nerve

  157.                 specific" GLUT3 is concentrated in the dense nucleus of the lens (Donaldson, et al., 2003). Exposure to

  158.                 excessive cortisol or hypoglycemia is able to quickly produce cataracts, showing the basic importance of

  159.                 glucose metabolism for lens health.&nbsp;</span>

  160.             <span>Oxidative metabolism in the surface cells is probably largely responsible for the streaming of fluid

  161.                 through the fiber cells, providing some ATP and the nutrients that allow the fiber cells to maintain and

  162.                 repair their structure, but I suspect that local metabolism of glucose by the fiber cells provides most

  163.                 of the energy for keeping the protein-water system in its orderly relaxed state.&nbsp;</span>

  164.             <span>The aging lens, like all normal tissues, is drier, has a lower water content, than younger tissues,

  165.                 but when a cataract begins to develop, there is a sharp increase in the water content in that area,

  166.                 something that happens in any excited or fatigued tissue. (In a stimulated nerve or muscle, for example,

  167.                 although in a closed system there would be a slight decrease in volume as its water becomes relatively

  168.                 randomized, there is normally a sudden absorption of water from the extracellular space, where the water

  169.                 has the same random organization.) With the decreasing energy charge of the cell, represented by

  170.                 decreasing ATP and increasing ADP and inorganic phosphate, the long range order of the water decreases,

  171.                 changing the activity of enzymes in a variety of ways, for example by the exchange of a high magnesium

  172.                 content for a high calcium content. While the renewal of proteins decreases because of an energy

  173.                 deficit, the activation of proteolytic enzymes by calcium degrades the cell architecture and the

  174.                 crystallin that makes up about 90% of the cell's protein, and these damaged proteins become

  175.                 progressively cross-linked, in a process analogous to the cross-linking of collagen in sun-damaged skin,

  176.                 or in cancer or a fibrotic failing heart.&nbsp;</span>

  177.             <span>The diffusion of water in these congested cataract areas becomes random, more like ordinary bulk

  178.                 water, and it's likely that this randomization of the water, along with the architectural

  179.                 disorganization of proteins and changing electrical fields, impedes the longitudinal flow of nourishing

  180.                 fluid through the lens. MRI studies show relatively free diffusion of water longitudinally in the lens

  181.                 fiber cells from front to back, but not transversely (Moffat and Pope, 2002). Water that's highly

  182.                 ordered by nearby surfaces can still be very mobile parallel to the surface.&nbsp;</span>

  183.             <span>The parasympathetic nerve transmitter acetylcholine is formed in the lens, as well as its receptor and

  184.                 the enzyme which destroys it, cholinesterase. Chemicals that inhibit cholinesterase, and drugs that

  185.                 mimic the action of acetylcholine on the receptor, cause cataracts. These drugs (Michon and Kinoshita,

  186.                 1968; Harkonen and Tarkkanen, 1976) cause the lens to take up water, sodium, and calcium, and to lose

  187.                 potassium, and by increasing the cells' energy expenditure, they accelerate the consumption of glucose

  188.                 while blocking other metabolism. Since these are known effects of stimulation by acetylcholine, it's

  189.                 reasonable to assume that acetylcholine is involved in the natural formation of cataracts.&nbsp;</span>

  190.             <span>Besides the direct excitatory effects of acetylcholine, the increase of intracellular calcium and

  191.                 decrease of magnesium (Agarwal, et al., 2012) caused by it promote the synthesis of nitric oxide (which,

  192.                 for example, blocks the function of cytochrome oxidase, reducing the production of ATP), and the

  193.                 interference with glucose metabolism in itself is cataractogenic (Greiner, et al., 1981).&nbsp;</span>

  194.             <span>Ultraviolet light powerfully stimulates the formation of nitric oxide (Chaudhry, et al., 1993), and is

  195.                 one of the known causes of cataracts. Since the cornea is more directly exposed than the lens to the

  196.                 ultraviolet rays of sunlight, the effects of injury can be seen more quickly. Exposure of the cornea to

  197.                 ultraviolet light causes swelling, reduced transparency, and the formation of nitric oxide, which enters

  198.                 the aqueous humor (Cejka, et al., 2012; Cejkova, et al., 2005). Swelling in itself, regardless of the

  199.                 cause, decreases the transparency of the cornea (Stevenson, et al., 1983); anything interfering with its

  200.                 energy metabolism causes swelling.&nbsp;</span>

  201.             <span>The blue color of ordinary water is caused by its absorption of red light, possibly by its hydrogen

  202.                 bonds (Braun and Smirnov, 1993), but there haven't been many studies of the physical effects of red

  203.                 light on water itself. Since water absorbs much more strongly in the infrared wavelengths, there is a

  204.                 tendency to explain the benefits of sunlight by its infrared rays. Red and orange wavelengths penetrate

  205.                 tissue very effectively, because of their weaker absorption by water, allowing them to react with

