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УЖМБС 2020, 5(5): 324–331
https://doi.org/10.26693/jmbs05.05.324
Biology

Effect of Exercise on Intestinal Microbium and Insulin Resistance in Person with Metabolic Syndrome

Hurenko O. O., Drozdovska S. B.
Abstract

Metabolic syndrome is a cluster of cardiometabolic risk factors. They include obesity, dyslipidemia, hypertension, and insulin resistance. Central obesity and resistance to insulin, in particular, are recognized as causative factors, which form the development of metabolic syndrome. Metabolic syndrome is a progressive and genetically determined condition. The result of its progression is that carbohydrate, lipid and purine metabolism break down. The intestinal microbiome has a significant role in the pathogenesis of metabolic syndrome. One of the methods of influencing the micribiotic composition is the physical activity. The human intestinal microbiome is a complex ecosystem consisting not only of microorganisms, but also including bacteria, archaea, fungi and viruses. Biodiversity and the overall composition of the microbiota play a crucial role in maintaining normal homeostasis in the human body. With the recent advent of the possibility of studying the intestinal microbiome, the impact on its taxonomic composition and metabolism through exercise is the subject of scientific interest. Recent studies showed that the intestinal microbiota was directly involved in the formation of the metabolic syndrome. The function of the microbiome is just as important as the function of the "metabolic organs" that affect energy homeostasis and control body weight. In addition, changes in the intestinal microbiotic composition lead to increased intestinal permeability, endotoxemia, which plays a role in the development of chronic inflammation in the host, contributing to the development of metabolic syndrome and related chronic metabolic diseases. Intestinal microbiota in its own right is injected into the development of systemic inflammation in obesity, such a rank, inappropriate insertions in development or regression of insulin resistance, and hyperglycemia in metabolic syndrome. Physical activity can affect not only the composition of the microbial composition, but also the metabolic activity of the intestinal microbiome. The health-improving effect of physical exercises is connected with their ability to change the composition of an intestinal microbiota. Studies involving professional athletes and a specially selected control group indicated that athletes had a lower pro-inflammatory status and a high degree of bacterial diversity. Due to this, there is a positive dynamics of improving carbohydrate metabolism and the impact on the course of pathological processes associated with the metabolic syndrome, through the introduction of regular physical activity. Conclusion. The literature review presents data on the metabolic syndrome, its pathogenesis and components of the spectrum of development of metabolic disorders. We also analyzed material on influence of gut microbiota on development of metabolic disturbances and inreraction of structure of a microbiotic composition with physical exercises

Keywords: microbiome, metabolic syndrome, insulin resistance, physical activity, obesity

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