View clinical trials related to Muscular Dystrophies.
Filter by:The hypotheses is that regular post exercise supplementation increase fitness and daily activity level in patients with Fascioscapulohumeral (FSH) muscular dystrophy. All patients are tested before and after 12 weeks of cycle-ergometer exercise. Maximal oxygen consumption and 6MWT is used as primarily effect goals. Secondary effect goals are risk of falls and daily activity level.
The Finding the Optimum Regimen for Duchenne Muscular Dystrophy (FOR DMD) study will compare three ways of giving corticosteroids to boys with Duchenne muscular dystrophy (DMD) to determine which of the three ways increases muscle strength the most, and which causes the fewest side effects. Using the results of this study, the investigators aim to provide patients and families with clearer information about the best way to take these drugs.
On the basis of published data and the investigators' results indicating that oxidative stress may contribute to the peripheral skeletal muscle dysfunction in patients with FSHD, the investigators propose a study to test whether or not an antioxidant supplementation has a therapeutic interest for patients with FSHD. Their results have important implications for the successful implementation of rational antioxidant therapy in FSHD in which cell loss could be linked to oxidative stress.
PDE5A inhibition, which boosts NO-cGMP signaling, will relieve functional muscle ischemia and restore normal blood flow regulation (i.e., functional sympatholysis) during exercise in boys with DMD. The investigators specific aim is to perform an efficient dose-titration study to inform the design of a randomized multicenter trial of PDE5A inhibition for clinical skeletal muscle and cardiac endpoints.
Duchenne/Becker muscular dystrophy (DBMD) is a genetic disorder that develops in boys. It is caused by a mutation in the gene for dystrophin, a protein that is important for maintaining normal muscle structure and function. Loss of dystrophin causes muscle fragility that leads to weakness and loss of walking ability during childhood and teenage years. A specific type of mutation, called a nonsense (premature stop codon) mutation, is the cause of DBMD in approximately 10-15% of boys with the disease. Ataluren is an orally delivered, investigational drug that has the potential to overcome the effects of the nonsense mutation. This study comprises a Phase 3, open-label study of ataluren in participants with nmDBMD who previously received ataluren at an Investigator site in a prior PTC-sponsored clinical study. A separate open-label study (PTC124-GD-016-DMD; NCT01247207) is being conducted for nmDBMD participants who previously received ataluren at an Investigator site in the United States (US).
This is an investigation of the efficacy and safety of CRD007 in Duchenne Muscular Dystrophy (DMD), Becker Muscular Dystrophy (BMD) and symptomatic carriers.
The primary objective of this study is to assess the ongoing efficacy, safety, and tolerability of an additional 212 weeks of treatment with eteplirsen injection in Duchenne muscular dystrophy (DMD) subjects who have successfully completed the 28 week eteplirsen study: Study 4658-us-201. This study will also evaluate the correlation between biomarkers for DMD and the clinical status of participating DMD subjects.
Physicians seek a method to assess neuromuscular disease that is both non-invasive and quantifiable. Many patients do not tolerate standard current day assessment tools (such as needle electromyogram), and Electrical Impedance Myography (EIM) has the potential to serve as a non-invasive, quantifiable, diagnostic tool for neuromuscular disease. If successful, these devices will allow for improved ability to diagnose neuromuscular disease and to assess disease progression or remission, allowing for better care of individual patients as well as for use in clinical trials, where improved outcome measures for neuromuscular diseases is being sought.
The investigators are performing a gene therapy clinical trial in Becker muscular dystrophy (BMD) and sporadic inclusion body myositis (sIBM) patients. Both of these conditions have an important common feature: loss of ability to walk because of weakness of the thigh muscles. The investigators plan to do a gene therapy trial to deliver a gene to muscle called follistatin (FS344) that can build muscle size and strength. If successful, the investigators can increase the size of the thigh muscle and potentially prolong a patient's ability to walk. The gene will be carried into the muscle by a virus called adeno-associated virus (AAV). This virus occurs naturally in muscle and does not cause any human disease, setting the stage for its safe use in a clinical trial. Presently there is no treatment that can reverse Becker muscular dystrophy or sporadic inclusion body myositis. Only supportive care is currently possible. In this study, subjects with either of these diseases will have shots of the follistatin gene injected directly into thigh muscle on one (first cohort) or both legs (2nd and 3rd cohort). One hundred and eighty days following the gene delivery, the muscle will undergo biopsy to look closely at the muscle to see if the muscle fibers are bigger. Between the time of the gene transfer and the muscle biopsy, patients will be carefully monitored for any side effects of the treatment. This will include an MRI of the thigh muscle before treatment and at day 180 following treatment. Blood and urine tests, as well as physical examination will be done on the subjects during the screening visit and on days 0, 1, 2, 7, 14, 30, 60, 90, and 180 to make sure that there are no side effects from the gene injections. Sutures will be removed 2 weeks post-biopsy. Additional blood samples will be collected at 9, 12, 18, and 24 months. Patients will be seen at the end of 1st and 2nd years for a physical exam, assessment of muscle strength and appropriate blood tests.
This is a pilot clinical trial to assess the ability of a new ultrasound-based imaging method, Double-Push Acoustic Radiation Force (DP ARF) ultrasound, to monitor the progression of Duchenne muscular dystrophy. The hypothesis being tested is that DP ARF ultrasound delineates changes in muscle composition and function in individual dystrophic muscles, from early through late stages of disease development, that correlate to time to loss of ambulation in patient volunteers.