1.
Effect of gut microbiome modulation on muscle function and cognition: the PROMOTe randomised controlled trial.
Ni Lochlainn, M, Bowyer, RCE, Moll, JM, García, MP, Wadge, S, Baleanu, AF, Nessa, A, Sheedy, A, Akdag, G, Hart, D, et al
Nature communications. 2024;15(1):1859
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Humans lose skeletal muscle with advancing age, and this can progress to sarcopenia. Dietary protein is crucial for maintaining skeletal muscle health; however, several factors can lead to reduced protein intake in older age. The aim of this study was to test whether the addition of gut microbiome modulation could augment established muscle function improvements from combined protein (branched chain amino acids [BCAA]) and resistance exercise. This study was based on the PROMOTe (effect of PRebiotic and prOtein on Muscle in Older Twins) trial which was a randomised controlled trial in which twin pairs (n= 72) were randomised, one twin to each study arm. Results showed that prebiotics improved cognition but did not impact muscle strength and function, compared with placebo. Furthermore, gut microbiome modulation via prebiotic supplementation in the context of ageing-muscle research is feasible and well tolerated, with clear responses noted in the gut microbiota composition and function. Authors concluded that cheap and readily available gut microbiome interventions hold promise for improving cognitive frailty in our ageing population.
Abstract
Studies suggest that inducing gut microbiota changes may alter both muscle physiology and cognitive behaviour. Gut microbiota may play a role in both anabolic resistance of older muscle, and cognition. In this placebo controlled double blinded randomised controlled trial of 36 twin pairs (72 individuals), aged ≥60, each twin pair are block randomised to receive either placebo or prebiotic daily for 12 weeks. Resistance exercise and branched chain amino acid (BCAA) supplementation is prescribed to all participants. Outcomes are physical function and cognition. The trial is carried out remotely using video visits, online questionnaires and cognitive testing, and posting of equipment and biological samples. The prebiotic supplement is well tolerated and results in a changed gut microbiome [e.g., increased relative Bifidobacterium abundance]. There is no significant difference between prebiotic and placebo for the primary outcome of chair rise time (β = 0.579; 95% CI -1.080-2.239 p = 0.494). The prebiotic improves cognition (factor score versus placebo (β = -0.482; 95% CI,-0.813, -0.141; p = 0.014)). Our results demonstrate that cheap and readily available gut microbiome interventions may improve cognition in our ageing population. We illustrate the feasibility of remotely delivered trials for older people, which could reduce under-representation of older people in clinical trials. ClinicalTrials.gov registration: NCT04309292.
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Energy Availability and Nutritional Intake during Different Training Phases of Wheelchair Athletes.
Hertig-Godeschalk, A, Ruettimann, B, Valido, E, Glisic, M, Stoyanov, J, Flueck, JL
Nutrients. 2023;15(11)
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To maintain a long-term and successful career, elite athletes try to prevent health problems and maximize training adaptations. This includes not only managing training volume and intensity, along with recovery, but also tailoring nutrition to individual needs. The aim of this study was to assess dietary intake, energy availability (EA), and blood biochemical parameters at four consecutive time points during the pre-competition and competition phases in elite wheelchair athletes participating in a pilot feasibility study. This study was a secondary analysis of a randomised controlled trial. In the main study the participants were athletes who received either daily probiotic or prebiotic supplementation for four weeks, followed by a four-week washout period, and another four weeks of daily supplementation with another supplement. Results showed that: - neither EA nor energy intake (EI) displayed significant differences across the various time points. - all athletes experienced low EA for at least one day, indicating how tough fuelling is for elite athletes. - daily macronutrient intake and timing were frequently suboptimal, with athletes not adjusting EI to accommodate higher training loads. Authors concluded that their findings highlight the need for specific nutritional guidelines tailored to wheelchair athletes, as well as the importance of continuous education and guidance from qualified sports nutritionists.
