Notes

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Larger-scale, well-designed studies are required. EU-funded guidelines recommend that patients with depression or vulnerability to depression should be encouraged to enhance a plant-based diet with a high content of grains/fibres, fermented foods, and fish. A significant impact of such a diet is likely mediated through the gut microbiota.The human gut microbiome plays a key role in host physiology in health and disease. There is a growing emphasis on the bidirectional interaction between various medications and the gut microbiome. Here, we will first review how drugs can affect microbiome composition and how the microbiome can alter the pharmacodynamics and potentially pharmacokinetics of psychotropic medications. We will take into consideration different classes of psychotropics, including antipsychotics, antidepressants, antianxiety drugs, anticonvulsants/mood stabilisers, opioid analgesics, drugs of abuse, alcohol, nicotine, and xanthines. The varying effects of these widely used medications on microorganisms are becoming apparent from in vivo and in vitro studies. This has important implications for future drug discovery in psychiatry which will need to consider the host microbiome as a major potential target.There is accumulating evidence from observational and intervention studies in nutritional psychiatry regarding the importance of diet for mental health outcomes across the lifespan. Here, we synthesise this evidence, including findings from large meta-analyses showing cross-sectional and prospective associations between diet quality and mental health, even following adjustment for relevant confounding factors. Potential mechanistic pathways underpinning these associations include those of the gut-brain axis, demonstrated mostly in animal models. https://www.selleckchem.com/products/5-chloro-2-deoxyuridine.html Dietary fibre is an important component of healthy diet and may be relevant for common mental disorders, with some studies showing a dose-dependent relationship between fibre intake and risk of depression. The potential contribution of nutraceuticals is also discussed, such as omega-3 fatty acids, vitamins, minerals, and psychobiotics. We consider the relevance of special diets such as the ketogenic diet and food sensitivities in the management of severe mental illness (e.g., anorexia nervosa) and brain disease (e.g., Alzheimer's disease). Given the relatively early nature of research in nutritional psychiatry, there remain a number of challenges to its translation into clinical practice. These span individual, clinical, and societal domains. We conclude with a discussion of micro- and macroeconomic factors which may be considered in the successful application of nutritional psychiatry research to improve public health.The gut microbiome plays a vital role in numerous aspects of physiology, including functions related to metabolism, the immune system, behaviour, brain structure and function. Furthermore, it is now becoming increasingly clear that alterations in microbial composition or diversity are implicated in several disease states, including anxiety, depression, autism spectrum disorder (ASD), Alzheimer's disease (AD), Parkinson's disease (PD), obesity, and diabetes. Therefore, therapeutic targeting of the gut microbiota has the potential to be useful in the treatment of both stress-related disorders and metabolic diseases. An important method by which the gut microbiome can influence the gut-brain axis is through microbial production of psychoactive metabolites. Several bacteria have been shown to produce metabolites which can impact host health, such as short-chain fatty acids, conjugated linoleic acid, antimicrobials, exopolysaccharides, and vitamins. Furthermore, several molecules with neuroactive functions, including serotonin, gamma-aminobutyric acid, catecholamines, and acetylcholine, have been isolated from bacteria within the human gut. This review aims to explore the psychoactive metabolites reported to be produced by gut bacteria, particularly those of relevance to stress-related disorders. Screening methods for psychoactive metabolite production, as well as the challenges and limitations of this research, will also be addressed. Finally, the implications of metabolite production for neuropsychiatric disorders such as depression, anxiety, and stress, behavioural disorders such as ASD, and neurodegenerative disorders such as AD and PD will be discussed.Understanding how the microbiome influences health and disease has emerged as an important area of research across all domains of biomedical and health sciences. An extensive body of work in animal models has established a link between the gut microbiome and anxiety-like behaviour. Foundational work on germ-free mice provided the catalyst for neuroscientists to consider the microbiota-brain axis and brain health. Research manipulating the microbiome, including use of germ-free mice, antibiotics, and probiotics, provide evidence that the microbiota influences stress systems and in particular anxiety-like behaviour. Consideration of anxiety-like behaviour in animal models of metabolic and inflammatory disorders expands the scope of the work and correlates in clinical studies are emerging. This chapter highlights the work done to date in animal studies and reviews the recent clinical literature translating these observations to anxiety disorders.There is currently enormous interest in the impact of the intestinal microbiota on the development and function of the brain via activity of the microbiota-gut-brain axis. It has long been recognised that symbiotic microorganisms influence host behaviour, but in recent years