View clinical trials related to Muscle Atrophy.
Filter by:The SARS-CoV-2 pandemic causes a major burden on patient and staff admitted/working on the intensive care unit (ICU). Short, and especially long admission on the ICU causes major reductions in skeletal muscle mass (3-4% a day) and strength. Since it is now possible to reduce mortality on the ICU, short and long-term morbidity should be considered another principal endpoint after SARS-CoV-2 infection. Cachexia is defined as 'a complex metabolic syndrome associated with underlying illness and characterized by loss of muscle mass'. Its clinical features are weight loss, low albumin, anorexia, increased muscle protein breakdown and inflammation. There is strong evidence that cachexia develops rapidly in patients hospitalized for SARS-CoV-2 infection, especially on the ICU. Several mechanisms are believed to induce cachexia in SARS-CoV-2. Firstly, the virus can interact with muscle cells, by binding to the angiotensin converting enzyme 2 (ACE-2). In vitro studies have shown the virus can cause myofibrillar fragmentation into individual sarcomeres, in addition to loss of nuclear DNA in cardiomyocytes. Similar results were found during autopsies. On a cellular level, nothing is known about the effects of SARS-CoV-2 infection on skeletal muscle cells. However, up to 19.4% of patients present with myalgia and elevated levels of creatine kinases (>200U/l), suggesting skeletal muscle injury. Moreover, patients with SARS-CoV-2 infection are shown to have elevated levels of C-reactive protein and other inflammatory cytokines which can all affect skeletal muscles. The above mentioned factors are not the only mediators by which skeletal muscle mass might be affected in SARS-CoV-2. There are other known factors to affect skeletal muscle mass on the ICU, i.e. immobilization and mechanical ventilation, dietary intake (anorexia) and inflammatory cytokines. SARS-CoV-2 infection in combination with bed rest and mechanical ventilation can lead to severe muscle wasting and functional decline resulting in long-term morbidity. Until know there are no studies investigating acute skeletal muscle wasting in patients infected with SARS-CoV-2 and admitted to the ICU. As a result, there is a need of more in-depth understanding the effects of SARS-CoV-2 infection on muscle wasting. An optimal characterization of these effects may lead to improvement in morbidity and even mortality in the short and long term by the establishment of evidence-based rehabilitation programs for these patients.
Unfortunately, hospital-acquired weakness is highly prevalent among COVID-19 hospitalized patients, who often require prolonged bed-rest or paralytics for an extended period of time in order to maintain oxygenation. Prolonged bed rest has been associated with pronounced loss of muscle mass that can exceed 10% over the 1st week, which leads to functional impairment and complications post-hospital discharge. Physical therapy and in-hospital mobility program may reduce the incident of hospital-acquired weakness, but they are often impractical for COVID-19 patients. In particular, conventional mobility programs are challenging for those who are being treated in an intensive Care Unit. The purpose of this study is to test feasibility and proof-of-concept effectiveness of daily use of lower extremity electrical stimulation (EE) therapy, as a practical solution to address lower extremity muscle deconditioning, to address chronic consequences of COVID-19 including hospital-acquired weakness.
The overall objective is to evaluate the validity of bedside US of QMLT and MF-BIA by comparing measurements from US and MF-BIA to those estimates of lean body mass obtained from CT Scan of abdomen when done for clinical reasons. The investigators expect to observe a high degree of correlation between these 3 baseline measures and the changes in US measures and MF-BIA over time to correlate with changes to CT Scan measures of lean body mass.
While "conditioning" by exercise training has been widely evaluated, the available literature on "passive deconditioning" (i.e. forced deconditioning) is predominately limited to studies with or with almost complete mechanical and/or metabolic immobilization/sedation of the respective functional system (e.g. paralysis, bedriddenness). Vice versa, the effects of moderately long interruptions of dedicated types of exercise while maintaining everyday activity are rarely addressed. However, this topic is of high relevance, e.g. considering that breaks of health-related exercise programs due to increased family/occupational stress, vacation or temporary orthopedic limitation are rather frequent in everyday life. In the present project we aimed to determine the effects of 3 months of physical deconditioning due to COVID-19 induced lockdown after 13 month of high intensity endurance and resistance exercise in early postmenopausal women on parameters related to health and physical fitness.
This study evaluates the effect of a supervised exercise program on paraspinal muscle morphology and function, as well as disability/function in patients with non-specific chronic low back pain. Half of the participants will do a targeted paraspinal muscle exercise program, while the other half will do a general exercise program.
The purpose of this study is to determine whether massage can attenuate the loss of muscle mass in humans after a short period of disuse.
This study involves minimally-invasive techniques to measure muscle mass, muscle protein breakdown and synthesis simultaneously in older age.
The effect of different protein intakes on skeletal muscle atrophy during short term unilateral leg immobilisation.
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.
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.