Abstract
Optimizing nutritional intake and timing helps athletes to improve performance and long-term health. Different training phases can require varying nutritional needs. In this study, we conducted a descriptive assessment of dietary intake, energy availability (EA), and blood biochemical parameters in elite wheelchair athletes during distinct training phases. Data analyzed in this study were collected as part of a randomized controlled crossover trial exploring the feasibility of probiotics and prebiotic supplementation. Data were obtained from consecutive three-day diaries and blood samples, both collected at four different time points across four consecutive months. We included 14 athletes (mean (standard deviation) age 34 (9) years, eight females, and six males) active in different wheelchair sports. The mean daily nutritional intake (g/kg body mass) for females and males was 2.7 (0.9) and 4.0 (0.7) for carbohydrates, 1.1 (0.3) and 1.5 (0.3) for protein, and 0.8 (0.3) and 1.4 (0.2) for fat. EA did not change across the four time points in either female (p = 0.30) or male (p = 0.05) athletes. The mean EA was lower in female athletes compared to male athletes (p = 0.03). Low EA (≤30 kcal/ kg fat-free mass/day) was observed in female (58 (29) % of days) and male (34 (23) % of days) athletes. Iron deficiency with anemia was observed in two female athletes. Mean vitamin D levels were insufficient (<75 nmol/L). Macronutrient intake, EA, and blood biochemical parameters were suboptimal in this cohort of elite wheelchair athletes, especially in female athletes.
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Effects of inulin supplementation on body composition and metabolic outcomes in children with obesity.
Visuthranukul, C, Chamni, S, Kwanbunbumpen, T, Saengpanit, P, Chongpison, Y, Tepaamorndech, S, Panichsillaphakit, E, Uaariyapanichkul, J, Nonpat, N, Chomtho, S
Scientific reports. 2022;12(1):13014
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The prevalence of overweight and obesity among children and adolescents has risen dramatically. Overweight and obese children are at risk of developing co-morbidities such as type 2 diabetes mellitus, hypertension, dyslipidaemia, metabolic syndrome, non-alcohol fatty liver disease and premature cardiovascular diseases. Furthermore, obese children are highly prone to become obese adults. The aim of this study was to determine the effects of prebiotic (as inulin) supplementation on body weight, adiposity, and metabolic profiles in obese Thai children. This study is a randomised double-blinded placebo-controlled trial. Participants (n=165) were randomly allocated to 3 groups: inulin, placebo, and dietary fibre advice group. Results show that the intensive behavioural modification and frequent follow-up are effective strategies to reduce body mass index and adiposity in obese children. Furthermore, even though inulin supplementation did not demonstrate considerable effect on adiposity and metabolic outcomes, it can increase fat-free mass in these children. Authors conclude that further research regarding the change of gut microbiota composition and their metabolites are needed to determine inulin’s impact on host microbe interaction in obese paediatric population.
Abstract
Inulin might improve body composition in obese children. We aimed to determine the effects of inulin supplementation on body composition and metabolic outcomes in obese children. A randomized, double-blinded placebo-controlled study was conducted in obese Thai children aged 7-15 years. Participants were assigned to 3 treatment groups for 6 months: 13 g of extracted inulin powder from Thai Jerusalem artichoke, isocaloric maltodextrin, and dietary fiber advice groups. Body composition was assessed by bioelectrical impedance analysis. One-hundred and fifty-five children completed the study (mean age 10.4 ± 2.2 years, BMI z-score 3.2 ± 1.0, 59% male). The drop-out rate was 6%. The inulin extract yielded more than 90% compliance without significant gastrointestinal side effects. All three groups demonstrated a significant decrease in BMI z-score, fat mass index (FMI), and trunk FMI, but the differences between groups were not observed. Fat-free mass index significantly increased only in the inulin group (16.18 ± 1.90 vs. 16.38 ± 1.98 kg/m2, P = 0.009). There were no significant differences in the metabolic profiles between groups. Despite showing no substantial effect on adiposity, inulin may increase fat-free mass in obese children. Further research in the change of gut microbiota composition is needed to determine inulin's impact on host-microbe interaction in pediatric obesity.