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Oxidative Stress and Inflammation Are Associated With Age-Related Endothelial Dysfunction in Men With Low Testosterone.
Babcock, MC, DuBose, LE, Witten, TL, Stauffer, BL, Hildreth, KL, Schwartz, RS, Kohrt, WM, Moreau, KL
The Journal of clinical endocrinology and metabolism. 2022;107(2):e500-e514
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Serum testosterone declines gradually with age at a rate of ~1% per year after the third decade. Vascular aging, featuring endothelial dysfunction mediated by oxidative stress and inflammation, is a major risk factor for the development of age-associated cardiovascular disease (CVD). The aim of this study was to examine the effects of low testosterone on cardiovascular aging in men. This study is a cross-sectional study which recruited 58 healthy men of all races/ethnic backgrounds aged 50-75 years (middle-aged/older) and 18-40 years (young). Results show that middle-aged/older men with lower testosterone have evidence of “accelerated” vascular aging, as indicated by a greater age-associated endothelial dysfunction of large arteries compared with their age-matched peers. The greater macrovascular endothelial dysfunction in middle-aged/older men with chronically low testosterone was independent of CVD risk factors or symptoms of androgen deficiency. Furthermore, increased systemic oxidative stress and inflammation are mechanistically linked to the greater age-associated endothelial dysfunction in middle-aged/older men with lower testosterone. Authors conclude that normal physiological levels of testosterone may be beneficial to cardiovascular health by attenuating the age-related decline in endothelial function.
Abstract
CONTEXT Vascular aging, including endothelial dysfunction secondary to oxidative stress and inflammation, increases the risk for age-associated cardiovascular disease (CVD). Low testosterone in middle-aged/older men is associated with increased CVD risk. OBJECTIVE We hypothesized that low testosterone contributes to age-associated endothelial dysfunction, related in part to greater oxidative stress and inflammation. METHODS This cross-sectional study included 58 healthy, nonsmoking men categorized as young (N = 20; age 29 ± 4 years; testosterone 500 ± 58 ng/dL), middle-aged/older with higher testosterone (N = 20; age 60 ± 6 years; testosterone 512 ± 115 ng/dL), and middle-aged/older lower testosterone (N = 18; age 59 ± 8 years; testosterone 269 ± 48 ng/dL). Brachial artery flow-mediated dilation (FMDBA) was measured during acute infusion of saline (control) and vitamin C (antioxidant). Markers of oxidative stress (total antioxidant status and oxidized low-density lipoprotein cholesterol), inflammation (interleukin [IL]-6 and C-reactive protein [CRP]), and androgen deficiency symptoms were also examined. RESULTS During saline, FMDBA was reduced in middle-aged/older compared with young, regardless of testosterone status (P < 0.001). FMDBA was reduced in middle-aged/older lower testosterone (3.7% ± 2.0%) compared with middle-aged/older higher testosterone (5.7% ± 2.2%; P = 0.021), independent of symptoms. Vitamin C increased FMDBA (to 5.3% ± 1.6%; P = 0.022) in middle-aged/older lower testosterone but had no effect in young (P = 0.992) or middle-aged/older higher testosterone (P = 0.250). FMDBA correlated with serum testosterone (r = 0.45; P < 0.001), IL-6 (r = -0.41; P = 0.002), and CRP (r = -0.28; P = 0.041). CONCLUSION Healthy middle-aged/older men with low testosterone appear to have greater age-associated endothelial dysfunction, related in part to greater oxidative stress and inflammation. These data suggest that low testosterone concentrations may contribute to accelerated vascular aging in men.
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Glucotypes reveal new patterns of glucose dysregulation.
Hall, H, Perelman, D, Breschi, A, Limcaoco, P, Kellogg, R, McLaughlin, T, Snyder, M
PLoS biology. 2018;16(7):e2005143
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One in 10 individuals is affected by diabetes, a condition involving abnormal regulation of blood glucose. Currently, diabetes is assessed using single-time or average measurements of blood glucose, without consideration for how blood glucose fluctuates over time. This study used continuous glucose monitoring (CGM) technology to evaluate how blood glucose fluctuates in individuals over time. The authors found that many individuals considered nondiabetic by standard measures experienced frequent elevations in blood glucose levels into the pre-diabetic or diabetic range (15% and 2% of the time, respectively). The authors developed a model for determining the “glucotype” (low, moderate or severe variability) of an individual, a more comprehensive measure of glucose patterns than the standard tests currently used. The authors argue that CGM should become an important tool in early identification of those at risk for type 2 diabetes.
