• Improvement in insulin resistance [ Time Frame: 01/03/2010 ] [ Designated as safety issue: No ]
  

• Improvement in endothelial dysfunction [ Time Frame: 01/03/2010 ] [ Designated as safety issue: No ]
  

Drug: Epigallocatechin Gallate (EGCG)
N/A

Green tea is a functional food whose consumption is associated with improved cardiovascular morbidity and mortality in several large epidemiological studies. One third of the solids in green tea are composed of the bioactive polyphenol epigallocatechin 3-gallate (EGCG). Studies in both cell- and animal-based models (from our lab and elsewhere) suggest that EGCG may mimic and/or augment beneficial metabolic, vascular, and anti-inflammatory actions of insulin. Indeed, we have recently shown that 3-week EGCG therapy of SHR rats (genetic model of hypertension with features of human metabolic syndrome including insulin resistance, hyperinsulinemia, endothelial dysfunction, and overweight) lowers blood pressure, improves endothelial dysfunction, increases insulin sensitivity, and raises adiponectin levels nearly as effectively as treatment with the conventional ACE-inhibitor enalapril. Obesity, type 2 diabetes, and hypertension are all important interrelated public health problems that are characterized by reciprocal relationships between insulin resistance and endothelial dysfunction. Thus, therapies for these diseases that improve insulin resistance often simultaneously improve endothelial function and vice versa. Based on results from cellular, physiological, and epidemiological studies, we hypothesize that oral EGCG administration will simultaneously ameliorate insulin resistance and lower blood pressure in human subjects with obesity, essential hypertension, or type 2 diabetes. To test these hypotheses, we will conduct a randomized, placebo-controlled, double-blind, cross-over study to evaluate potential beneficial effects of EGCG to modulate insulin sensitivity, blood pressure, vascular function, and inflammatory markers in four groups of subjects (lean healthy controls, obesity, essential hypertension, or type 2 diabetes). After a 2-week EGCG-free run-in period, each subject will be randomized to receive EGCG or placebo capsules (400 mg p.o. B.I.D.) for 4 weeks. This will be followed by a 2-week EGCG-free washout period after which subjects will cross-over to the other treatment arm. At baseline, and after each 4-week treatment period, we will assess insulin sensitivity (hyperinsulinemic isoglycemic glucose clamp technique) and vascular function. Regarding vascular function, we will measure basal and insulin-stimulated brachial artery blood flow (large conduit artery assessed by Doppler ultrasound) as well as capillary recruitment in forearm skeletal muscle (small nutritive arterioles assessed by ultrasound with microbubble contrast). Blood pressure will be measured weekly in the NIH CRC throughout the duration of the study. EGCG pharmacokinetics will be measured at the beginning of each glucose clamp study day after oral administration of a single dose of EGCG or placebo. Finally, various plasma markers of inflammation will be measured at baseline and at the end of each treatment arm to evaluate potential changes that may be related to improvements in metabolic and/or vascular function. This study will explore whether EGCG, a single compound thought to be a major bioactive component of green tea, is effective at improving insulin resistance and lowering blood pressure in subjects with obesity, hypertension, or diabetes. Results from this study may have important implications for understanding potential health benefits of functional foods that contain bioactive polyphenols including green tea, dark chocolate, and red wine.