View clinical trials related to Muscle Atrophy.
Filter by:The aim of the study is to investigate the effect of exercise in form of whole-body electromyostimulation (WB-EMS) on early tumor-induced muscular dysfunction. It is anticipated to gain detailed knowledge about composition and metabolism of skeletal muscle cells, and single muscle fiber functionality. To determine key factors leading to impaired force generation and thus decreased muscle strength in cancer patients who are suspected to develop or already show early signs of tumor cachexia is crucial for the establishment of effective cancer treatment. Comparative analysis of skeletal muscle biopsies taken from the abdomen of patients during indicated surgeries will be conducted. The patients will be allocated to the following study groups: a) Study group 1: Patients without cancer, b) Study group 2: Patients with solid tumors who did not perform physical training and c) Study group 3: Patients with solid tumors who executed physical training in form of WB-EMS. The investigation can help to understand skeletal muscle physiology under exercise and to get a better insight into the effects of physical training on early-stage muscle atrophy, both on cellular and molecular level. Initially, it is planned to identify the inflammation and nutrition status of the patients, and to determine skeletal muscle strength. It is anticipated to explore muscle protein composition, particularly myosin to actin ratio and their interaction. Biochemical analysis and the examination of the cellular ultra-structure should enhance the knowledge about the key mechanisms controlling the contractile apparatus of single muscle fibers in order to determine the quality of muscle force. Taken together, these investigations will help to better understand muscle atrophy in advanced cancer patients, and might support the development of targeted anti-cachectic therapies, that can be applied already in early phases of the tumor disease to significantly improve the patients' prognosis and their quality of life.
Space flight is associated with detrimental changes to the human body, including bone and muscle loss, fluid changes and deconditioning of muscles in the heart and blood vessels. Bed rest experiments, on Earth, are used to study these changes in healthy volunteers, as the disuse of muscles, and impact on the body, mimic the changes seen in the low-gravity environment of Space. Moreover, these changes are similar to those reported in people who remain in bed for long periods of time, such as is seen in intensive care or stroke patients, and bed rest studies also allow the physiological and biochemical impacts of this confinement to be investigated. For example, we know from previous research that muscle inactivity can lead to the development of resistance to the action of the hormone 'insulin', which is a longer term risk factor for the development of type 2 diabetes. Previous studies suggest that this inactivity-induced insulin resistance occurs within the first 48 hours of immobilization. However, it is not clear whether the biochemical and physiological processes underlying these short-term responses to inactivity are the same as those seen in the longer term. The current study aims to investigate the biochemical and physiological changes seen after 3 days of bed rest and to compare to those measured in a previous 57 days bed rest study carried out at Institut Médecine Physiologie Spatiale (MEDES; Toulouse, France). A 3-day period of reconditioning will subsequently be used to determine if these changes can be readily reversed.
Rotator cuff disease is one of the most prevalent musculoskeletal conditions across the world. Patients with chronic rotator cuff tears often have substantial muscle atrophy and fatty infiltration. Surgical repair of the tear does not reverse the atrophy, and many patients continue to experience weakness, pain, and a persistent reduction in the quality of life. An important limitation in our ability to successfully rehabilitate these injuries postoperatively and return patients to normal function has to do with the poor quality of the muscle and tendon after rotator cuff repair. The stromal vascular fraction (SVF) of subcutaneous adipose tissue is highly enriched with cells (SVFCs) that can both directly participate in tissue regeneration by differentiating into myogenic and tenogenic cells, and indirectly by secreting growth factors and small molecules which activate pathways associated with healthy tissue regeneration. High numbers of autologous SVFCs can be isolated using the cost-effective, intraoperative Icellator (Tissue Genesis, Honolulu, HI) point-of-care system. This clinical trial will be determine if the use of SVFCs can enhance outcomes for patients who are undergoing surgical repair of a torn supraspinatus rotator cuff.
The aim of this randomised, double-blind, placebo-controlled, parallel groups trial is to investigate the effects of 12 weeks resistance exercise and whey protein supplementation on energy metabolism, markers of appetite, inflammation and hormonal response and body composition and strength and functional performance. Generally healthy, retired men aged 60-80 years will be recruited (n = 52 in total, n = 13 per group). Participants will be randomised to either: a) control group, b) whey protein supplement group, c) resistance exercise + control group or d) resistance exercise + whey protein supplementation group.
This is a retrospective, observational study and will investigate the clinical predictive value of and change in muscle quantity and quality in critically ill patients with severe respiratory failure requiring veno-venous extracorporeal membrane oxygenation (VV-ECMO).
This is a safety and tolerability study investigating the effect of an amino acid formulation in healthy volunteers during and after limb immobilization.