evidence has accumulated that this can, in fact, be beneficial to the host. Indeed, substantial research has now demonstrated an influence of the intestinal microbiota on a wide range of mammalian behaviours. Here, we review what is currently known about the influence of intestinal microbiota on learning and memory, olfaction, social behaviours, and circadian processes. While work in animal models is compelling, further work is required to elucidate mechanisms whereby bacterial influence is occurring, as well as to determine the extent to which gut microbiota can influence similar phenotypes in humans.The dynamic population of microbes that reside in the gastrointestinal tract plays a pivotal role in orchestrating several aspects of host physiology and health, including but not limited to nutrient extraction and metabolism, as well as the regulation of intestinal epithelial barrier integrity. Gut microbes interact with the host in a bi-directional manner as the microbiota can support the development and education of the innate and adaptive immune systems, thereby conferring protection against pathogens and harmful stimuli while training the host to maintain a homeostatic tolerance towards commensal symbiotics. Recent advances in the field have highlighted the importance of the host-microbiota relationship in neurodevelopment and behaviour, with relevant implications for the onset and progression of brain disorders of inflammatory origin. Microbial modulation of brain function is achieved throughout complex neuro-immune-endocrine pathways of the microbiome-gut-brain axis. Changes in the composition of the gut microbiota or perturbation in microbial-derived metabolites and neuroactive compounds are sensed by the afferent branches of the sympathetic and vagal innervation and transmitted to the central nervous system, which in turn produces behavioural responses. Here, we focus on how the crosstalk between the gut microbiota and the immune system modulates the development and function of the peripheral and central nervous systems. Specific attention is afforded to the involvement of host-microbe neuroimmune interactions in the pathogenesis of neuro-psychiatric and neuroinflammatory disorders such as autism spectrum disorders, anxiety, and depression, as well as Parkinson's and Alzheimer's diseases.Psychosocial stress, driven by a variety of sources and influences, can be ubiquitous in our modern society. Prolonged exposure to these stressors can have detrimental biological and psychological effects; extant findings in childhood adversity indicate that the cumulative effects of exposure to childhood adversity increase risk for developmental delays, altered immune responses, and psychopathology later in life. The pathways by which these effects are conferred continue to be studied. Given that pregnancy is a critical period during which susceptibility to lifetime health and illness are programmed, this chapter will focus on the impacts of maternal history of childhood adversity on offspring mental health, including the role of the microbiota-gut-brain axis. One of the most commonly used frameworks of the last several decades for measuring childhood adversity is the Adverse Childhood Experiences (ACEs) psychometric. We provide an overview of the possible mechanisms through which maternal stress, including the cumulative effects of maternal ACEs, may increase susceptibility to disease in offspring. These include altered epigenetic regulation, hypothalamic-pituitary-adrenal axis function and peripheral inflammation, and gut microbial composition. Finally, we conclude with clinical considerations, including possible future therapeutic interventions.Since the beginning of life on earth, microorganisms have played a significant role in evolution. Throughout the history of Homo sapiens and its precursor humanoid forms, microorganisms have been present at birth and proliferated until death. It is at these extremes of life that the microbiome, especially that within the gastrointestinal tract, is most dynamic and perhaps has its greatest influence on host health. Here, we focus on the role of the gut microbiome as a regulator of brain and behaviour through key points in the human lifespan. We first describe trajectories of the microbiome in early life and ageing, before providing evidence for the existence of sensitive periods in the microbiome-gut-brain axis at these extremes of the lifespan. Finally, we briefly examine potential mechanisms for interactions between the microbiome and the brain during development and ageing.Maturity-onset diabetes of the young (MODY) is a heterogeneous group of monogenic disorders of impaired pancreatic β cell function. The mechanisms underlying MODY include β cell KATP channel dysfunction (e.g., KCNJ11 [MODY13] or ABCC8 [MODY12] mutations); however, no other β cell channelopathies have been associated with MODY to date. Here, we have identified a nonsynonymous coding variant in KCNK16 (NM_001135105 c.341T>C, p.Leu114Pro) segregating with MODY. KCNK16 is the most abundant and β cell-restricted K+ channel transcript, encoding the two-pore-domain K+ channel TALK-1. Whole-cell K+ currents demonstrated a large gain of function with TALK-1 Leu114Pro compared with TALK-1 WT, due to greater single-channel activity. Glucose-stimulated membrane potential depolarization and Ca2+ influx were inhibited in mouse islets expressing TALK-1 Leu114Pro with less endoplasmic reticulum Ca2+ storage. TALK-1 Leu114Pro significantly blunted glucose-stimulated insulin secretion compared with TALK-1 WT in mouse and human islets. These data suggest that KCNK16 is a previously unreported gene for MODY.
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