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The effects of dietary patterns and food groups on symptomatic osteoarthritis: A systematic review.
Zeng, J, Franklin, DK, Das, A, Hirani, V
Nutrition & dietetics: the journal of the Dietitians Association of Australia. 2023;80(1):21-43
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Osteoarthritis is a chronic joint disease that can lead to disability, characterised by the deterioration and loss of joint cartilage, inflammation, pain, aches, and stiffness. Research has shown a positive association between osteoarthritis progression and pro-inflammatory diets, such as Western diets, and a negative association with anti-inflammatory diets, such as the DASH and Mediterranean diets. This systematic review evaluated the evidence from the literature to show the positive and negative associations between osteoarthritis and diet. The Prudent diet, Mediterranean diet, and increased fibre intake were effective in reducing the progression of osteoarthritis and alleviating its symptoms, while the Western diet increased the progression of symptomatic osteoarthritis. The Prudent diet was found to be particularly effective in alleviating symptomatic osteoarthritis. The beneficial effects of anti-inflammatory diets and increased fibre intake are thought to be due to the reduction and suppression of inflammatory cytokines, while inflammatory diets have the opposite effect. Although there is high heterogeneity between the studies, healthcare professionals can use the results of this systematic review to understand the therapeutic clinical utility of anti-inflammatory diets and high-fibre intake in reducing the progression of symptomatic osteoarthritis in people above the age of 45 years. Further robust studies are needed to evaluate the effectiveness of other therapeutic dietary strategies.
Abstract
AIM: To systematically review current literature to determine the association between symptomatic osteoarthritis and dietary patterns, diet quality and food groups in adults aged ≥45 years. METHODS The review was registered on PROSPERO (CRD42021270891). Cochrane Central Library, Cumulative Index of Nursing and Allied Health Literature, Embase, Medline and Web of Science databases were searched. A total of 3816 records were identified. Eligible articles involved populations aged ≥45 years with symptomatic osteoarthritis, assessing dietary patterns, diet quality or food groups, with pain in joints as outcomes. The Joanna Briggs Institute Critical Appraisal Checklists were used for quality assessment. Grading of Recommendations, Assessment, Development and Evaluation was used to assess the certainty of evidence. RESULTS Six cohort studies were included. The Prudent dietary pattern and the Mediterranean dietary pattern reduced the progression of osteoarthritis symptoms. The Western dietary pattern increased symptomatic osteoarthritis progression. Increased total fibre consumption reduced symptomatic osteoarthritis progression and pain worsening, but the effects of fibre from each food group were inconclusive. Diet with high inflammatory potential increased risk of new onset symptomatic osteoarthritis, but the effects of overall diet quality were inconclusive. CONCLUSIONS The Prudent dietary pattern showed the highest protection on symptomatic osteoarthritis in adults aged 45 years and over. The body of evidence is limited, suggesting that further research is needed to corroborate the estimated effect at a high certainty of evidence, and to incorporate previously unstudied dietary patterns and food groups. Identifying the most beneficial dietary pattern may inform future guidelines for reducing symptomatic osteoarthritis in middle aged and older adults.
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The Gut Microbiota (Microbiome) in Cardiovascular Disease and Its Therapeutic Regulation.
Rahman, MM, Islam, F, -Or-Rashid, MH, Mamun, AA, Rahaman, MS, Islam, MM, Meem, AFK, Sutradhar, PR, Mitra, S, Mimi, AA, et al
Frontiers in cellular and infection microbiology. 2022;12:903570
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Cardiovascular disease (CVD) accounts for 31% of all-cause mortality worldwide. Irregularities in the composition of intestinal microbial composition, genetic factors, nutrition, metabolic irregularities, and smoking are among the potential causes of CVD. Intestinal permeability and translocation of endotoxins and bacterial metabolites to systemic circulation may trigger an immune response and inflammation, which may increase the risk of CVD. Synthesis of bacterial metabolites such as trimethylamine N-oxide (TMAO) by choline-inducing gut bacteria and reduced consumption of dietary TMAO precursors may elevate the CVD risk. This review explores the latest research on the role of gut microbiota in the development of atherosclerosis and CVD, as well as potential strategies to prevent CVD by targeting TMAO-producing gut bacteria. Elevated levels of TMAO in the bloodstream can lead to the buildup of cholesterol and ultimately result in atherosclerosis. However, consuming probiotics and fibre-rich foods can help regulate gut bacteria, reduce inflammation, and improve lipid profiles, all of which contribute to better cardiovascular health. More future robust studies are required to examine the mechanistic insights and confirm whether TMAO can serve as a biomarker for preventing CVD through the therapeutic modulation of intestinal bacteria.
