微生态制剂在老年人肠道菌群失衡中的应用

人类从青年到老年这个过程,随着年龄的增长,退行性和感染性疾病的易感性也增加,其可能与人体肠道菌群失衡有着密切的关系。人体肠道内生理菌群对机体健康具有重要的作用,其变化与宿主的免疫功能、食物、疾病和年龄等有关。了解老年人肠道菌群特点,且在老年人肠道菌群失调相关疾病中合理介入微生态制剂,将大大有利于老年人身体健康。本文就老年人肠道菌群失衡相关疾病以及微生态制剂在这些疾病中的应用进行综述。     

浅析肠道菌群干预治疗癫痫的潜在应用前景

肠道菌群是存在于人体内的庞大而复杂的微生物群落,菌群的变化会影响大脑的生理、行为和认知功能,而大脑可以通过免疫、内分泌和神经通路等途径调节神经生理行为,与很多神经和精神疾病(如癫痫、脱髓鞘疾病、阿尔茨海默症、自闭症等)的发生发展有关。近年来诸多证据表明自身免疫机制在癫痫进展中发挥重要作用,肠道菌群可通过调节免疫反应来影响疾病的进展。本文从肠道菌群与大脑间关系的认知、相互间功能影响及与癫痫的关系等方面,探讨通过肠道菌群干预治疗癫痫的机制与潜在应用前景,希望为菌群干预治疗与预防一些神经及精神疾病提供参考。     

瘦素在脑老化认知发展不同阶段中的作用

脑老化过程中伴随脑结构、功能退化和认知能力减退,其认知发展呈异质性,即发展的不均一性,有成功脑老化、正常脑老化、轻度认知功能障碍和阿尔茨海默病等状态。瘦素在不同认知状态下含量不同。研究发现,无神经病理改变的老年人群瘦素水平高,认知功能减退不明显;多数轻度认知功能障碍者瘦素水平降低;瘦素可改善阿尔茨海默病患者的认知障碍,被认为是一种潜在的认知增强剂。瘦素水平降低在脑老化认知障碍的发展中起重要作用。     

肠道菌群与脑-肠轴相互作用关系研究进展

人体肠道内定植了大量的细菌,它们参与机体多种生理功能的维持。大脑与胃肠道之间通过脑-肠轴进行双向关联。近年研究发现肠道菌群与脑-肠轴可相互作用、相互影响。肠道菌群可影响机体神经内分泌系统及免疫系统的功能,脑-肠轴功能变化同样也会改变肠道的菌群结构。本研究就肠道菌群与脑-肠轴功能相互影响的研究进展作一综述,以期为深入了解肠道菌群对脑-肠轴功能的影响提供参考。     

基于脑-肠轴理论探讨针灸治疗认知障碍的机制

认知障碍是一种主要影响认知能力（包括学习、记忆、感知和问题解决等）的心理健康障碍。认知障碍常见于阿尔茨海默病、血管性痴呆、轻度认知障碍等患者。与药物治疗相比，针灸治疗具有低成本、可耐受性和安全等特点，已成为改善认知功能的潜在工具。许多研究表明，在认知障碍的患者中，针灸治疗具有明显改善认知功能的作用。但针灸改善认知功能的机制仍不清楚。基于中医从肠治脑的理论基础以及目前实验研究，脑-肠轴与针灸改善大脑认知功能关系密切。对于针灸改善认知的脑-肠轴机制的理解能促进肠道微生物微观机制研究，但肠道微生物存在个体差异、动态变化、种类繁多等特征，以肠道稳态为调控目标的新针灸方案有待研究完善与规范。本文综述了针灸干预脑-肠轴治疗认知障碍，针灸通过维持肠道生态平衡、保持肠道菌群多样性、调整有益菌群丰度、调节代谢、促进生成脑源性神经营养因子（BDNF）、抑制小胶质细胞激活、降低神经炎症反应、减少Aβ蛋白沉积等机制，实现对认知障碍的治疗。     

肠道微生物菌群对脑及行为的影响

肠道微生物菌群组成的变化对正常生理的影响及其在疾病中的作用逐渐成为研究热点。肠道微生物菌群通过脑肠轴影响宿主生理学的各个方面,包括脑-肠交流、脑功能甚至行为。对无菌动物、被致病细菌感染的、使用益生菌或用抗生素药物的动物研究表明,肠道微生物菌群可以调节宿主焦虑样症状及行为。研究表明对肠道微生物菌群的调节可能是治疗复杂中枢神经系统失调症的新策略。     

