View clinical trials related to Muscular 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.
Intrathecal administration of Nusinersen, an antisense oligonucleotide capable of increasing Survival Motor Neuron protein production, has been tested in Spinal Muscular Atrophy (SMA) to improve motor function and survival. A feature of adult SMA patients is a progressive neuromyopathic scoliosis, so spinal nusinersen administration can be challenging. Landmark identification using a pre-procedure ultrasound (US) facilitates technical performance of spinal anesthesia and allows for the elimination of radiation exposure. The aim of this randomized prospectic study is to determine if the US assistance for spinal administration of nusinersen is able to increase the proportion at successful 1st needle insertion of the needle. Secondary outcome measures are procedure time, patient satisfaction and prevalence of postdural puncture headache. Patients will be randomlized to receive a US-assisted nusinersen administration or a landmark based nusinersen administration.
The Motor Function Measure (MFM), a reliable tool assessing motor function and its progression in most neuromuscular diseases, is widely used in France in many teams. It can be used regardless of the severity of the motor impairment or the ambulatory status of the patient, allowing its use throughout the whole follow-up period of the patient, even in case of the loss of walking. Two versions of the MFM exist, one composed of 32 items originally validated for patients from 6 years old (MFM-32) and a shorter version composed of 20 items originally validated for patients between 2 and 6 years old (MFM-20). In order to prove the possible use of MFM-32 as early as the age of 2 years to validly and reliably monitor the evolution of the motor function of children treated with Nusinersen, we propose in this project to study the sensitivity to treatment-induced change of MFM-32 and the validity of the scale in this population.
This is a single center, 22-month observational study of nusinersen treatment in adult patients with spinal muscular atrophy (SMA). There will be a total of seven visits. Nusinersen is provided as standard of care and not considered research in this study. Information will be collected regarding the general health, and function including muscle strength of, as well as any positive and/or adverse events experienced by the study participants.
The aim of the proposed project is to evaluate whether the metabolome of patients with spinal muscular atrophy (SMA) before the initiation of treatment with nusinersen differs from the metabolome of healthy individuals and whether it changes 14 months after treatment with nusinersen.
The purpose of this study is to investigate the neurophysiological contributors to muscle function following ACL Reconstruction and the influence of motor control biofeedback exercise on measures of muscle function. The research team hypothesizes that the application of motor biofeedback will increase cortical excitability of the quadriceps compared to the passive movement of the knee. This is a single session cross-over intervention study with a 1-week washout period between treatment arms.
This study aims in investigating the effects of a core muscles' strengthening program on core muscles' atrophy and contraction ability. Twenty healthy adults recruited and randomly assigned to either a 5-week training group developed to activate and strengthen local trunk muscles or a control group. The training program includes isometric bridging exercises from various positions and dynamic exercises for lumbopelvic stability. Core muscles' thickness will be assessed at rest and contracting conditions, prior and after the intervention, using ultrasonography.
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 strengh and muscle mass) is one of comorbidities affecting 30% to 60% of patients and playing a key role in their prognosis. During exacerbation, some studies have suggested an association between muscle dysfunction and modifications of inflammatory circulating factors such as CRP, TNF-alpha, IL- 6, IL8, but no exhaustive study has identified precisely one (or more) biomarker(s) that can induce this muscle wasting during the exacerbation of COPD. Our hypothesis is that the serum of exacerbated COPD patients represents a deleterious microenvironment for the muscle cells which would amplify the mechanisms of atrophy linked to hospitalization. Our team has already developed a cell culture model to study the effects of the plasma microenvironment on atrophy of cultured myotubes. The investigators have shown that the serum of COPD patients can induce muscle atrophy. The objectives of this study are : 1/ to evaluate the effects of circulating pro-inflammatory factors on atrophy and the myogenic capacities of muscle cells; and 2/ to identify one (or more) circulating biomarker (s) that may be responsible for the muscle damage induced by the microenvironment of hospitalized patients for exacerbation of COPD. First, myotubes and myoblasts of healthy subjects will be cultivated with 9 exacerbation copd patient serum or 9 copd patient serum or 9 healthy subject serum. Myotube diameters, atrophy, inflammatory and oxidative stress markers and alteration of the myogenic capacity of satellite cells will be compared between three groups. Second, the differential expression of circulating proinflammatory molecules will be compared in the serum of the three groups. Identifying circulating factors associated with muscle weakness 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. .