Abstract
In the last two decades, considerable interest has been shown in understanding the development of the gut microbiota and its internal and external effects on the intestine, as well as the risk factors for cardiovascular diseases (CVDs) such as metabolic syndrome. The intestinal microbiota plays a pivotal role in human health and disease. Recent studies revealed that the gut microbiota can affect the host body. CVDs are a leading cause of morbidity and mortality, and patients favor death over chronic kidney disease. For the function of gut microbiota in the host, molecules have to penetrate the intestinal epithelium or the surface cells of the host. Gut microbiota can utilize trimethylamine, N-oxide, short-chain fatty acids, and primary and secondary bile acid pathways. By affecting these living cells, the gut microbiota can cause heart failure, atherosclerosis, hypertension, myocardial fibrosis, myocardial infarction, and coronary artery disease. Previous studies of the gut microbiota and its relation to stroke pathogenesis and its consequences can provide new therapeutic prospects. This review highlights the interplay between the microbiota and its metabolites and addresses related interventions for the treatment of CVDs.
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Gut Microbiota-Derived Metabolites and Cardiovascular Disease Risk: A Systematic Review of Prospective Cohort Studies.
Sanchez-Gimenez, R, Ahmed-Khodja, W, Molina, Y, Peiró, OM, Bonet, G, Carrasquer, A, Fragkiadakis, GA, Bulló, M, Bardaji, A, Papandreou, C
Nutrients. 2022;14(13)
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Cardiovascular disease (CVD) remains a major public health issue. Identification of circulating biomarkers with prognostic value may help to both identify pathophysiological processes relevant to CVD development and improve preventive cardiovascular risk reduction efforts. The aim of this study was to identify the association of circulating levels of microbial metabolites with CVD incidence. This study is a systematic review of twenty-one studies of which 19 were prospective cohort studies, one study included one nested case-control study and one study included two nested case–control studies. Results show that: - associations of trimethylamine N-oxide (TMAO) [molecular metabolite derived from the gut flora] and subsequent risk of CV outcomes were supported by some but not all prospective studies. - inconsistent results were also obtained for secondary bile acids in relation to CVD and related outcomes, and CVD/all-cause mortality. - with regards to branched-chain amino acids (BCAAs), their associations with CV outcomes were robust amongst most of the studies. Authors conclude that their findings show inconsistent results for TMAO and bile acids but robust ones for the relationships between BCAAs and CVD. Thus, further studies are needed to investigate whether circulating microbial metabolites could be an intervention target for CVD.
Abstract
Gut microbiota-derived metabolites have recently attracted considerable attention due to their role in host-microbial crosstalk and their link with cardiovascular health. The MEDLINE-PubMed and Elsevier's Scopus databases were searched up to June 2022 for studies evaluating the association of baseline circulating levels of trimethylamine N-oxide (TMAO), secondary bile acids, short-chain fatty acids (SCFAs), branched-chain amino acids (BCAAs), tryptophan and indole derivatives, with risk of cardiovascular disease (CVD). A total of twenty-one studies were included in the systematic review after evaluating 1210 non-duplicate records. There were nineteen of the twenty-one studies that were cohort studies and two studies had a nested case-control design. All of the included studies were of high quality according to the "Newcastle-Ottawa Scale". TMAO was positively associated with adverse cardiovascular events and CVD/all-cause mortality in some, but not all of the included studies. Bile acids were associated with atrial fibrillation and CVD/all-cause mortality, but not with CVD. Positive associations were found between BCAAs and CVD, and between indole derivatives and major adverse cardiovascular events, while a negative association was reported between tryptophan and all-cause mortality. No studies examining the relationship between SCFAs and CVD risk were identified. Evidence from prospective studies included in the systematic review supports a role of microbial metabolites in CVD.
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The Gut Microbiota and Its Implication in the Development of Atherosclerosis and Related Cardiovascular Diseases.
Sanchez-Rodriguez, E, Egea-Zorrilla, A, Plaza-Díaz, J, Aragón-Vela, J, Muñoz-Quezada, S, Tercedor-Sánchez, L, Abadia-Molina, F
Nutrients. 2020;12(3)
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Cardiovascular disease (CVD) is the leading non-communicable disease and cause of death worldwide. The human microbiome can exert direct influences on bodily functions and in recent years much attention has been drawn to the significance of these microorganisms and their role in disease development. Divergences of microbiome patterns are also implicated in the progression and pathogenesis of CVD. This review describes the connection between host microbiota and CVD development. Elaborated are some of the potential mechanisms by which the microbiota and their associated metabolites can directly influence vascular tone and contribute to high blood pressure. More indirect processes, such as microbiota-mediated inflammation, insulin resistance and obesity are also accounted for. Furthermore, the authors discuss modulation of the microbiome composition as potential target for therapeutic interventions. Known influences that alter the microbiome are diet patterns, specific compounds such as probiotics, fish oils and polyphenols, physical activity and novel technologies like faecal transplants. This review outlines the many ways in which the microbiome can contribute to the development of CVD. Summarised are key points to consider in clinical practice, when navigating CVD and its microbiome associated risks factors.