肠道菌群与甲状腺疾病

肠道菌群被称为人类的第二基因组。近年研究发现许多内分泌及免疫相关疾病如糖尿病、非酒精性脂肪肝、炎症性肠炎、类风湿性关节炎等的发生发展与肠道菌群紊乱存在相关性。甲状腺是机体重要的内分泌腺体,常见的甲状腺疾病包括:甲状腺功能亢进症、甲状腺功能减退症和甲状腺炎等。甲状腺疾病的病因及发病机制尚不清楚,多数学者认为其与自身免疫异常有关。肠道菌群可以通过影响机体免疫状态等多种机制参与甲状腺稳态的维持,本文对肠道菌群与甲状腺疾病之间的关联性研究进展进行简要综述,以期为肠道菌群和甲状腺疾病领域的研究提供理论依据。     

微生物在精神分裂症发病机制的研究现状

脑和肠道微生物群之间的相互作用逐渐被揭示。目前已经提出脑-肠轴失调和异常与各种中枢神经系统疾病有关。精神分裂症是一种病因不明的严重精神障碍。最近研究表明,肠道微生物的组成和数量变化会通过肠道菌群-肠-脑轴影响人类的认知和社会行为,这意味着肠道菌群在精神分裂症患者中可能起着重要的作用,并有望成为精神分裂症新的治疗靶点。本文综述了肠道菌群与精神分裂症相关性的研究进展,为预防和治疗精神分裂症等精神障碍类疾病提供了理论依据。     

肠道菌群与脊髓损伤并发症

脊髓损伤是严重的致残性神经系统疾病,脊髓损伤后产生的水肿、炎症反应和代谢紊乱等并发症是致使脊髓损伤继发性加重的主要原因。近年来,随着对肠道微生物的研究越来越深入,肠道菌群对神经系统疾病的影响得到广泛关注。肠道菌群可以通过调节机体能量代谢、炎症反应及作用于神经内分泌和脑-肠轴的途径影响中枢神经系统疾病。最近研究发现,肠道菌群与脊髓损伤并发症的关系非常紧密。脊髓损伤后肠道菌群的变化可能影响脊髓损伤后并发症发生以及加重。本文主要就肠道菌群对脊髓损伤后并发症的影响和可能的作用机制进行综述,为临床研究和治疗脊髓损伤提供新思路。     

肠道菌群与精神分裂症的研究进展

精神分裂症是一种精神障碍疾病。除了遗传因素外,一些环境因素也参与了精神分裂症的发生,肠道微生物群是近年来发现的主要影响因素之一。研究表明,精神分裂症患者肠道菌群普遍发生了紊乱,肠道菌群通过肠-脑轴影响神经功能和疾病。肠道菌群可以通过影响神经系统发育、免疫和代谢功能来诱导精神分裂症的发生,肠道菌群可能是精神分裂症防治的有效靶点,调节肠道菌群可能是防治精神分裂症的一种潜在方法。本文就精神分裂症的易感因素、肠道菌群在精神分裂症中的作用、机制以及防治策略等方面的研究进展进行综述。     

肠道微生物群在人类健康衰老中的作用机制研究进展北大核心

衰老的特征是组织器官的功能衰退以及衰老相关疾病风险的增加,这给维护和促进健康长寿带来一系列新的挑战。尽管进行了广泛的衰老相关研究,但进展有限。人们越来越意识到肠道微生物群的结构和功能积极参与了衰老过程。肠道微生物群紊乱表现为许多与年龄相关的肠外器官轴的衰老。肠道微生物群可以被调节,这暗示了通过肠道微生物群抗衰老是一个可以实现的重要目标。本综述总结了肠道微生物群在不同年龄段中的动态演替,这种动态的肠道微生物群从胎儿到出生和婴儿期开始迅速发展,从断奶期到幼儿期迅速变化,然后建立稳定的成年人菌群,直到随着年龄增长最后发生衰退;肠道微生物群与肠外器官轴(大脑、心脏、肝脏、胰腺、肌肉、皮肤和骨骼)衰老相关疾病,以及通过饮食、粪菌移植和微生态制剂调节肠道微生物群靶向抗衰老的研究进展,以期为调控肠道微生物群抗衰老研究提供参考。     

Age-dependent changes in the gut microbiota and serum metabolome correlate with renal function and human aging

