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OVERVIEW OF ADVANCED GLYCATION END-PRODUCTS
(AGES)Part 4
Supplements: Improve AGEs Effects Alpha-Lipoic Acid
Effective inhibitor of AGE formation in diabetes Limited to animal studies More favorable supplement to consider
N-Acetylcysteine (NAC) Antioxidant precursor to a natural antioxidant ,
glutathione, known to be depleted in diabetic patients
Findings by De Mattia et al. demonstrated reductions in pro-atherosclerotic vascular adhesion molecules from NAC supplementation in Type 2 diabetics
Supplements: Improve AGEs Effects Benfotiamine
Lipophillic derivative of the B-vitamin thiamine May prevent inflammation caused by AGE
intake by shunting glycolytic intermediates to the reductive pentose pathway
Findings by Stirban et al. demonstrated that the administration of 1050 mg of benfotiamine per day to Type 2 diabetic patients: Reduced inflammatory markers Improved circulations Reduced pro-atherosclerotic adhesion molecules
Supplements: Improve AGEs Effects L-Carnosine
Scientific reviews suggest: Carnosine is a potent inhibitor of the formation
of AGE products Has therapeutic potential in diabetes and
diabetic complications Clinical studies are non-existent in U.S.
literature Impossible to recommend a dose Lack of studies in humans make it difficult to
determine the safety of carnosine
Supplements: Improve AGEs Effects Vitamin C and Vitamin E
Preliminary animal research suggests a combination of vitamin C and vitamin E may prevent AGE product formation
Findings by Konen et al. supplemented 22 diabetic patients with vitamin C and vitamin E for one year and did not observe a reduction in AGE content of skin samples
Pharmacological Agents Under Investigation Specifically Aiming at AGEs AGE Breakers (4,5- dimethyl-3
phenacylthiazolium, also known ALT-711) Break AGE protein-protein crosslinks in vitro Improve arterial compliance in a phase 2
clinical trial in the elderly Inhibitor of AGEs (Aminoguandine)
Hydrazine compound that prevents AGE formation by reacting mostly with derivatives of early glycation products that are not bound to proteins
Also NOS inhibitor
Pharmacological Agents Under Investigation Specifically Aiming at AGEs
Findings by Bolton et al. in a placebo controlled, randomized trial in Type 1 diabetic patients demonstrated: Slower reduction in glomerular filtration rate Reduced 24-hour urinary proteinuria and
progression of retinopathy Did not attenuate the time to doubling of serum
creatinine
“More Common” Pharmacological Agents that May Reduce AGE Accumulation Antihypertensives (Angiotensin Converting
Enzyme (ACE) Inhibitors and Angiotensin Receptor Blockers) Reduce AGE accumulation in concert with the
severity of diabetic nephropathy Antihyperglycemic (Metformin)
Diamino biguanide compound that may decrease AGE accumulation by reducing methylglyoxal levels
A scavenger of reactive oxygen species, reducing oxidative stress
Treatment improves endothelial function in Type 2 diabetic patients
Metabolic Activation Therapy (MAT) Role in Diabetic Patients Metabolic Activation Therapy (MAT)
Patented procedure developed by Dr. Thomas T. Aoki Chronic therapy to stop the advancement of diabetic
complications or to control A1c values when all other therapeutic options have failed
Does not reverse tissue damage that has already occurred due to progression of the disease
Activate the cells in the liver and elsewhere to synthesize glucokinase and other insulin-dependent enzymes with the delivery of insulin at a target level equal to that of a non-diabetic person, 200-1,000 microU/mL
Metabolic Activation Therapy (MAT) Role in Diabetic Patients Higher level at the portal vein in conjunction with
the pulsatile fashion, 10 pulses per hour Mimics the body's first phase of insulin secretion Enhances the liver’s processing of glucose or
activating it to maintain metabolic homeostasis, resulting in other tissues and organs being affected
Glucose is recognized as an alternate source of energy and its uses less oxygen for its utilization
Allowing tissues with decreased circulation to function with less demand for oxygen, resulting in normal functioning, damage repair, and healing
Conclusion
The formation of advanced glycation end-products (AGEs) is a contributing factor in complications found in diabetic patients.
AGE formation in diabetic patients occurs as a consequence to chronically elevated blood glucose levels.
Primary sources of AGEs should be avoided or limited if possible.
Dietary intake of AGEs affect blood vessel inflammation and oxidation of “bad” cholesterol, leading to increased atherosclerosis.
Dietary modifications are strongly recommended to reducing AGEs effects in all patients.
Conclusion
Supplements may be beneficial to improving or preventing the effects of AGE products in diabetic patients; however, studies are limited by small sample size of humans, only animal studies, or lack of studies altogether.
The investigation of pharmacological agents specifically aiming at AGEs: AGE breakers and inhibitors.
Common pharmacological agents that may reduce AGE accumulation: antihypertensives (ACEIs and ARBs) and metformin.
Metabolic Activation Therapy (MAT) may have its advantage in reducing the effects of AGEs by allowing tissues with decreased circulation to function with less demand for oxygen, resulting in normal functioning, damage repair, and healing through the activation of the diabetic patient’s metabolism by directly burning glucose.
References
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