Abstract
The importance of gut microbiota in health and disease is being highlighted by numerous research groups worldwide. Atherosclerosis, the leading cause of heart disease and stroke, is responsible for about 50% of all cardiovascular deaths. Recently, gut dysbiosis has been identified as a remarkable factor to be considered in the pathogenesis of cardiovascular diseases (CVDs). In this review, we briefly discuss how external factors such as dietary and physical activity habits influence host-microbiota and atherogenesis, the potential mechanisms of the influence of gut microbiota in host blood pressure and the alterations in the prevalence of those bacterial genera affecting vascular tone and the development of hypertension. We will also be examining the microbiota as a therapeutic target in the prevention of CVDs and the beneficial mechanisms of probiotic administration related to cardiovascular risks. All these new insights might lead to novel analysis and CVD therapeutics based on the microbiota.
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Gut microbial metabolites in depression: understanding the biochemical mechanisms.
Caspani, G, Kennedy, S, Foster, JA, Swann, J
Microbial cell (Graz, Austria). 2019;6(10):454-481
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Major depressive disorder is a leading cause of disability and is linked to shortened life expectancy and suicide. Despite its prevalence, for near to a third of patients, long-term treatment options are ineffective. In addition to the primary presentation of persistent low mood, other emotional and physiological symptoms, researchers have also identified alterations in metabolism, hormones and the immune system. Furthermore, increasing evidence suggests that depression and depressive behaviour is also influenced by divergences in gut health and gut bacteria composition. With insights from animal and human research, this review highlights how the gut and gut bacteria-derived metabolites can directly or indirectly influence mood. Described are the pathways of how the gut and its microorganism communicate with the brain, the essential role the immune system has as part of the gut-brain communication, and the impact of low-grade, chronic inflammation on neurofunction. Comprehensive summaries are dedicated to how several metabolites or by-products from gut bacteria can influence the nervous system and gene expression in relation to depression. These include substances like neurotransmitters, short-chain fatty acids, tryptophan metabolites, lactate, bile acids, choline metabolites and folate. This article yields a detailed overview of how gut health and microbiota can influence neurofunction and mental health. The authors promote the idea of the gut as a suitable target for the management of depressive disorders, whilst also eluding to the current limitations and need for further research.
Abstract
Gastrointestinal and central function are intrinsically connected by the gut microbiota, an ecosystem that has co-evolved with the host to expand its biotransformational capabilities and interact with host physiological processes by means of its metabolic products. Abnormalities in this microbiota-gut-brain axis have emerged as a key component in the pathophysiology of depression, leading to more research attempting to understand the neuroactive potential of the products of gut microbial metabolism. This review explores the potential for the gut microbiota to contribute to depression and focuses on the role that microbially-derived molecules - neurotransmitters, short-chain fatty acids, indoles, bile acids, choline metabolites, lactate and vitamins - play in the context of emotional behavior. The future of gut-brain axis research lies is moving away from association, towards the mechanisms underlying the relationship between the gut bacteria and depressive behavior. We propose that direct and indirect mechanisms exist through which gut microbial metabolites affect depressive behavior: these include (i) direct stimulation of central receptors, (ii) peripheral stimulation of neural, endocrine, and immune mediators, and (iii) epigenetic regulation of histone acetylation and DNA methylation. Elucidating these mechanisms is essential to expand our understanding of the etiology of depression, and to develop new strategies to harness the beneficial psychotropic effects of these molecules. Overall, the review highlights the potential for dietary interventions to represent such novel therapeutic strategies for major depressive disorder.
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Small talk: microbial metabolites involved in the signaling from microbiota to brain.
Caspani, G, Swann, J
Current opinion in pharmacology. 2019;48:99-106
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The gut-brain axis (GBA) is the communication network between the gastrointestinal tract and the central nervous system. An array of gut bacteria-derived metabolites mediates this interaction between the gastrointestinal system and the brain, influencing physiological and pathological processes in direct and indirect ways. Thus a variation in the gut microbiome can alter the functional capacity and output of the gut-brain-communication. In this review, the authors summarise key bacterial metabolites from the gut and their effect on the brain. Addressed are short-chain fatty acids, their impact on gut and brain barrier integrity, their role in appetite regulation, and their association with anxiety and depressive disorders amongst other aspects. Secondly, bile acids, which are processed by the microbiome, can activate several receptors. And thus divergence gut bacteria can alter the composition of bile acids and change their signalling capacity. Bile acids can also directly modify gut and blood-brain barrier function and may carry a signalling role in the brain. A few neurotransmitters are covered in this article, as several types of gut bacteria synthesize neurotransmitters, such as serotonin and dopamine. Though, it is uncertain whether all gut-derived neurotransmitters can reach the brain. However, certain GABA-producing bacteria have been shown to elicit higher GABA levels in the brain. The microbiota can also be involved with the conversion of neurotransmitters such as dopamine. The final section briefly capture the evidence of other brain health-relevant molecules derived from the intestinal microbiota, including Lipopolysaccharides, choline, lactate and B-Vitamins. This review yields a short and comprehensive summary highlighting the many ways the gut can influence brain function and health and could be of interest to those providing mental health support in light of gut function.