The study purpose is to investigate the hypothesis that in adults with SAH, early neuromuscular electrical stimulation (NMES) and high protein supplementation (HPRO) will improve muscle mass, metabolic and inflammatory biomarker profiles, compared to SAH controls receiving standard of care interventions for nutrition and mobilization. The investigators will accomplish this by studying the effects of a high protein (HPRO) nutritional treatment as well as NMES intervention have upon muscle wasting and motor strength acutely after SAH. This will be addressed in a prospective trial of SAH patients receiving HRPO with NMES as compared to age and severity-matched SAH patients undergoing standard of care interventions for nutrition and mobilization. Additionally, the study will investigate the impact HPRO and NMES interventions have upon inflammatory cytokines and markers of energy balance. Results of this study will establish evidence for precision nutrition plus early exercise to mitigate the catabolic and inflammatory state produced by SAH to improve muscle, metabolic, and health recovery outcomes.
This study is a collaboration between the Centre of Human & Aerospace Physiological Sciences (CHAPS) and the Sleep and Brain Plasticity Centre (Department of Neuroimaging) at King's College London and the Sleep Disorders Centre at Guy's Hospital.The main purpose of the study is to evaluate the effects of a 7 day unloading period (simulating micro gravity) on muscle mass using three independent methods; two scanning techniques (magnetic resonance imaging (MRI) and dual x-ray absorptiometry (DXA)) and one that involves swallowing a capsule that contains a harmless chemical called creatine (D3-Creatine (D3-cr)) and then measuring its concentration in urine. In order to induce muscle loss, participants will be required to lie flat on their back on a water bed filled with water and salt (called hyper-buoyancy flotation (HBF)). As this situation is similar to that experienced in space, the investigators will also measure the effect of HBF on sleep, brain and physiological function - all things known to change in astronauts. Sixteen male subjects (18-40 yrs) will be recruited to participate in the study that will require physiological testing before, during and following both 7 days of normal conditions and 7 days of HBF bed-rest. Each subject will be exposed to the same conditions and assessments over the study period. As some loss of muscle is expected, participants will be offered an exercise rehabilitation programme upon completion of HBF with self-monitored and/or guided sessions based on those provided by the Space Medicine Office of the European Space Agency to returning astronauts.
Chronic Obstructive Pulmonary Disease (COPD) is characterized by persistent airway obstruction and inflammatory response of the lungs and bronchi. Episodes of exacerbations contribute to increase the severity and prognosis of the disease. Muscle dysfunction (loss of strength and muscle mass) is one of comorbidities affecting 30% to 60% of patients and playing a key role in their prognosis. Indeed, several studies have shown muscle weakness during hospitalization for exacerbation of COPD by measure of maximal voluntary contraction of quadriceps (MVCQ), but the results are variable from one patient to another. Moreover, no study was interested in the change of muscle mass in patients hospitalized for an exacerbation of COPD. Several mechanisms have been mentioned but not demonstrated: systemics factors (initial amyotrophy, inflammation, oxidative stress, corticotherapy, hypoxia…) but also physical inactivity. In this context, identifying factors associated with the onset of muscle weakness during hospitalization for exacerbation of COPD is a necessary step to better understand the mechanisms and consider a personalized therapeutic approach that can improve the functional and clinical prognosis of disease. The primary outcome is to identify the clinical and biological determinants associated with the onset of amyotrophy (Measure by ultrasound of sectional area of the Rectus Femoris, CSARF), during hospitalization for exacerbation of COPD. The secondary outcome is to identify the clinical and biological determinants associated with the onset of MVCQ decrease, during hospitalization for exacerbation of COPD. 120 patients hospitalized for exacerbation of COPD will be recruited in two hospitals (CHU Montpellier - CHU Grenoble, FRANCE). The measures of CSARF and MVCQ are carried out on the second, fifth, eighth day of hospitalization, on discharge and on the sixtieth day after hospitalization. A blood test will be performed on the second day of hospitalization to explore different markers of inflammation and oxydative stress. Moreover, to quantify the level of physical activity (number of steps), each patient will carry a pedometer throughout the duration of hospitalization. At the end of protocol, two groups will be made from the median of CSARF : patients with a small reduction in CSARF compared to patients with a greater reduction in SSRF between the second and eighth days of hospitalization (or between the second day of hospitalization and discharge). Then clinical (comorbidities, severity disease, initial weakness, initial amyotrophy, usual physical activity before hospitalization, treatment, exacerbation number in the previous year…) and biological (markers of inflammation and oxydative stress) determinants were compared between the two groups. Thus, the identification of the determinants associated with the onset of amyotrophy induced during exacerbation of COPD will guide research for exploration of physiopathological mechanisms of this muscular dysfunction in the exacerbation of COPD as well as to identify a personalized support.
Muscle atrophy and insulin resistance are common after bed rest in healthy older adults. Metformin treatment has been shown to improve insulin sensitivity and attenuate muscle loss in insulin resistance adults though the mechanisms are not fully known. Metformin used as a preventive strategy to maintain muscle and metabolic health in bed ridden older adults has not been investigated.