View clinical trials related to Skeletal Muscle.
Filter by:The goal of this observational study is to learn about functional bladder problems in children. The main questions it aims to answer are: - Does bladder symptoms in children have an effect on core muscles? - How do core muscles change based on an increase or decrease in these symptoms?
The research project is aiming to examine the muscular adaptations to resistance training (RT), detraining (DT) and repeated RT (i.e. retraining). The research project will also examine differences in muscular adaptations between 20 weeks of continuous RT and 20 weeks of intermittent RT including a 10-week DT period in the middle of the training intervention. This is randomized controlled trial in which the research participants will be randomized into discontinuous and continuous groups (both n=~20). Both will be doing a 2-3-week familiarization and control period at the start. Then in the former there will be an initial strength training period (10-wks), a DT period (10-wks), and a second strength training (retraining) period (10-wks). The second group includes a 10-wk non-training control period (10-wks) followed by a RT period (20-wks). Participants will be young, healthy men and women (age 18-35, which 50% are females) with no systematic RT experience during the last 6 months. Measurements will be completed before and after each study period. Body composition will be measured via bioelectrical impedance analysis (BIA) and 3D body scans. Dynamic leg press and elbow flexion one repetition-maximum (1RM) will be used to test maximal strength. Anaerobic performance and strength endurance will be tested in elbow flexion and dynamic leg press using RM tests. Vastus lateralis (VL) and biceps brachii muscle cross-sectional area (CSA) will be assessed via ultrasound. Muscle biopsies of the VL muscle will be obtained to assess changes in muscle fiber morphology and factors regulating and associated with the hypertrophic processes and metabolism. Blood samples will be collected to analyze changes in metabolism and physiology. A rating of perceived exertion (RPE) during training will be collected after every exercise to ensure proper training intensity. Finally, nutrition and habitual physical activity will be assessed with 4-day diet diaries and physical activity questionnaires before the intervention and during each 10-week period.
The aim of this study is to investigate the effect of oral ketone administration during and immediately after an ultramarathon. Potential changes in cognitive function (reaction time, number of errors), running performance, jump height, skeletal muscle inflammatory infiltration and hormonal alterations will be the main focus. In this context, subjects (n=24) will perform a 100km ultrarunning trail, while receiving either ketone ester (KE, n =12) or placebo (CON, n=12). Experimental measurements will be performed immediately before and after the ultramarathon as well as 24h after the ultramarathon.
The key objective of this pilot research study is to dose human volunteers with a heavy (non-radioactive) isotope derivative of nicotinamide to detect NAD synthesis in human skeletal muscle. The ultimate goal is to examine the impact of lifestyle choices, aging, nutraceuticals, and drugs on the rate of NAD synthesis in human subjects.
Prolonged periods of reduced activity are associated with decreased vascular function and muscle atrophy. Physical inactivity due to a sedentary lifestyle or acute hospitalization is also associated with impaired recovery, hospital readmission, and increased mortality. Older adults are a particularly vulnerable population as functional (vascular and skeletal muscle mitochondrial dysfunction) and structural deficits (loss in muscle mass leading to a reduction in strength) are a consequence of the aging process. The combination of inactivity and aging poses an added health threat to these individuals by accelerating the negative impact on vascular and skeletal muscle function and dysfunction. The underlying factors leading to vascular and skeletal muscle dysfunction are unknown, but have been linked to increases in oxidative stress. Additionally, there is a lack of understanding of how vascular function is impacted by inactivity in humans and how these changes are related to skeletal muscle function. It is the goal of this study to investigate the mechanisms that contribute to disuse muscle atrophy and vascular dysfunction in order to diminish their negative impact, and preserve vascular and skeletal muscle function.
The purpose of this study is to assess which amino acids are affecting acute muscle collagen synthesis in response to supplementation and exercise.
Prolonged periods of reduced activity are associated with decreased vascular function and muscle atrophy. Physical inactivity due to acute hospitalization is also associated with impaired recovery, hospital readmission, and increased mortality. Older adults are a particularly vulnerable population as functional (vascular and skeletal muscle mitochondrial dysfunction) and structural deficits (loss in muscle mass leading to a reduction in strength) are a consequence of the aging process. The combination of inactivity and aging poses an added health threat to these individuals by accelerating the negative impact on vascular and skeletal muscle function and dysfunction. The underlying factors leading to vascular and skeletal muscle dysfunction are unknown, but have been linked to increases in oxidative stress. Additionally, there is a lack of understanding of how vascular function is impacted by inactivity in humans and how these changes are related to skeletal muscle function. It is our goal to investigate the mechanisms that contribute to disuse muscle atrophy and vascular dysfunction in order to diminish their negative impact, and preserve vascular and skeletal muscle function across all the lifespan.
Obesity is pro-inflammatory, impairs metabolism, and physically limiting. Specifically, muscle in obese persons does not synthesize proteins normally. This further increases metabolic and physical dysfunction. As such, obesity programs should not only focus on weight loss, but muscle metabolic health. Dairy nutrients have anti-inflammatory and anabolic properties, but mostly evaluated in isolation and/or pre-clinical designs. Also, it is unknown if the circulating benefits extend to the muscle. We hypothesize that dairy full-fat milk will improve these obesity characteristics.
Recently a common Greenlandic nonsense p.Arg684erTer variant (in which arginine is replaced by a termination codon) in the gene TBC1D4 was discovered. The variant has an allele frequency of 17%. Homozygous carriers of this TBC1D4 variant have impaired glucose tolerance and a 10-fold enhanced risk of developing type 2 diabetes (T2D). The investigators propose to carry out comprehensive metabolic phenotyping of adult Inuits carrying zero or two alleles of the TBC1D4 variant. The investigators hypothesise that regulation of TBC1D4 in skeletal muscle is pivotal in regulating glucose uptake during exercise, during physiological insulin stimulation, and for the ability of an acute bout of exercise to improve insulin sensitivity to regulate glucose metabolism in humans. The overall aims in the present project are to: 1. Determine whether the TBC1D4 p.Arg684Ter variant affects the regulation of glucose uptake in skeletal muscle during exercise and during physiological insulin stimulation. 2. Determine the effect of the TBC1D4 p.Arg684Ter variant for the ability of acute exercise to insulin sensitize skeletal muscle to regulate glucose metabolism. 3. Define the metabolic pathways affected by the p.Arg684Ter variant in order to identify causal factors responsible for the diabetic phenotype of Inuit carriers. The knowledge generated will contribute to additional explanatory clues to the increased frequency of T2D in the carriers.
During middle-age, humans begin to lose muscle mass and strength. With increasing age the deterioration of muscle health is associated with a decline in quality of life and the loss of independence. β-hydroxy β-methylbutyrate (HMB) plus Vitamin D (VitD) have been proposed to increase skeletal muscle mass, contractile function and improve body composition but has yet to be evaluated in middle-aged women. The overall goal of this study is to determine the effects of HMB +VitD supplementation during 12 weeks of resistance exercise training or a non-exercise control on body composition, skeletal muscle size, and skeletal muscle function in middle-aged women.