Active clinical trials for "Mitochondrial Diseases"

Past mitochondrial disease treatment studies have been unsuccessful in determining treatment efficacy, and a major factor has been the lack of validated biomarkers in mitochondrial myopathy (MM). There is currently a growing number of potential new treatments to be tested through MM clinical intervention trials, which has created a pressing need for quantitative biomarkers that reliably reflect MM disease severity, progression, and therapeutic response. The purpose of the study is to measure the efficacy of an electrochemical oxygen nanosensor to measure in vivo mitochondrial function in human muscle tissue, and its ability to discriminate MM patients from healthy volunteers. The data and results from this nanosensor study may contribute to current and future research, including improved diagnostic and therapeutic approaches for patients with mitochondrial disease.

Cell and mice studies suggest mitochondrial dysfunction may cause altered bone structure. Hypothesis: Decreased mitochondrial energy production affects bone cell development and activity negatively. Comparing humans with the mitochondrial DNA variant, m.3243A>G, pathogenic variants in POLG or TWNK genes to healthy controls, the aim is to evaluate the effect of mitochondrial dysfunction on: 1: bone-cell development and -activity in bone marrow stem cells and blood. 2: bone cell metabolism including glucose consumption. 3: bone structure assessed by electron microscopy and μCT scans of bone biopsies.

The overarching aim of this intervention study is to interrogate the interconnection between the muscle mitochondrial adaptations and the changes in muscle insulin sensitivity elicited by exercise training in individuals harbouring pathogenic mitochondrial DNA mutations associated with an insulin-resistant phenotype. In a within-subject parallel-group longitudinal design, participants will undergo an exercise training intervention with one leg, while the contralateral leg will serve as an inactive control. After the exercise intervention, patients will attend an experimental trial including: A hyperinsulinemic-euglycemic clamp combined with measurements of femoral artery blood flow and arteriovenous difference of glucose Muscle biopsy samples

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).

This is an open-label, multi-centre study in subjects with a genetically confirmed mitochondrial deoxyribonucleic acid (DNA) transfer ribonucleic acid (tRNA)Leu(UUR) m.3243A>G mutation who completed study KH176-202. In the KH176-203 study subjects will be receiving KH176 100 mg BID or KH176 50 mg bid in die (BID) (as determined by the investigator based on safety / tolerability considerations) for a year, thereby ensuring continued treatment with KH176 after study KH176-202. A final follow-up visit is scheduled 4 weeks after the intake of the last dose of study medication for patients not rolling over into the compassionate use program. Primary safety data and secondary efficacy (endpoint) data will be monitored and reviewed every three months by an independent Data Safety Monitoring Board (DSMB) to evaluate potential risks and benefits.

This is a parallel-arm, double-blind, placebo-controlled study with a screening phase that includes a 28-day run-in phase to establish baseline seizure frequency, followed by a 24-week, randomized, placebo-controlled phase. After completion of the randomized, placebo-controlled phase, participants may enter a 48-week, long-term, extension phase during which they will receive open-label treatment with vatiquinone.

Diabetes can lead to heart failure independently, but the underlying causes remain incompletely understood. The main aim of this study is to identify differential regulation of mitochondrial substrate utilization and complex activity in heart failure and type 2 diabetes mellitus (T2DM). For this, we will conduct a prospective, observational study to examine myocardial mitochondrial oxidative function and related metabolic parameters, gene expression, histological markers, and inflammation in cardiac tissue from patients with heart failure or patients after heart transplantation. We will further assess cardiac function using cardiac magnetic resonance imaging with and without stress protocols and magnetic resonance spectroscopy. Glycemic control/T2DM will be characterized by oral glucose tolerance tests. The results of this project will help to better understand the cellular mechanisms of the development of diabetic cardiomyopathy and contribute to the development of early diagnostic, as well as therapeutic approaches for the prevention and treatment of diabetic cardiomyopathy.

The study objectives are to evaluate the safety of a single intravenous (IV) infusion of autologous CD34+ cells enriched with placenta-derived allogeneic mitochondria in participant with primary mitochondrial disease associated with mitochondrial DNA mutations or deletions. 6 participants aged from 4 to 18 years old on the day of screening visit with primary mitochondrial disease associated with mitochondrial DNA mutations or deletions will be enrolled.

The specific aims of this study are (1) to determine the clinical phenotypes and natural history of hepatic RC and FAO disorders, (2) to determine the correlation between genotype and phenotype, (3) to determine if circulating biomarkers reflect diagnosis and predict liver disease progression and survival with the native liver, (4) to determine the clinical outcome of these disorders following liver transplantation, and (5) to develop a repository of serum, plasma, urine, tissue and DNA specimens that will be used in ancillary studies. To accomplish these aims, the ChiLDREN investigators at clinical sites (currently 15 sites) will prospectively collect defined data and specimens in a uniform fashion at fixed intervals in a relatively large number of subjects. Clinical information and DNA samples to be collected from subjects and their parents will enhance the potential for meaningful research in these disorders. A biobank of subject specimens and DNA samples will be established for use in ancillary studies to be performed in addition to this study.

The purpose of the study is to systematically characterize the clinical course of the progressive neuropathy and optic atrophy observe in pediatric and adult patients with biallelic mutations in the ferredoxin reductase gene.