Lipoic Acid Reverses Mitochondrial DecayAugust 2011
By Michael Anderson
It is estimated that 85% of the oxygen contained in every breath you take is consumed by the mitochondria within each cell of your body.1
The decay of these energy-producing powerhouses in turn lies at the core of most age-related pathologies.
In experimental models examining the mitochondrial theory of aging, it has been shown that cells microinjected with mitochondria isolated from old animals degenerate far more rapidly than those microinjected with mitochondria from young animals.2
The good news is that when supplied with a nutrient regimen that includes lipoic acid, a profound regeneration is observed in similar animal models,3 including improved metabolic function and a marked decline in oxidative stress.
In this article, the recent data on lipoic acid’s multimodal power to combat a host of age-related diseases is detailed. You will learn how it may help prevent cardiovascular disease, obesity, diabetes, neurodegenerative disorders, and cancer. You will also learn of drug company efforts to produce high-cost, synthetic forms of lipoic acid to capitalize on its unique health-promoting properties at your expense.
How Lipoic Acid Combats Cellular Degeneration
Lipoic acid is a vital “co-factor” for enzymatic reactions within the mitochondria, helping to optimize energy conversion.9,10 It possesses unique properties that specifically slow mitochondrial aging by preventing release of mutagenic oxidants.11 Recent research further reveals lipoic acid’s ability to alleviate mitochondrial dysfunction in aging cells (thus improving mitochondrial function).12,13
Researchers have further discovered that lipoic acid enhances the effects of insulin, benefitting glucose metabolism and lowering blood sugar levels.10
This in turn mitigates the pathologic cross-linking of glucose and protein that result in advanced glycation end products (AGEs).14
These advanced glycation end products have been shown to accelerate the onset of cardiovascular disease, brain degeneration, ocular disorders, and cancer.14-17
Lipoic acid also suppresses production of inflammatory cell-signaling molecules, while increasing production of molecules involved in vascular tone, such as endothelial nitric oxide synthase (eNOS).18,19
Owing to its pronounced power to combat mitochondrial aging, behemoth pharmaceutical companies are now attempting to manipulate its molecular structure and render it patentable.20 Such drugs include more complex molecules in which lipoic acid is “conjugated,” or chemically joined, to form hybrid compounds with additional biological characteristics.
This would allow drug manufacturers to make absurd claims of superior benefit for their artificial, synthetic lipoic acid products. The result would be needless additional cost for what is already a proven multi-modal nutrient.
Lipoic acid in the biologically active “R” form (see below) is readily available without a prescription and affordable.
Lipoic acid’s powerful antioxidant, anti-inflammatory, and lipid-lowering capabilities make it an ideal, multi-targeted nutrient for reducing cardiovascular risk.23,24 Lipoic acid helps protect the endothelium, the delicate, one-cell-thick lining of blood vessels. Additionally, lipoic acid improves blood vessels’ ability to relax, helping to lower blood pressure, improve blood flow, and reduce risk for cardiovascular events such as heart attack and stroke.25-28 Better blood flow in legs can also mean reduced pain with prolonged walking or other exercise.29
Cardiac surgeons are now beginning to recommend lipoic acid, along with other antioxidants such as CoQ10, prior to surgery in order to protect delicate blood vessels during surgery. Improved physical and mental quality of life in such patients has been reported to last for more than a month after the surgery.30
You can use lipoic acid to help lower your risk for cardiovascular disease long before you need cardiac surgery, though. Lipoic acid lowers total cholesterol and low-density lipoprotein (LDL) levels and reduces the size and number of atherosclerotic plaques, the dangerous points of arterial narrowing that produce heart attacks and strokes.23,24,28,31 In addition, lipoic acid may also lower levels of certain cellular toxins that contribute to cardiovascular diseases, especially those related to diabetes.32,33
Even people with pre-existing heart disease can benefit from lipoic acid. Cardiac stents, intended to improve blood flow following a heart attack, can become blocked by formation of unwanted new tissue, an effect that is prevented by lipoic acid supplementation.34 And, lipoic acid prevents death of heart cells exposed to high blood sugar levels, a contributor to diabetic heart disease.35
Lipoic acid has beneficial effects on the forces that cause us to gain weight and store excess fat. It works on brain areas to reduce appetite, food intake, and body weight.36-39 Lipoic acid also stimulates increased energy expenditure, burning excess calories by activating cellular energy signaling complexes.13,36
Overweight and obese people lose their normal sensitivity to insulin, resulting in ever-higher levels of blood sugar and advanced glycation end product–induced tissue damage. Lipoic acid improves insulin sensitivity and stimulates sugar uptake from the blood to help normalize sugar levels.40-43 In the liver, lipoic acid decreases fat production and accumulation, helping to prevent development of dangerous non-alcoholic fatty liver disease (NAFLD).44,45
Lipoic acid has been successfully used in patients taking medications that stimulate weight gain, such as antipsychotic drugs.46 Even in people who are only overweight (not yet obese), lipoic acid reduced body weight by 8% while shrinking waist size by more than 2 inches.47 In patients who are already obese, there was a 9% loss of weight and a decrease in waist size of more than 3 inches.47