  206.                 pigments in the cell, such as cytochrome oxidase, which is activated (or re-activated) by red light,

  207.                 increasing the production of ATP. This effect counteracts the toxic effects of ultraviolet light, but

  208.                 there are probably other mechanisms involved in the many beneficial effects of red light.&nbsp;</span>

  209.             <span>Recent work by a group at the University of Ulm in Germany (Andrei Sommer, et al., 2011) has revealed

  210.                 an effect of red light (670 nm) on water that I think helps to explain some of its protective and

  211.                 restorative actions. Shining laser light onto layers of water adsorbed on a solid surface, they were

  212.                 able to show "a breathing-like volume expansion of the topmost sheets of water molecules." They explain

  213.                 this as the result of a stabilization of a more ordered state of the hydrogen bonds of the water. They

  214.                 are applying this to chemotherapy, since the expansion of water in the cell where much of the water is

  215.                 in adsorbed layers similar to their experimental set-up, alternating with its volume contraction as the

  216.                 light is pulsed, causes water to move in and out of the cell quickly, taking some of the drug with it.

  217.                 They have also proposed that degenerative changes in the connective tissues involve a loss of ordered

  218.                 water, and have experimented with light treatments to restore elasticity and flexibility.&nbsp;</span>

  219.             <span>Since the water in cataracts is in a less ordered state than in the transparent lens, the re-ordering

  220.                 effect of red light could be valuable, and if the effects are the same as in their experiments with

  221.                 cancer cells, the increased volume of the re-ordered water would cause a movement of water out of the

  222.                 cataract, as it does in cancer cells in their experiment. And the known restorative effect of red light

  223.                 on oxidative production of ATP would almost certainly be helpful.&nbsp;</span>

  224.             <span>Among the popular medical treatments that are likely to contribute to the development of cataract are

  225.                 glucocorticoids, and drugs that increase serotonin (Dietze and Tilgner, 1973; Korsakova and Sergeeva,

  226.                 2010), and drugs that increase nitric oxide. Free fatty acids are toxic to the lens, which contains the

  227.                 enzymes for synthesizing prostaglandins and related promoters of inflammation; the products of lipid

  228.                 peroxidation are increased in people with cataracts. Endotoxin from the intestine increases the

  229.                 formation of nitric oxide, so it's essential to minimize intestinal inflammation.&nbsp;</span>

  230.             <span>High altitude very strongly protects against cataracts (Brilliant, et al., 1983). Low oxygen tension

  231.                 itself protects the lens's clarity (Akoyev, et al., 2009), possibly by the protective effect of

  232.                 increased carbon dioxide against glycation of protein amino groups. Aspirin's known anticataract effect

  233.                 apparently involves a similar protection of crystallin against glycation, but aspirin has several other

  234.                 protective effects, including prevention of protein cross-linking, and the inhibition of the synthesis

  235.                 of nitric oxide and prostaglandins and other disruptive materials (Crabbe, 1998; Beachy, et al., 1987;

  236.                 Lonchampt, et al., 1983). Progesterone's inhibition of nitric oxide production is probably protective

  237.                 for the lens, paralleling its effects in other organs. Inhibitors of nitric oxide, such as

  238.                 aminoguanidine, are protective. Anticholinergics, including atropine, inhibit over-hydration of the lens

  239.                 and prevent cataracts caused by excessive cholinergic stimulation (e.g., Kaufman, et al., 1977).

  240.                 Caffeine, in animal experiments, prevents cataracts. Uric acid, which inhibits nitric oxide formation,

  241.                 is reduced in people with cataracts. The factors that prevent or promote other degenerative diseases are

  242.                 similarly protective or harmful for the lens.</span>

  243.             <span><h3>REFERENCES</h3></span>

  244.             <span>J Physiology 1962; 161, 379-391. Volume changes in frog muscle during contraction. Abbott C &amp;

  245.                 Baskin RJ.</span>

  246.             <span>Exp Eye Res. 2012 Aug;101:82-9. Magnesium deficiency: does it have a role to play in cataractogenesis?

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  248.             <span>Invest Ophthalmol Vis Sci. 2009 Mar;50(3):1271-82. Hypoxia-regulated activity of PKCepsilon in the

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  250.             <span>Anat Rec (Hoboken). 2010 Nov;293(11):1805-15. A novel terminal web-like structure in cortical lens

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  282.                 Thanos S.</span>

  283.             <span>Invest Ophthalmol Vis Sci. 1981 Nov;21(5):700-13. Organophosphates of the crystalline lens: a nuclear

  284.                 magnetic resonance spectroscopic study. Greiner JV, Kopp SJ, Sanders DR, Glonek T.</span>

  285.             <span>Acta Ophthalmol (Copenh). 1976 Aug;54(4):445-55. Effects of phospholine iodide on the metabolites of

  286.                 the glycolytic, pentose phosphate and sorbitol pathways in the rabbit lens. Harkonen M, Tarkkanen

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