1.
Effects of a Synbiotic on Plasma Immune Activity Markers and Short-Chain Fatty Acids in Children and Adults with ADHD-A Randomized Controlled Trial.
Yang, LL, Stiernborg, M, Skott, E, Xu, J, Wu, Y, Landberg, R, Arefin, S, Kublickiene, K, Millischer, V, Nilsson, IAK, et al
Nutrients. 2023;15(5)
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Attention deficit hyperactivity disorder (ADHD) is a common childhood-onset neurodevelopmental psychiatric disorder. The core symptoms of the disorder are inattention and hyperactivity/impulsivity. The aim of this study was to explore the effects of Synbiotic 2000 on concentrations of plasma immune activity markers and short-chain fatty acids (SCFAs) in ADHD. This study is a double-blind randomised controlled trial over a period of 9-weeks. Patients (n= 248) were randomly allocated to one of the two treatments: Synbiotic 2000 or placebo. Results show that there was no statistically significant overall effect of Synbiotic 2000 compared to placebo on any analyte analysing all the paediatric and all adult participants as one group. However, age-group stratified analyses showed that plasma levels of several of the analytes were at baseline different in the children compared to in the adults. Authors conclude that Synbiotic 2000, in children with ADHD, reduces markers of intestinal and vascular inflammation, the latter in part through increasing SCFAs levels. Furthermore, they suggest that the findings warrant further studies to determine if persons with ADHD would benefit inflammation-wise from dietary intake of Synbiotic 2000 or a similar synbiotic.
Abstract
Synbiotic 2000, a pre + probiotic, reduced comorbid autistic traits and emotion dysregulation in attention deficit hyperactivity disorder (ADHD) patients. Immune activity and bacteria-derived short-chain fatty acids (SCFAs) are microbiota-gut-brain axis mediators. The aim was to investigate Synbiotic 2000 effects on plasma levels of immune activity markers and SCFAs in children and adults with ADHD. ADHD patients (n = 182) completed the 9-week intervention with Synbiotic 2000 or placebo and 156 provided blood samples. Healthy adult controls (n = 57) provided baseline samples. At baseline, adults with ADHD had higher pro-inflammatory sICAM-1 and sVCAM-1 and lower SCFA levels than controls. Children with ADHD had higher baseline sICAM-1, sVCAM-1, IL-12/IL-23p40, IL-2Rα, and lower formic, acetic, and propionic acid levels than adults with ADHD. sICAM-1, sVCAM-1, and propionic acid levels were more abnormal in children on medication. Synbiotic 2000, compared to placebo, reduced IL-12/IL-23p40 and sICAM-1 and increased propionic acid levels in children on medication. SCFAs correlated negatively with sICAM-1 and sVCAM-1. Preliminary human aortic smooth-muscle-cell experiments indicated that SCFAs protected against IL-1β-induced ICAM-1 expression. These findings suggest that treatment with Synbiotic 2000 reduces IL12/IL-23p40 and sICAM-1 and increases propionic acid levels in children with ADHD. Propionic acid, together with formic and acetic acid, may contribute to the lowering of the higher-than-normal sICAM-1 levels.
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Towards Tailored Gut Microbiome-Based and Dietary Interventions for Promoting the Development and Maintenance of a Healthy Brain.
Larroya, A, Pantoja, J, Codoñer-Franch, P, Cenit, MC
Frontiers in pediatrics. 2021;9:705859
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The cause of neurodevelopmental disorders (NDDs) is complex and multifactorial. Recent studies have indicated that early life disturbances of the gut microbiome can impact neurodevelopment, suggesting this critical window may play a key role in the prevention or progression of neurological disease. The growing field of personalized nutrition works on the basis of tailored dietary intervention strategies that consider individual variability based on genetics, diet, and the environment. The aim of this paper is to review the current evidence on the neurodevelopmental interaction between the gut microbiota, environment and host, and assess the efficacy of tailored, personalized nutrition interventions aimed at preventing or treating NDDs. The literature provides evidence that the gut microbiota is susceptible to influence by various factors early in life, and the health of the microbiome may modulate mental health consequences later in life. Additionally, key nutritional deficiencies and microbiome alterations have been linked to NDDs, suggesting potential markers that may lead to improved prevention and treatment. Based on the current literature, the authors emphasize the need for further research during the critical window of microbiome development in order to target the cause of neurodevelopmental impairments. They suggest these findings could help progress the field of Nutritional Psychiatry towards effective tailored nutrition and personalized medicine.
Abstract
Mental health is determined by a complex interplay between the Neurological Exposome and the Human Genome. Multiple genetic and non-genetic (exposome) factors interact early in life, modulating the risk of developing the most common complex neurodevelopmental disorders (NDDs), with potential long-term consequences on health. To date, the understating of the precise etiology underpinning these neurological alterations, and their clinical management pose a challenge. The crucial role played by diet and gut microbiota in brain development and functioning would indicate that modulating the gut-brain axis may help protect against the onset and progression of mental-health disorders. Some nutritional deficiencies and gut microbiota alterations have been linked to NDDs, suggesting their potential pathogenic implications. In addition, certain dietary interventions have emerged as promising alternatives or adjuvant strategies for improving the management of particular NDDs, at least in particular subsets of subjects. The gut microbiota can be a key to mediating the effects of other exposome factors such as diet on mental health, and ongoing research in Psychiatry and Neuropediatrics is developing Precision Nutrition Models to classify subjects according to a diet response prediction based on specific individual features, including microbiome signatures. Here, we review current scientific evidence for the impact of early life environmental factors, including diet, on gut microbiota and neuro-development, emphasizing the potential long-term consequences on health; and also summarize the state of the art regarding the mechanisms underlying diet and gut microbiota influence on the brain-gut axis. Furthermore, we describe the evidence supporting the key role played by gut microbiota, diet and nutrition in neurodevelopment, as well as the effectiveness of certain dietary and microbiome-based interventions aimed at preventing or treating NDDs. Finally, we emphasize the need for further research to gain greater insight into the complex interplay between diet, gut microbiome and brain development. Such knowledge would help towards achieving tailored integrative treatments, including personalized nutrition.