Abstract
Diabetes is an increasing problem worldwide; almost 30 million people, nearly 10% of the population, in the United States are diagnosed with diabetes. Another 84 million are prediabetic, and without intervention, up to 70% of these individuals may progress to type 2 diabetes. Current methods for quantifying blood glucose dysregulation in diabetes and prediabetes are limited by reliance on single-time-point measurements or on average measures of overall glycemia and neglect glucose dynamics. We have used continuous glucose monitoring (CGM) to evaluate the frequency with which individuals demonstrate elevations in postprandial glucose, the types of patterns, and how patterns vary between individuals given an identical nutrient challenge. Measurement of insulin resistance and secretion highlights the fact that the physiology underlying dysglycemia is highly variable between individuals. We developed an analytical framework that can group individuals according to specific patterns of glycemic responses called "glucotypes" that reveal heterogeneity, or subphenotypes, within traditional diagnostic categories of glucose regulation. Importantly, we found that even individuals considered normoglycemic by standard measures exhibit high glucose variability using CGM, with glucose levels reaching prediabetic and diabetic ranges 15% and 2% of the time, respectively. We thus show that glucose dysregulation, as characterized by CGM, is more prevalent and heterogeneous than previously thought and can affect individuals considered normoglycemic by standard measures, and specific patterns of glycemic responses reflect variable underlying physiology. The interindividual variability in glycemic responses to standardized meals also highlights the personal nature of glucose regulation. Through extensive phenotyping, we developed a model for identifying potential mechanisms of personal glucose dysregulation and built a webtool for visualizing a user-uploaded CGM profile and classifying individualized glucose patterns into glucotypes.
3.
Fructose metabolism and metabolic disease.
Hannou, SA, Haslam, DE, McKeown, NM, Herman, MA
The Journal of clinical investigation. 2018;128(2):545-555
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Sugar consumption is thought to be a contributing factor in the increase in diabetes and obesity and the associated risk of cardiovascular disease worldwide. Sucrose (table sugar) and high fructose corn syrup contain almost equal amounts of fructose and glucose and are commonly added to processed foods. Whilst long-term studies are lacking, some short-term intervention studies show that fructose can impair lipid metabolism and insulin sensitivity in humans. This article reviews the biochemistry and molecular genetics of fructose metabolism as well as potential mechanisms by which excessive fructose consumption contributes to cardiometabolic disease. Fructose absorption in the human intestine is saturable, and there is a large range in capacity to absorb fructose between individuals, and unabsorbed fructose may contribute to gastrointestinal symptoms including pain and bloating. Fructose concentrations in the blood can increase 10-fold after consumption, but are rapidly cleared, mostly by the liver, where it provides substrate for metabolic processes, but may also be involved in signalling functions. Fructose may enhance glucose uptake by the liver and storage as glycogen and lipids. It may also increase production of uric acid which is implicated with gout. Excessive fructose consumption affects lipid metabolism and may contribute to fat accumulation in the liver and increase circulating triglycerides, a risk factor for heart disease. In animal models it also induces increased insulin levels. Fructose is one of the sweetest sugars which may affect appetite and overeating. It may also induce addiction-like behaviours such as binging and dependence in part by stimulating dopaminergic pathways. It also appears to induce leptin resistance which further increases food intake and obesity.
Abstract
Increased sugar consumption is increasingly considered to be a contributor to the worldwide epidemics of obesity and diabetes and their associated cardiometabolic risks. As a result of its unique metabolic properties, the fructose component of sugar may be particularly harmful. Diets high in fructose can rapidly produce all of the key features of the metabolic syndrome. Here we review the biology of fructose metabolism as well as potential mechanisms by which excessive fructose consumption may contribute to cardiometabolic disease.