-
1.
Effect of ultra-processed diet on gut microbiota and thus its role in neurodegenerative diseases.
Martínez Leo, EE, Segura Campos, MR
Nutrition (Burbank, Los Angeles County, Calif.). 2020;71:110609
-
-
-
Plain language summary
The consumption of ultra-processed foods has increased dramatically in recent years, resulting in an overconsumption of foods that are nutritionally only suitable to be consumed occasionally. Prolonged and short-term dietary modifications can affect the composition and diversity of the gut microbiota and in turn, dysregulation of the gut microbiota may be associated with diseases of the brain. This systematic review study aimed to determine the relationship between diets high in ultra-processed foods, gut microbiota dysregulation and how this may influence early development of brain diseases. The authors first reviewed literature surrounding the role of gut microbiota on health owing to their ability to produce signalling molecules that have various functions around the body. An imbalance in the gut microbiota can result in an overproduction of signalling molecules that contribute to an unhealthy state. These signalling molecules can also act on the brain through several ways such as the nervous, circulatory, and immune systems. The review demonstrates that high fat, high sugar diets are related to increased risk for diseases such as Alzheimer’s disease and that diets high in fibre, are related to a low incidence of brain disorders, but as very few studies have looked at this in relation to gut microbiota relationships are only speculative. It was concluded that gut microbiota dysregulation could act as a clinical indicator between brain diseases and ultra-processed foods, however further studies are needed on the relationship between diet, gut microbiota and brain diseases.
Abstract
The current dietary pattern is characterized by high consumption of ultra-processed foods and lower consumption of fiber and vegetables, environmental factors that are associated directly with the current incidence of chronic metabolic diseases. Diet is an environmental factor that influences the diversity and functionality of the gut microbiota, where dietary changes have a direct action on their homeostasis. The environment created in the gut by ultra-processed foods, a hallmark of the Western diet that are recognized as trigger factors for low-grade systemic inflammatory and oxidative changes, favor the development of neurodegenerative diseases (NDs). From a systematic search, the present review analyzes the relationship and effect of the current feeding pattern, with the dysregulation of the microbiota and its influence on the development of cognitive decline. Because diagnosis of NDs is usually at late stages, this review highlights the importance of a search for stricter public health strategies regarding access to and development of ultra-processed foods.
-
2.
Current Perspectives on Gut Microbiome Dysbiosis and Depression.
Capuco, A, Urits, I, Hasoon, J, Chun, R, Gerald, B, Wang, JK, Kassem, H, Ngo, AL, Abd-Elsayed, A, Simopoulos, T, et al
Advances in therapy. 2020;37(4):1328-1346
-
-
-
Free full text
-
Plain language summary
The gut microbiome has been implicated in several neurological disorders; however exact mechanisms are still not fully understood. This review of recent studies, aimed to investigate the relationship between an imbalanced gut microbiome and depression. The authors first looked at the epidemiology of disease, concluding that significant burden needs to be assessed through improved preventative measures. This will depend upon the correct identification of risk factors, and the study focused on the role of the gut microbiome in this through animal and human studies. Imbalances in inflammation through altered gut microbiota, depleted biodiversity and stress induced microbiome changes were all implicated in the development of depression. It was concluded that studies on the role of microbiota in depression remain promising but are small and follow many different methodologies. This study could be used by healthcare professionals to better understand the role of gut microbiota in the development of depression and that ensuring a healthy gut may improve symptoms.
Abstract
The human gut microbiome partakes in a bidirectional communication pathway with the central nervous system (CNS), named the microbiota-gut-brain axis. The microbiota-gut-brain axis is believed to modulate various central processes through the vagus nerve as well as production of microbial metabolites and immune mediators which trigger changes in neurotransmission, neuroinflammation, and behavior. Little is understood about the utilization of microbiome manipulation to treat disease. Though studies exploring the role of the microbiome in various disease processes have shown promise, mechanisms remain unclear and evidence-based treatments for most illnesses have not yet been developed. The animal studies reviewed here offer an excellent array of basic science research that continues to clarify mechanisms by which the microbiome may affect mental health. More evidence is needed, particularly as it relates to translating this work to human subjects. The studies presented in this paper largely demonstrate encouraging results in the treatment of depression. Limitations include small sample sizes and heterogeneous methodology. The exact mechanism by which the gut microbiota causes or alters neuropsychiatric disease states is not fully understood. In this review, we focus on recent studies investigating the relationship between gut microbiome dysbiosis and the pathogenesis of depression. This article is based on previously conducted studies and does not contain any studies with human participants or animals performed by any of the authors.