Lipoic acid has an important role in managing diabetes, particularly the massive oxidative and inflammatory changes the disease produces.48,49 The benefits of lipoic acid include promoting insulin sensitivity and glucose uptake.50-52 Diabetics are at increased risk for the kinds of cardiovascular problems that lipoic acid can prevent, including accumulation of cellular toxins.32,53 By protecting against endothelial damage, lipoic acid reduces the threat of diabetic vascular and kidney complications.26,54
Lipoic acid is proving to be especially effective at preventing the painful and debilitating condition known as diabetic neuropathy, an almost inevitable complication in people with poor blood sugar control.55 Diabetic neuropathy begins with pain, burning, and/or stabbing sensations in the extremities.56 In more advanced stages of this condition, the pain disappears as severe damage is done to microscopic blood vessels. Ultimately the loss of nerve function can lead to open sores, infections, and even amputations. Despite considerable knowledge about how diabetic neuropathy arises, no drug treatment has yet proved effective in preventing or reversing the condition.56
Lipoic acid’s powerful antioxidant actions limit damage to the lining and blood supply of nerves, helping to reduce both symptoms and nerve dysfunction.57 Clinical studies have uniformly demonstrated improvements in pain, numbness, and stinging, while also improving nerve conduction velocity, a measure of how efficiently nerves transmit electrical impulses.58-61 Studies have shown that lipoic acid produces significant improvements when administered for 3 weeks, and longer studies have shown sustained effects.62,63 Lipoic acid also has beneficial effects on circulation in patients with diabetic neuropathy, improving blood flow and the amount of blood reserve available during high demand.64
It’s essential to start early with optimal levels of lipoic acid to prevent diabetic neuropathy. People with good blood sugar control and younger patients do better, as do women, and thinner patients in general.58 While doses of up to 1,800 mg/day are well-tolerated, 600 mg/day of alpha-lipoic acid seems to produce the best results in those with diabetes.59 This translates into a 300 mg dose of R-lipoic acid to obtain the same biological activity.21,22
Protection from Brain Cell Degeneration
Lipoic acid protects brain tissue from the long-term effects of advanced glycation end products and the resulting inflammation and oxidative damage, conditions that lead to neurodegenerative diseases like Alzheimer’s disease.9,65,66 A hallmark of Alzheimer’s disease is the formation of an abnormal protein called amyloid-beta, the result of chronic inflammation and a producer of increased oxidative stress. Lipoic acid reduces amyloid-beta-induced inflammation and improves brain cells’ production of the chemical signaling molecules called neurotransmitters.67,68 Mitochondrial function is significantly impaired in the brains of Alzheimer’s and Parkinson’s disease patients and lipoic acid decreases mitochondrial oxidant stress in those cells.69,70
These effects work together with other nutrients like acetyl-L-carnitine, docosahexaenoic acid (DHA), phosphatidylserine (PS), and glyceryl-phosphoryl-choline (GPC) to improve cognitive performance.71 Research has shown that lipoic acid prevents cell death in the brain regions most affected in Parkinson’s disease.72 These findings are both good news and important reminders of the need to incorporate lipoic acid early, before symptoms progress in these chronic, debilitating diseases. Lipoic acid may also have an important role in preventing the immune over-response that causes multiple sclerosis, another chronic, progressive brain disease.73-81
By increasing antioxidant capacity, scavenging free radicals, reducing lipid peroxidation, and enhancing energy utilization, lipoic acid may also minimize the damage produced by brain trauma.82 Lipoic acid has shown benefit in preventing trauma-related injuries to the brain, spinal cord, and even peripheral nerves, all of which are vulnerable following a major accident.83-85
Cancer scientists are growing increasingly interested in lipoic acid because cancer cells offer many targets for its anti-inflammatory attributes.86 These attributes allow lipoic acid to intervene at multiple points in the chain of carcinogenesis.86,87 In experimental studies, lipoic acid shows promise against cancers of the blood (leukemia), lung, breast, and liver.88-93 Preliminary research indicates that lipoic acid acts to halt the cell reproductive cycle of cancer cells, slowing or stopping tumor growth.88,89 Lipoic acid may also help induce apoptosis, the programmed cell death that is the body’s natural control mechanism for weeding out nascent cancers.88-93 Lipoic acid also protects against chemical-induced DNA damage that can lead to cancerous transformation.94 Lipoic acid may help prevent metastatic cancer spread by reducing activity of enzymes that tumors use to invade tissues.93 Finally, in those unfortunate enough to require chemotherapy to treat an existing cancer, lipoic acid can afford powerful protection against some of the side effects, such as diarrhea, intestinal cramping, and ulcers, thanks to its antioxidant capabilities.87
Cells with mitochondria isolated from old animals degenerate far more rapidly than those with mitochondria from young animals, revealing the importance of healthy mitochondria to delay the aging process. When supplied with a nutrient regimen that includes lipoic acid, a profound regenerative effect is observed, including improved metabolic function and significant declines in oxidative stress.
Recent data reveal that lipoic acid specifically targets factors that contribute to mitochondrial aging, dysfunction, and cell death. Lipoic acid can prevent and even mitigate cardiovascular diseases, obesity, insulin resistance, and complications of diabetes. Lipoic acid protects against nerve and brain cell damage induced by aging and trauma.
New evidence suggests that lipoic acid may also have important cancer-preventive effects, even against some of the most difficult-to-treat malignancies.
If you have any questions on the scientific content of this article, please call a Life Extension® Health Advisor at
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