Human aging is invariably accompanied by a decline in renal function, a process potentially exacerbated by uremic toxins originating from gut microbes. Based on a registered household Chinese Guangxi longevity cohort (n = 151), we conducted comprehensive profiling of the gut microbiota and serum metabolome of individuals from 22 to 111 years of age and validated the findings in two independent East Asian aging cohorts (Japan aging cohort n = 330, Yunnan aging cohort n = 80), identifying unique age-dependent differences in the microbiota and serum metabolome. We discovered that the influence of the gut microbiota on serum metabolites intensifies with advancing age. Furthermore, mediation analyses unveiled putative causal relationships between the gut microbiota (Escherichia coli, Odoribacter splanchnicus, and Desulfovibrio piger) and serum metabolite markers related to impaired renal function (p-cresol, N-phenylacetylglutamine, 2-oxindole, and 4-aminohippuric acid) and aging. The fecal microbiota transplantation experiment demonstrated that the feces of elderly individuals could influence markers related to impaired renal function in the serum. Our findings reveal novel links between age-dependent alterations in the gut microbiota and serum metabolite markers of impaired renal function, providing novel insights into the effects of microbiota-metabolite interplay on renal function and healthy aging.     

Diet,inflammation and the gut microbiome: Mechanisms for obesity-associated cognitive impairment

Poor diet and obesity are associated with cognitive impairment throughout adulthood, and increased dementia risk in aging. Here we review the current literature interrogating the mechanisms by which diets high in fat, or fat and sugar lead to cognitive impairment, focusing on changes to gut microbiome composition, inflammatory signalling and blood-brain barrier integrity. Preclinical studies indicate weight gain is not necessary for diet-induced cognitive impairment. Rather, gut microbiome composition, and systemic and central inflammatory processes appear to contribute to diet-induced cognitive impairment. While both obese humans and rodents exhibit reduced blood-brain barrier integrity, cognitive impairments precede these changes, suggesting other mechanisms may underly diet-induced cognitive changes. Other potential candidates include hormone, glucoregulatory and cardiovascular changes. Poor diet and obesity act through multiple mechanisms to affect cognitive health and the challenge for future research is to identify key processes that can be reversed to improve cognition and quality of life.     

Alzheimer’s disease and gut microbiota

Alzheimer’s disease (AD) is a most common neurodegenerative disorder, which associates with impaired cognition. Gut microbiota can modulate host brain function and behavior via microbiota-gut-brain axis, including cognitive behavior. Germ-free animals, antibiotics, probiotics intervention and diet can induce alterations of gut microbiota and gut physiology and also host cognitive behavior, increasing or decreasing risks of AD. The increased permeability of intestine and blood-brain barrier induced by gut microbiota disturbance will increase the incidence of neurodegeneration disorders. Gut microbial metabolites and their effects on host neurochemical changes may increase or decrease the risk of AD. Pathogenic microbes infection will also increase the risk of AD, and meanwhile, the onset of AD support the “hygiene hypothesis”. All the results suggest that AD may begin in the gut, and is closely related to the imbalance of gut microbiota. Modulation of gut microbiota through personalized diet or beneficial microbiota intervention will probably become a new treatment for AD.     

宿主遗传因素对肠道菌群的影响

随着高通量测序技术的发展,人们逐渐认识到肠道菌群与人类的健康和疾病密切相关,并发现肠道菌群受很多因素的影响。除了研究传统饮食和药物对肠道菌群的改变外,近年来,科学家也开始注重遗传因素在塑造肠道菌群中的作用。遗传因素可决定宿主的饮食偏好、肠道的生理结构、肠道屏障功能和免疫功能等,而这些都直接与肠道菌群相互作用,参与肠道微生态平衡的构建和稳定。因此,在研究肠道菌群与疾病发生相关性的过程中也需要考虑遗传因素的重要性。随着基因敲除、无菌小鼠和菌群移植等实验技术的革新,以及主成分分析、数量性状基因座和全基因组关联性分析等大数据分析手段的提高,科学家能够深入研究宿主遗传基因与肠道菌群之间的关联性,从而证明宿主遗传基因在塑造肠道微生态的过程中具有重要作用。本文将首先简述肠道菌群与疾病发生之间可能存在的联系,然后从多方面综述遗传因素对肠道菌群的影响及主要的研究进展,从而为今后该领域的深入研究提供重要的指导,也为今后预防和治疗疾病提供新思路和新方法。     

Decreased Enterobacteriaceae translocation due to gut microbiota remodeling mediates the alleviation of premature aging by a high-fat diet