Abstract
The wealth of biotransformational capabilities encoded in the microbiome expose the host to an array of bioactive xenobiotic products. Several of these metabolites participate in the communication between the gastrointestinal tract and the central nervous system and have potential to modulate central physiological and pathological processes. This biochemical interplay can occur through various direct and indirect mechanisms. These include binding to host receptors in the brain, stimulation of the vagus nerve in the gut, alteration of central neurotransmission, and modulation of neuroinflammation. Here, the potential for short chain fatty acids, bile acids, neurotransmitters and other bioactive products of the microbiome to participate in the gut-brain axis will be reviewed.
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Crosstalk between the microbiome and epigenome: messages from bugs.
Qin, Y, Wade, PA
Journal of biochemistry. 2018;163(2):105-112
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Trillions of microbes live symbiotically in and on an individual human being, most of them inside the digestive tract and communally known as the gut microbiome. The gut microbiome plays a vital role in the individual host’s health, not only by helping digest food and harvest energy, but also by regulating immune development and influencing gene expression. Diet and factors, such as infections and the use of antibiotics, can alter the balance of the microbiome and lead to various outcomes. This paper reviewed the current understanding of the ways in which the gut microbiome is capable of altering the host’s gene expression through microbial signals, including metabolites, bile acids, inflammation and altered composition. The studies highlighted in the paper show that gut microbes communicate both with local cells in the intestines and with more distant organs, such as the liver and the cardiovascular system. Through this communication, they can regulate the expression of immune cells, cancer cells, enzymes and inflammation-related molecules. The authors concluded that these interactions, or the crosstalk between the microbes and the host, demonstrate a crucial role of the gut microbiome in the host’s response to environmental signals. However, many of the mechanisms are still unclear, so further studies are needed to explain specific microbe-derived signals, affecting host gene expression, and to deepen our understanding of how lifestyle, health status and environmental exposures, such as antibiotics, regulate the microbiome and its influence.
Abstract
Mammals exist in a complicated symbiotic relationship with their gut microbiome, which is postulated to have broad impacts on host health and disease. As omics-based technologies have matured, the potential mechanisms by which the microbiome affects host physiology are being addressed. The gut microbiome, which provides environmental cues, can modify host cell responses to stimuli through alterations in the host epigenome and, ultimately, gene expression. Increasing evidence highlights microbial generation of bioactive compounds that impact the transcriptional machinery in host cells. Here, we review current understanding of the crosstalk between gut microbiota and the host epigenome, including DNA methylation, histone modification and non-coding RNAs. These studies are providing insights into how the host responds to microbial signalling and are predicted to provide information for the application of precision medicine.
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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.
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Functional interactions between the gut microbiota and host metabolism.
Tremaroli, V, Bäckhed, F
Nature. 2012;489(7415):242-9
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This literature review aims to discuss evidence for the role of the gut microbiota in metabolism and possible links to obesity. Obesity and caloric intake can influence the microbiota, but whether the reverse is true in humans remains unclear. Much of the mechanisms have been determined in rodents, determining similar pathways in humans is difficult. The interplay of diet, host and gut microbiota may cause increased gut permeability (leaky gut) that could lead to an increase in inflammation that may cause obesity, fatty liver disease and insulin resistance. It is increasingly accepted that gut microbiota can contribute to diseases such as obesity, diabetes and cardiovascular disease, but exactly how and by how much remains unclear. Evidence for treating the microbiota to help with these metabolic diseases, either by pre- or probiotic supplementation, is building. However, double-blind, placebo-controlled studies are required to determine effects. The influence of the gut microbiota is a promising area, but one that needs further research.
Abstract
The link between the microbes in the human gut and the development of obesity, cardiovascular disease and metabolic syndromes, such as type 2 diabetes, is becoming clearer. However, because of the complexity of the microbial community, the functional connections are less well understood. Studies in both mice and humans are helping to show what effect the gut microbiota has on host metabolism by improving energy yield from food and modulating dietary or the host-derived compounds that alter host metabolic pathways. Through increased knowledge of the mechanisms involved in the interactions between the microbiota and its host, we will be in a better position to develop treatments for metabolic disease.