View clinical trials related to Mitochondrial Myopathies.
Filter by:Positive effect of physical activity on health arouses a strong interest at international level and is developped within the scope of national programs. Recommandations exist but must be designed for patients with functional limitations of activities. Patients with mitochondrial diseases have exercice intolerance with an increase of muscular weakness and fatigue after low exercice volume. Theses patients have functional limitations of activities. In order to establish an appropriate training programme, it will be important to define and consider the physical condition. The Society of Mitochondrial Medecine published recommandations for management of theses patients,However, theses recommandations do not allow them to propose a training program of what can be done. For these vulnerable patients, therapists are responsible fo advising a training programm without guidelines to establish its terms and conditions. In addition, some exercices do not appear to have been the subject of complete assessmeents. Regarding training programs (aerobic training, muscle reinforcement, miwed training), scientific literature shows a significant genetic and clinical variabilities, as well as a lack of data on clinical severity of included patients. In addition, the lack of informations regarding training effects of heteroplamy level limits our comprehension of mechanisms involved in adaptation of mitochondrial pool during training. Therefore, further reserchs on this subject are essential. It is necessary to offer these patients a follow-up and personalized training program, which are in adequation with daily life. Some publications call on specifics concepts which are not compatible with day-to-day life. The investigators think it will be useful to investigate training effects in order to have practival conclusions, easily reproducible at home by patients with simple and inexpensive equipment. In this context, video consultation could allow the close follow-up of these patients. The investigators hypothesize that a mixed training (endurance and muscle reinforcement), personalized, at home and followed by video consultation have positive effects on some physical criteria (such as musclar strength, tolerance to effort, functional abilities) without increasing heteroplasmy and creatine phosphokinase levels.
This study is designed to evaluate the long-term safety and tolerability of REN001 administered once daily to subjects with PMM due to mitochondrial DNA mutations (mtDNA-PMM) or nuclear DNA mutations (nDNA-PMM). Subjects with mtDNA mutations will have previously completed Study REN001-201 or participated in Study REN001-101. Subjects with nDNA mutations who enroll in this study will be REN001- naïve.
The goal of this observational study is to develop and validate tools to measure disease course in patients with primary mitochondrial myopathy (PMM). The main aims of this study are: - Development, validation, and optimization of objective outcome measures for mitochondrial myopathy - Defining the natural history of mitochondrial myopathy Researchers will compare data from patients with primary mitochondrial myopathy to healthy controls. Data from healthy controls will also help define normative data for future studies. Participants will perform clinical exams of muscle strength and endurance and will complete surveys.
The aims of the current study are as follow: i) Evaluate the safety, usability, and acute efficiency of a powered knee-hip dermoskeleton (MyoSuit, MyoSwiss, Zurich, Switzerland) in patients with neuromuscular disorders, ii) Elaborate recommendations regarding usability criteria for safe and efficient use the device in patients with neuromuscular disorders (e.g. type and severity of patient's functional deficits), iii) generate necessary data to foresee a future study involving a home use of the device and assessment of long-term benefits.
Mitochondrial diseases caused by defects in oxidative phosphorylation (OXPHOS) due to heteroplasmic mitochondrial DNA (mtDNA) mutations are rare (frequency 1/5,000), but severe multi-system disorders. Clinical manifestations are highly variable, but predominantly affect energy demanding tissues, like brain and muscle. Myopathy is a common feature of mtDNA disorders, being present in more than 50% of the mtDNA mutation carriers, and seriously affects patients' general well-being and quality of life. Currently, no treatment is available for these patients, although the induction of muscle regeneration by exercise treatment has been shown to alleviate their myopathy. This implies that these patients can produce muscle fibres that perform better, most likely because the mutation load is lower. Mesoangioblasts (MABs) are myogenic precursors that have been recognized as a source for development of a systemic myogenic stem-cell therapy. Autologous MABs may be feasible for half of the mtDNA mutation carriers of 6 different mtDNA mutations, as their mtDNA mutation load in mesoangioblasts was (nearly) absent (<10%). However, there are many more mtDNA mutations in the 16.5kb mtDNA and the aim of this study is to determine the mtDNA mutation load in mesoangioblasts of other mtDNA mutation carriers and identify the patients or mutations for which this is a feasible approach.
The aims of the current study are as follow: i) Evaluate the safety, usability, and acute efficiency of a programmable ambulation exoskeleton (KeeogoTM Dermoskeleton System, B-Temia Inc., Quebec, Canada) in patients with neuromuscular disorders, ii) Elaborate recommendations regarding usability criteria for safe and efficient use the device in patients with neuromuscular disorders (e.g. type and severity of patient's functional deficits), iii) generate necessary data to foresee a future study involving a home use of the device and assessment of long-term benefits.
SPIMD-301 is a 48-week, randomized, double-blind, parallel-group, placebo-controlled trial to assess efficacy and safety of single daily subcutaneous (SC) administration of elamipretide as a treatment for subjects with primary mitochondrial myopathy associated with nuclear DNA mutations (nPMD).
Rationale: Mitochondrial disorders are progressive, often fatal multisystem disorders, in 20-25% of the cases caused by heteroplasmic mutations in the mitochondrial DNA (mtDNA). At this moment, there is no effective treatment known to influence the disease process or manifestation. Myogenic stem cell-based therapies complementing defective muscle cells and fibres, are highly promising to combat the myopathy and exercise intolerance which affect >50% of heteroplasmic mtDNA mutation carriers. Myogenic stem cells called mesoangioblasts (MABs), are currently the only myogenic precursors that fulfil all criteria to be used as advanced therapy medicinal product (ATMP) for systemic treatment. The researchers have demonstrated that MABs of most m.3243A>G carriers contain no or only a low amount (<10%) of the mtDNA mutation, allowing direct ex vivo expansion of patient-derived MABs. The overall aim is to induce muscle regeneration using these autologous MABs with a mutation load of <10%, as an advanced therapy medicinal product (ATMP). Objective: The phase I trial will consist of an intra-arterial injection (via catheter in femoral artery) of the autologous MABs in the left lower leg of 5 m.3243A>G patients.
This study is an observational longitudinal study involving the use of MRIs and video recordings taken at home of patients completing basic tasks. Once consent is obtained, subjects will be asked to schedule an appointment with radiology to undergo the listed MRIs of the heart and/or muscle. Subjects will also be given instructions on how to use the video recording app on their personal devices, or study provided device. The subjects will be followed regularly over the course of two years, submitting video recordings of their movements and reporting to Mayo Clinic for MRIs as scheduled.
In the Metabolic Disorder clinic at The Hospital for Sick Children, the investigators identified a male, proband with possible Luft's disease. The investigators hypothesize that Luft's disease is caused by excess or dysregulation of brown/beige fat tissue. To address the hypothesis, the investigators would like to assess brown fat distribution and activity in this subject.