-
3.
Mental Disorders Linked to Crosstalk between The Gut Microbiome and The Brain.
Choi, TY, Choi, YP, Koo, JW
Experimental neurobiology. 2020;29(6):403-416
-
-
-
Free full text
Plain language summary
The gut microbiome may have a role in regular brain function and mental health and this review paper aimed to determine the mechanisms through which this may be possible. There are several mental health disorders that may be affected by the gut microbiome, major depressive disorder (MDD), anxiety disorder, autism spectrum disorder (ASD), Alzheimer’s disease (AD), and addiction. It appears that there is a correlation between a disordered gut microbiome (known as dysbiosis) and MDD, ASD and addiction. Anxiety symptoms in healthy individuals and cognitive deficits in individuals with AD have reportedly been improved with probiotics. How the gut microbiome communicates with the brain was also discussed with the enteric nervous system, vagus nerve, spinal chord, immune system and brain signalling molecules all being implicated as possible routes. Finally, the paper discussed the use of probiotics for the prevention or treatment of mental disorders, with Bifidobacteria, Lactobacillus and specifically L. reuteri, L. plantarum and L. helveticus all shown in animal models to improve aspects associated with mental disorders. Amongst the human research B. longum has been shown to relieve stress and increase cognitive function in healthy individuals. It was concluded that studies have elucidated a relationship between the gut microbiome and mental health through various routes of communication. Research should focus on how gut microbiome changes are involved in mental illness. This study could be used by healthcare professionals to further knowledge on the potential relationship between the gut microbiome and mental health.
Abstract
Often called the second brain, the gut communicates extensively with the brain and vice versa. The conversation between these two organs affects a variety of physiological mechanisms that are associated with our mental health. Over the past decade, a growing body of evidence has suggested that the gut microbiome builds a unique ecosystem inside the gastrointestinal tract to maintain the homeostasis and that compositional changes in the gut microbiome are highly correlated with several mental disorders. There are ongoing efforts to treat or prevent mental disorders by regulating the gut microbiome using probiotics. These attempts are based on the seminal findings that probiotics can control the gut microbiome and affect mental conditions. However, some issues have yet to be conclusively addressed, especially the causality between the gut microbiome and mental disorders. In this review, we focus on the mechanisms by which the gut microbiome affects mental health and diseases. Furthermore, we discuss the potential use of probiotics as therapeutic agents for psychiatric disorders.
-
4.
Bacterial Metabolites of Human Gut Microbiota Correlating with Depression.
Averina, OV, Zorkina, YA, Yunes, RA, Kovtun, AS, Ushakova, VM, Morozova, AY, Kostyuk, GP, Danilenko, VN, Chekhonin, VP
International journal of molecular sciences. 2020;21(23)
-
-
-
Free full text
Plain language summary
Depression is multifactorial disease and it is the most common type of psychiatric disorder. Literature indicates that there are significant differences between the gut microbiota (GM) of patients with depression and healthy controls. The aim of this review was to examine (a) various low-molecular compounds as potential biomarkers of depression in correlation with the metabolism of the GM, and (b) ways to correct the microbiota imbalance. Results show that: - the use of the GM biomarkers, reflecting the neuromodulatory [the process by which nervous activity is regulated through classes of neurotransmitters], immunomodulatory [the process by which the body’s immune system is altered] and antioxidant statuses of the host organism, in the analysis of metagenomic [the study of a collection of genetic material (genomes) from a mixed community of organisms] data from patients with neuropsychiatric diseases, is gaining currency. - diet remains one of the most effective measures that can be taken to restore the microbial balance in the gut and alleviate the symptoms of depression. - a healthy diet during the depression therapy, along with the application of probiotics and psychobiotics, may potentially improve the course of the disease and contribute to the progress of treatment. Authors conclude that further progress in the practical understanding of the role of the GM in depression will greatly depend on correct planning of future metagenomic studies.
