View clinical trials related to Muscle Damage.
Filter by:Iron supplementation is very common in athletes, probably due to its catalytic role on the oxygen transport and optimal function of oxidative enzymes and proteins during exercise. Iron is also characterized as a potent pro-oxidant, as it can lead to increased production of reactive oxygen and nitrogen species (RONS) that are involved in critical biological processes, such as gene expression, signal transduction and enzyme activity. In exercise, low levels of RONS are essential for optimal force production, whereas excessive production of RONS can cause contractile dysfunction, resulting in muscle weakness and fatigue. On the other hand, RONS are involved in signaling pathways and up-regulation of the expression of several genes, and therefore, RONS can provoke favorable effects such as training adaptations. The purpose of the present study is to investigate the effect of iron supplementation on redox status, muscle damage and muscle performance after an acute bout of a valid muscle damaging eccentric exercise model in adults and children.
To examine the influence of compression garments manufactured with Far-Infrared technology on exercise performance during and after repeated eccentric isokinetic muscle actions of the leg extensors.
Intense, eccentric resistance exercise causes muscle damage, soreness, inflammation, and a loss of muscle function. Protein-amino acid supplementation before, during, and following damaging resistance exercise may reduce muscle damage and accelerate recovery. This study will determine if supplementation with Herbalife 24 Rebuild Strength (compared to placebo) before, during, and after a 90-minute bout of eccentric exercise attenuates exercise-induced muscle damage, inflammation, and delayed onset of muscle soreness (DOMS), speeds recovery of muscle function, and maintains immune function in NASCAR pit crew athletes (Hendrick Motor Sports).
Healthy participants will ingest American ginseng daily or a placebo for four weeks prior to engaging in a unaccustomed exercise bout designed to induce mild-moderate muscle soreness. Muscle soreness will be assessed via decrements in muscle strength and with a self-rating of perceived soreness before and several times after the exercise.
Study Objectives 1. Compare beta-hydroxy-beta-methylbutyrate free acid (HMB-FA) to cold water immersion on performance recovery from an acute bout of high intensity resistance exercise. 2. Compare HMB-FA + Cold water immersion to HMB-FA or cold water immersion. 3. Examine the effect of these recovery modalities on markers of muscle damage, inflammation and immune function. Subjects Subjects (men and women, 18 - 35 y) with at least one year of resistance training experience will be recruited. Subjects will be randomly divided into one of four groups: a cold water immersion group (CW), HMB-FA, CW+HMB-FA and a control group (CT). Study Protocol Subjects will report to the Human Performance Laboratory (HPL) on four separate occasions. On the first visit (T1) subjects will be tested for maximal strength [one repetition-maximum (1-RM)] on the squat, dead lift and barbell lunge exercises.] On their second visit (T2) subjects will perform a lower body resistance exercise session consisting of four sets of the squat, dead lift and barbell lunge exercises. All subjects will then report back to the HPL at 24- (T3) and 48-hours (T4) post-exercise. During T3 and T4, subjects will perform four sets of the squat exercise only using the same loading pattern and rest interval length as T2. Following the T2 and T3 workouts subjects in CT will undergo no treatment; subjects in CW will be required to sit in a whirlpool tub for 10-min up to their umbilicus in water at 50° F - 54° F (10° C - 12° C); subjects in HMB-FA will be provided the supplement 30 min prior each workout and CW+HMB-FA will be administered together at time points describe above. Statistical Analysis Statistical evaluation of performance and biochemical changes will be accomplished using a repeated measures analysis of variance (ANOVA).
The purpose of the present investigation is to compare the responses and adaptations of young and elderly individuals to repeated eccentric exercise in regards to muscle function and redox homeostasis in a side-by-side comparison.
The aim of this study is to assess the effect of ingesting a commercial carbohydrate and protein dietary supplement in powder form (P-CHO supplement) or a milk shake with skimmed milk, strawberries and banana (MS), after resistance exercise, in muscle damage, oxidative stress, inflammation and functional recovery. It is hypothesised if the ingestion of a milk shake with skimmed milk and fruit (strawberry and banana) has the same impact on markers of muscle damage, oxidative stress, inflammation and functional recovery induced by resistance exercise, as the intake of a commercial powder with the same CHO and protein amounts. Fifteen adult athletes from the Portuguese Athletic Federation will complete 2 trials separated at least by 2 weeks. Alternate legs and drinks will be used in each trial and participants will be overnight-fasted. This study will have a single-blind, randomized, crossover, repeated-measures experimental design. In each trial, after warm-up, the eccentric peak torque of the knee joint extensors will be determined using an isokinetic dynamometer. After this, participants will complete an isokinetic exercise until exhaustion at a constant angular velocity of 60° • s-1. After the exhaustion protocol, athletes will perform again the peak torque determination. Immediately after, participants will drink the P-CHO supplement or MS during the first 2 h. Both drinks will contain 0.8-1.2 g carbohydrates • kg-1 • h-1 and 0.2-0.4 g protein • kg-1 • h-1. Twenty four and 48 h after the exhaustion protocol participants will return to the laboratory to repeat the peak torque determination. Blood samples will be collected before warming-up, immediately and 2 h after the last peak torque determination and 24 h and 48 h after. Serum samples will be analyzed for creatine kinase, lactate dehydrogenase, interleukine-6, protein carbonyls and total antioxidant status. The delayed onset muscle soreness, using a visual analogue scale, and girths will be measured at the same moments as blood sampling. Two-way repeated-measures ANOVA will be used for statistical analysis of the data.
Consumption of vitamin supplements is a common practice among athletes or people participating in health promoting exercise programs. The reason for this interest in vitamin supplements is primarily because of the observation that enhanced production of reactive oxygen and nitrogen species (RONS) influence fundamental biological processes, such as gene expression, signal transduction and enzyme activity. In a muscle and exercise physiology context, a low level of RONS is required for normal force production, whereas marked increases in RONS can cause contractile dysfunction, resulting in muscle weakness and fatigue. On the other hand RONS are involved in signaling pathways and serve to up-regulate the expression of a number of genes and can exert favorable effects such as training adaptations. The present study will employ a valid eccentric exercise model to examine the influence of combined vitamin C and E supplementation after acute and chronic eccentric exercise on muscle damage and performance, redox status, hemolysis and lipid and lipoprotein profile.
The purpose of this study is to determine the influence of non-steroidal anti-inflammatory drugs (NSAIDs) on muscle regeneration. The investigators' hypothesis is that ingestion of NSAID will delay or impair muscle regeneration.
The purpose of this study is to determine the effects of fish oil supplementation (Lovaza, GlaxoSmithKline) on muscle strength, muscle soreness and inflammation following exercise.