1.
Role of gut microbiota in cardiovascular diseases.
Novakovic, M, Rout, A, Kingsley, T, Kirchoff, R, Singh, A, Verma, V, Kant, R, Chaudhary, R
World journal of cardiology. 2020;12(4):110-122
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Cardiovascular disease (CVD) is the leading cause of death globally. CVD risk factors such as aging, obesity, dietary patterns and a sedentary lifestyle induce changes in the gut microbiota. The resulting dysbiosis is associated with intestinal inflammation leading to reduced integrity of the gut barrier. When this happens, certain components enter the circulation which may facilitate the development of CVD. Looking at the gut microbiota as a locus of intervention is therefore a novel and relevant avenue for future research. This article reviews the normal function and composition of the gut microbiome, the mechanisms leading to reduced gut barrier integrity (leaky gut syndrome), its link to CVD and potential novel therapeutic approaches aimed towards restoring gut microbiome and CVD prevention. The alteration of the gut microbiome is a potential therapeutic target in managing CVD. However, further experiments are needed to see if the effects observed in animal studies can be translated to humans.
Abstract
The human gut is colonized by a community of microbiota, primarily bacteria, that exist in a symbiotic relationship with the host. Intestinal microbiota-host interactions play a critical role in the regulation of human physiology. Deleterious changes to the composition of gut microbiota, referred to as gut dysbiosis, has been linked to the development and progression of numerous diseases, including cardiovascular disease (CVD). Imbalances in host-microbial interaction impair homeostatic mechanisms that regulate health and can activate multiple pathways leading to CVD risk factor progression. Most CVD risk factors, including aging, obesity, dietary patterns, and a sedentary lifestyle, have been shown to induce gut dysbiosis. Dysbiosis is associated with intestinal inflammation and reduced integrity of the gut barrier, which in turn increases circulating levels of bacterial structural components and microbial metabolites, including trimethylamine-N-oxide and short-chain fatty acids, that may facilitate the development of CVD. This article reviews the normal function and composition of the gut microbiome, mechanisms leading to the leaky gut syndrome, its mechanistic link to CVD and potential novel therapeutic approaches aimed towards restoring gut microbiome and CVD prevention. As CVD is the leading cause of deaths globally, investigating the gut microbiota as a locus of intervention presents a novel and clinically relevant avenue for future research.
2.
Pilot Study of Novel Intermittent Fasting Effects on Metabolomic and Trimethylamine N-oxide Changes During 24-hour Water-Only Fasting in the FEELGOOD Trial.
Washburn, RL, Cox, JE, Muhlestein, JB, May, HT, Carlquist, JF, Le, VT, Anderson, JL, Horne, BD
Nutrients. 2019;11(2)
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Intermittent fasting – the practice of significantly cutting food intake on a number of days and eating normally on others – has been connected with numerous health benefits such as weight loss, reduced risk of heart disease and Type 2 diabetes, longer life span and improved quality of life. This randomised, cross over trial of 30 healthy individuals sought to evaluate the effects of fasting on Trimethylamine N-oxide (TMAO) levels, a substance produced in humans by intestinal bacteria and associated with heart disease in humans. 74 other metabolites were also measured. Subjects were randomised to a ‘fasting first’ group, with water-only intake for 24 hours, followed by 24 hours of eating freely, or an ‘eating first’ group, before crossing over. Measurements were made at baseline, at the end of the fasting day and at the end of the eating day. The authors found that TMAO levels decreased on the fasting day compared to the eating day. These levels returned to pre-fasting levels within 24 hours. 30 of the other 74 metabolic markers, including some amino acids and fatty acids, achieved significant changes between fasting and eating days. The authors suggest that consistent and repeated episodes of intermittent fasting may lead to improved health and reduced risk of heart disease and diabetes. Nutrition Practitioners may wish to consider intermittent fasting when working with clients with these conditions.
Abstract
Intermittent fasting (IF) has been connected with health benefits such as weight loss, lower risk of coronary artery disease (CAD) and diabetes, increased longevity, and improved quality of life. However, the mechanisms of these IF benefits in humans require further investigation. This study sought to elucidate some of these mechanisms through secondary analyses of the Fasting and ExprEssion of Longevity Genes during fOOD abstinence (FEELGOOD) trial, in which apparently healthy participants were randomized in a Latin square design to a 24-h water-only fast and a 24-h ad libitum fed day. Two pathways were investigated, with trimethylamine N-oxide (TMAO) levels measured due to their association with elevated risk of CAD, along with conductance of a broad panel of metabolic analytes. Measurements were made at baseline, at the end of the fasting day, and at the end of the fed day. A fasting mean of 14.3 ng in TMAO was found versus the baseline mean of 27.1 ng with p = 0.019, although TMAO levels returned to baseline on refeeding. Further, acute alterations in levels of proline, tyrosine, galactitol, and urea plasma levels were observed along with changes in 24 other metabolites during the fasting period. These acute changes reveal short-term mechanisms which, with consistent repeated episodes of IF, may lead to improved health and reduced risk of CAD and diabetes.
3.
Physical exercise, gut, gut microbiota, and atherosclerotic cardiovascular diseases.
Chen, J, Guo, Y, Gui, Y, Xu, D
Lipids in health and disease. 2018;17(1):17
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Cardiovascular diseases (CVD), such as heart attacks and strokes, are the leading cause for mortality worldwide. Many studies have shown beneficial effects of physical exercise on cardiovascular risk factors, such as high cholesterol, high blood pressure, abdominal obesity and diabetes. However, some of the mechanisms, by which these beneficial effects occur, are not well understood. It is believed that gut microbiota, affected by physical exercise, altering the intestinal environment, plays a role. This review paper summarised the current understanding on the effects of physical exercise on CVD, through its effects on the gut microbiota and intestinal function. The authors reviewed animal and human studies looking at how various types of exercise, such as high-intensity interval training (mice), running (rats and mice) and rugby (humans), affect diversity and distribution of microbes, metabolites produced by microbiota, intestinal wall integrity and systemic inflammation. Based on the reviewed papers, the authors concluded that, although further research is warranted, many studies confirm the premise that physical exercise can prevent CVD through modifying gut microbiota and alleviating systemic inflammation.
Abstract
Arteriosclerotic cardiovascular diseases (ASCVDs) are the leading cause of morbidity and mortality worldwide and its risk can be independently decreased by regular physical activity. Recently, ASCVD and its risk factors were found to be impacted by the gut microbiota through its diversity, distribution and metabolites. Meanwhile, several experiments demonstrated the relationship between physical exercise and diversity, distribution, metabolite of the gut microbiota as well as its functions on the lipid metabolism and chronic systematic inflammation. In this review, we summarize the current knowledge on the effects of physical exercise on ASCVD through modulation of the gut microbiota and intestinal function.