Abstract
Depression is a global threat to mental health that affects around 264 million people worldwide. Despite the considerable evolution in our understanding of the pathophysiology of depression, no reliable biomarkers that have contributed to objective diagnoses and clinical therapy currently exist. The discovery of the microbiota-gut-brain axis induced scientists to study the role of gut microbiota (GM) in the pathogenesis of depression. Over the last decade, many of studies were conducted in this field. The productions of metabolites and compounds with neuroactive and immunomodulatory properties among mechanisms such as the mediating effects of the GM on the brain, have been identified. This comprehensive review was focused on low molecular weight compounds implicated in depression as potential products of the GM. The other possible mechanisms of GM involvement in depression were presented, as well as changes in the composition of the microbiota of patients with depression. In conclusion, the therapeutic potential of functional foods and psychobiotics in relieving depression were considered. The described biomarkers associated with GM could potentially enhance the diagnostic criteria for depressive disorders in clinical practice and represent a potential future diagnostic tool based on metagenomic technologies for assessing the development of depressive disorders.
-
5.
Immediate and long-term consequences of COVID-19 infections for the development of neurological disease.
Heneka, MT, Golenbock, D, Latz, E, Morgan, D, Brown, R
Alzheimer's research & therapy. 2020;12(1):69
-
-
-
Free full text
Plain language summary
Covid-19 may cause brain dysfunction evidenced by symptoms individuals experience once they have contracted the disease. Loss of smell, taste and confusion have all been reported by patients and a number of severe cases have reported incidences of stroke. These are all of concern, as Covid-19 can severely affect the elderly who ordinarily are the most likely to suffer from brain disorders. This small review paper of 27 studies stated that there are four possible ways in which Covid-19 may affect the brain, which put Covid-19 sufferers at an increased risk of long-term brain disorders. This was supported by findings, which showed one third of Covid-19 patients leave hospital with evidence of brain dysfunction. Inflammation was heavily reviewed by the authors as a possible causal factor. It was concluded that patients who survive Covid-19 infection are at an increased risk for developing brain disorders such as Alzheimer's disease, however it was acknowledged that further studies are required. Clinicians could use this study to understand the possible need for both short-term and long-term monitoring of brain function in individuals who have survived Covid-19, especially if they are elderly.
Abstract
Increasing evidence suggests that infection with Sars-CoV-2 causes neurological deficits in a substantial proportion of affected patients. While these symptoms arise acutely during the course of infection, less is known about the possible long-term consequences for the brain. Severely affected COVID-19 cases experience high levels of proinflammatory cytokines and acute respiratory dysfunction and often require assisted ventilation. All these factors have been suggested to cause cognitive decline. Pathogenetically, this may result from direct negative effects of the immune reaction, acceleration or aggravation of pre-existing cognitive deficits, or de novo induction of a neurodegenerative disease. This article summarizes the current understanding of neurological symptoms of COVID-19 and hypothesizes that affected patients may be at higher risk of developing cognitive decline after overcoming the primary COVID-19 infection. A structured prospective evaluation should analyze the likelihood, time course, and severity of cognitive impairment following the COVID-19 pandemic.
-
6.
Brown Adipose Crosstalk in Tissue Plasticity and Human Metabolism.
Scheele, C, Wolfrum, C
Endocrine reviews. 2020;41(1)
-
-
-
Free full text
-
Plain language summary
Brown adipose tissue (BAT) is an important contributor to the regulation of metabolism via cellular communication with organs such as liver, muscle, gut and central nervous system. BAT is important for heat generation and is at high levels in human infants. Levels of activation of BAT decline as we age and it has been shown that the amount of BAT is smaller and its activity reduced in those with obesity and type 2 diabetes. To date, there is no answer to efficiently restore functional BAT in aging and obese subjects. This review looks at experiments done on the factors secreted from active BAT (batokines). The review aims to provide a structure for the processes and cell types involved in BAT and the recent findings of BAT whole-body communication are discussed. Altogether, these findings demonstrate that BAT has an adaptive capacity. Studying batokines, offers an alternative approach to identify novel drug targets for metabolic regulation.
Abstract
Infants rely on brown adipose tissue (BAT) as a primary source of thermogenesis. In some adult humans, residuals of brown adipose tissue are adjacent to the central nervous system and acute activation increases metabolic rate. Brown adipose tissue (BAT) recruitment occurs during cold acclimation and includes secretion of factors, known as batokines, which target several different cell types within BAT, and promote adipogenesis, angiogenesis, immune cell interactions, and neurite outgrowth. All these processes seem to act in concert to promote an adapted BAT. Recent studies have also provided exciting data on whole body metabolic regulation with a broad spectrum of mechanisms involving BAT crosstalk with liver, skeletal muscle, and gut as well as the central nervous system. These widespread interactions might reflect the property of BAT of switching between an active thermogenic state where energy is highly consumed and drained from the circulation, and the passive thermoneutral state, where energy consumption is turned off. (Endocrine Reviews 41: XXX - XXX, 2020).