Aging-associated microbial dysbiosis exacerbates various disorders and dysfunctions, and is a major contributor to morbidity and mortality in the elderly, but the underlying cause of this aging-related syndrome is confusing. SIRT6 knockout (SIRT6 KO) mice undergo premature aging and succumb to death by 4 weeks, and are therefore useful as a premature aging research model. Here, fecal microbiota transplantation from SIRT6 KO mice into wild-type (WT) mice phenocopies the gut dysbiosis and premature aging observed in SIRT6 KO mice. Conversely, an expanded lifespan was observed in SIRT6 KO mice when transplanted with microbiota from WT mice. Antibiotic cocktail treatment attenuated inflammation and cell senescence in KO mice, directly suggesting that gut dysbiosis contributes to the premature aging of SIRT6 KO mice. Increased Enterobacteriaceae translocation, driven by the overgrowth of Escherichia coli, is the likely mechanism for the premature aging effects of microbiome dysregulation, which could be reversed by a high-fat diet. Our results provide a mechanism for the causal link between gut dysbiosis and aging, and support a beneficial effect of a high-fat diet for correcting gut dysbiosis and alleviating premature aging. This study provides a rationale for the integration of microbiome-based high-fat diets into therapeutic interventions against aging-associated diseases.     

肠道微生物与骨质疏松相关性的研究进展

随着人口老龄化问题的加剧,骨质疏松症的高发生率降低了人们的生活质量。越来越多的证据表明,肠道微生物群与骨代谢联系密切,肠道微生物群稳态的破坏会导致宿主的病理生理反应,从而引起骨质疏松。通过研究两者之间的相互作用,或许能为骨质疏松症的预防及相关诊疗提供有价值的帮助。本文就目前肠道微生物与骨质疏松症相关机制和主要治疗的研究现状作一综述。     

微生物-肠-脑轴的研究进展

肠道微生物群能够调节宿主肠道稳态,同时参与调节宿主神经系统功能和行为。肠道菌群失调可能导致宿主神经系统功能障碍,从而引发神经退行性疾病。因此,研究微生物在肠?脑轴中发挥的作用及其机制,靶向调控肠道微生物菌群结构和功能,将为神经系统疾病的诊断与治疗提供新的手段。近年来,有关肠道微生物与机体神经系统间的互作研究受到了广泛关注,然而其具体的调控机制还未明晰。因此,本文综述了肠道微生物对宿主神经健康的调节作用,以及肠道微生物与宿主间的互作在调节神经功能、行为的潜力等研究进展,为更好地了解肠道微生物在调控宿主神经系统功能和行为的作用机制提供参考。     

Chronic Functional Bowel Syndrome Enhances Gut-Brain Axis Dysfunction,Neuroinflammation, Cognitive Impairment,and Vulnerability to Dementia

The irritable bowel syndrome (IBS) is a common chronic functional gastrointestinal disorder world wide that lasts for decades. The human gut harbors a diverse population of microbial organisms which is symbiotic and important for well being. However, studies on conventional, germ-free, and obese animals have shown that alteration in normal commensal gut microbiota and an increase in pathogenic microbiota—termed “dysbiosis”, impact gut function, homeostasis, and health. Diarrhea, constipation, visceral hypersensitivity, and abdominal pain arise in IBS from the gut-induced dysfunctional metabolic, immune, and neuro-immune communication. Dysbiosis in IBS is associated with gut inflammation. Gut-related inflammation is pivotal in promoting endotoxemia, systemic inflammation, and neuroinflammation. A significant proportion of IBS patients chronically consume alcohol, non-steroidal anti-inflammatories, and fatty diet; they may also suffer from co-morbid respiratory, neuromuscular, psychological, sleep, and neurological disorders. The above pathophysiological substrate is underpinned by dysbiosis, and dysfunctional bidirectional “Gut-Brain Axis” pathways. Pathogenic gut microbiota-related systemic inflammation (due to increased lipopolysaccharide and pro-inflammatory cytokines, and barrier dysfunction), may trigger neuroinflammation enhancing dysfunctional brain regions including hippocampus and cerebellum. These as well as dysfunctional vago-vagal gut-brain axis may promote cognitive impairment. Indeed, inflammation is characteristic of a broad spectrum of neurodegenerative diseases that manifest demntia. It is argued that an awareness of pathophysiological impact of IBS and implementation of appropriate therapeutic measures may prevent cognitive impairment and minimize vulnerability to dementia.