-
7.
Using psychoneuroimmunity against COVID-19.
Kim, SW, Su, KP
Brain, behavior, and immunity. 2020;87:4-5
-
-
-
Free full text
-
Plain language summary
This viewpoint article raises awareness of the threat of COVID-19 poses to psychiatric patients who are in mental health hospitals. Those patients appear to have a much elevated mortality rate and are potentially more vulnerable to the effects of panic/anxiety due to the pandemic. Their lifestyle choices, influenced by fears about the virus, may also have a negative effect on their immunity. The article also raises the issue of the effects the pandemic and associated changes to day-to-day life can have on the mental and general health of the rest of the population, and in particular to mental health professionals, whose ability to care for their psychiatric patients may be impaired. The authors also briefly discuss the psychological and immunological mechanisms that connect our mental state to the ability of our immune system to fight infections, and the impact of our lifestyles and environments. To summarise they state that infected patients, uninfected quarantined individuals and medical professionals all require mental health supporting strategies, and that epidemiological studies of potential long-term psychiatric consequences are essential.
Abstract
The worldwide outbreak of coronavirus disease 2019 (COVID-19) raises concerns of widespread panic and anxiety in individuals subjected to the real or perceived threat of the virus. Compared to general populations, patients who are institutionalized in a closed unit are also very vulnerable to COVID-19 infection and complications. This crisis touched on difficult issues of not only psychiatric care and ethics, but also psychological impacts to psychiatric care givers. In this Viewpoint, we address both physical and biopsychosocial aspects of this infection, as well as the psychoneuroimmunity of preventive strategies of healthy lifestyle, regular exercise, balanced nutrition, quality sleep and a strong connection with people. Social distancing and wearing masks might help us from pathogen exposure, yet such these measures also prevent us from expressing compassion and friendliness. Therefore, all forms of psychological support should be routinely implemented not only to consider psychological resilience but also to enhance psychoneuroimmunity against COVID-19.
-
8.
The Gut Microbiome and Mental Health: What Should We Tell Our Patients?: Le microbiote Intestinal et la Santé Mentale : que Devrions-Nous dire à nos Patients?
Butler, MI, Mörkl, S, Sandhu, KV, Cryan, JF, Dinan, TG
Canadian journal of psychiatry. Revue canadienne de psychiatrie. 2019;64(11):747-760
-
-
-
Free full text
-
Plain language summary
The gut-brain axis is the bi-directional communication pathway and increasing evidence indicates its impact in neural health and disease. With the field of nutritional psychiatry actively developing, psychiatric patients have become increasingly aware of the therapeutic use of probiotics and mental health. This review aims to inform psychiatrists about the communication between the microbiome and brain and discuss its relevance to the management and treatment of psychiatric illness. In reviewing the common psychiatric illnesses, the current literature shows inconsistent results on specific microbiome compositions related to specific illnesses, yet shows promising effects for probiotic use in many disorders. These findings offer a novel paradigm for approaching mental illness through the lens of nutritional psychiatry. Authors conclude there is much work to be done translating laboratory findings into clinical practice, and highlight the necessity for clinicians to stay informed of the literature and make accurate recommendations to patients.
Abstract
The gut microbiome as a potential therapeutic target for mental illness is a hot topic in psychiatry. Trillions of bacteria reside in the human gut and have been shown to play a crucial role in gut-brain communication through an influence on neural, immune, and endocrine pathways. Patients with various psychiatric disorders including depression, bipolar disorder, schizophrenia, and autism spectrum disorder have been shown to have significant differences in the composition of their gut microbiome. Enhancing beneficial bacteria in the gut, for example, through the use of probiotics, prebiotics, or dietary change, has the potential to improve mood and reduce anxiety in both healthy people and patient groups. Much attention is being given to this subject in the general media, and patients are becoming increasingly interested in the potential to treat mental illness with microbiome-based therapies. It is imperative that those working with people with mental illness are aware of the rationale and current evidence base for such treatment strategies. In this review, we provide an overview of the gut microbiome, what it is, and what it does in relation to gut-brain communication and psychological function. We describe the fundamental principles and basic techniques used in microbiome-gut-brain axis research in an accessible way for a clinician audience. We summarize the current evidence in relation to microbiome-based strategies for various psychiatric disorders and provide some practical advice that can be given to patients seeking to try a probiotic for mental health benefit.
-
9.
Tryptophan Metabolism in Inflammaging: From Biomarker to Therapeutic Target.
Sorgdrager, FJH, Naudé, PJW, Kema, IP, Nollen, EA, Deyn, PP
Frontiers in immunology. 2019;10:2565
-
-
-
Free full text
Plain language summary
Inflammation is a normal physiological process activated by the immune system in response to injury or infection. As we age, the immune system changes and the balance between pro- and anti-inflammatory agents can shift. This causes a chronic inflammatory state referred to as inflammaging. The rate of inflammaging is strongly associated with age-related disability, disease and mortality. The way in which the essential amino acid tryptophan (Trp) is broken down affects inflammation. If it is converted to kynurenine (Kyn) and its metabolites, inflammation is modulated. Studies have shown that the Kyn/Trp ratio, measured in blood, is strongly associated with ageing in humans. It could therefore be a useful marker to predict the onset of age-related diseases. This review discusses the metabolism of Trp and the links to inflammation. The authors hypothesize how intervening in these pathways could impact health- and lifespan. Future studies are needed to confirm the value of Trp metabolism as a biomarker for (un)healthy ageing and as drug target for inflammaging-related disease.
Abstract
Inflammation aims to restore tissue homeostasis after injury or infection. Age-related decline of tissue homeostasis causes a physiological low-grade chronic inflammatory phenotype known as inflammaging that is involved in many age-related diseases. Activation of tryptophan (Trp) metabolism along the kynurenine (Kyn) pathway prevents hyperinflammation and induces long-term immune tolerance. Systemic Trp and Kyn levels change upon aging and in age-related diseases. Moreover, modulation of Trp metabolism can either aggravate or prevent inflammaging-related diseases. In this review, we discuss how age-related Kyn/Trp activation is necessary to control inflammaging and alters the functioning of other metabolic faiths of Trp including Kyn metabolites, microbiota-derived indoles and nicotinamide adenine dinucleotide (NAD+). We explore the potential of the Kyn/Trp ratio as a biomarker of inflammaging and discuss how intervening in Trp metabolism might extend health- and lifespan.
-
10.
A Review of Dietary (Phyto)Nutrients for Glutathione Support.
Minich, DM, Brown, BI
Nutrients. 2019;11(9)
-
-
-
Free full text
Plain language summary
Glutathione is made up of 3 amino acids (cysteine, glutamic acid and glycine) and plays important roles in the body, including oxidative stress reduction, supporting the immune system and contributing to detoxification processes. Evidence suggests that it is an important marker and target for treatment in many chronic, age-related diseases. This review article explores the evidence of nutritional strategies to improve glutathione status. The authors examine the evidence for supplementation of the precursors of glutathione as well as with various forms of supplemental glutathione itself, and the impacts on glutathione status and clinical impacts. Crucially, the review article provides information on dietary sources of precursors of glutathione and glutathione itself, which will provide Nutrition Practitioners with compelling information for use in clinic. Lean protein, brassica vegetables, polyphenol-rich fruits and vegetables, green tea, herbs and spices and omega-3 rich foods are all discussed in detail.
Abstract
Glutathione is a tripeptide that plays a pivotal role in critical physiological processes resulting in effects relevant to diverse disease pathophysiology such as maintenance of redox balance, reduction of oxidative stress, enhancement of metabolic detoxification, and regulation of immune system function. The diverse roles of glutathione in physiology are relevant to a considerable body of evidence suggesting that glutathione status may be an important biomarker and treatment target in various chronic, age-related diseases. Yet, proper personalized balance in the individual is key as well as a better understanding of antioxidants and redox balance. Optimizing glutathione levels has been proposed as a strategy for health promotion and disease prevention, although clear, causal relationships between glutathione status and disease risk or treatment remain to be clarified. Nonetheless, human clinical research suggests that nutritional interventions, including amino acids, vitamins, minerals, phytochemicals, and foods can have important effects on circulating glutathione which may translate to clinical benefit. Importantly, genetic variation is a modifier of glutathione status and influences response to nutritional factors that impact glutathione levels. This narrative review explores clinical evidence for nutritional strategies that could be used to improve glutathione status.