View clinical trials related to Mitochondrial Diseases.
Filter by:Mitochondrial disorders are a group of inherited disorders causing malfunctional mitochondria. Mitochondria are found in every cell of the body, and the disorders therefore give symptoms from every tissue, especially those with high energy needs as the brain, heart and muscles. The disorders are highly disabling. The aim of the study is to investigate the relation between muscle strength and contractile cross sectional area (CCSA) in the leg of patients affected by mitochondrial diseases. The hypothesis is that there can be a disrupted relationship between strength and CCSA.
Mitochondrial Diseases are rare progressive, multi-system, often early fatal disorders affecting both children and adults. KH176 is a novel chemical entity currently under development for the treatment of inherited mitochondrial diseases, including MELAS (Mitochondrial Encephalomyopathy, Lactic acidosis, and Stroke-like episodes), Leigh's Disease and Leber's Hereditary Optic Neuropathy (LHON). KH176 is a potent intracellular redox modulating agent targeting the reactive oxygen species which are important in the pathogenesis of disorders of mitochondrial oxidative phosphorylation. After demonstrating a favourable safety profile in the pre-clinical testing, the safety, tolerability and pharmacokinetic and pharmacodynamic characteristics of the compound will now be evaluated in healthy male subjects in this trial
Diseases caused by brain energy supply defects can be innate (fibromyalgia secondary to familial mitochondrial disorders) or acquired (tardive dyskinesia or weight gain associated with prolonged antipsychotic use). Patients with these possible mitochondrial disorders will provide a baseline resting heart rate sample, ingest low-dose metformin (500 mg), and then provide an additional sample 2 hours later.
The purpose of this study is to gather preliminary data on whether bezafibrate can improve cellular energy production in mitochondrial disease. Mitochondrial diseases are rare inherited disorders that arise due to deficient energy production within the cells of the body. Consequently, the typical clinical features arise in organs with high energy requirements. Mitochondrial disorders exhibit highly variable clinical effects, both between individuals and within families. Characteristic symptoms include muscle weakness (myopathy), hearing loss, migraine, epilepsy and stroke like episodes in addition to diabetes and heart problems. Mitochondrial disorders can therefore impact considerably on both quality of life and life expectancy. Despite this, no proven disease modifying treatments are available. Pre-clinical studies have identified that several existing medications improve mitochondrial function. Of these, bezafibrate has the best supportive data and, because it is already licensed as a treatment for high blood fats, has a well characterised side effect profile. The investigators will therefore conduct a feasibility study of bezafibrate in people with mitochondrial myopathy. Ten affected participants will be recruited and will receive a titrating course of bezafibrate three times daily for 12 weeks.
The aim of this study is to assess nutritional intake (quantitatively and qualitatively), nutritional state and body composition of patients suffering from mitochondrial cytopathy, compared to healthy controls. The energy intake will be calculated through dietary protocols, the energy expenditure by indirect calorimetry and body composition will be performed with bio-impedance analysis. Further on, the investigators expect to be able to provide nutritional counselling to this population in order to increase energy and protein intake, which may improve health and well-being.
Phase 1/2, multi-center, randomized, double-blind, multiple ascending dose, placebo-controlled study that enrolled 36 subjects with mitochondrial myopathy associated with genetically confirmed mitochondrial disease to evaluate the safety, tolerability, pharmacokinetics (PK), and preliminary efficacy of MTP-131 in this patient population.
The purpose of this 3-year, multi-site, non-randomized, prospective, observational study is to characterize the natural history of Pearson Syndrome. The Syndrome is a rare mitochondrial disorder due to a large-scale mtDNA deletion. Children typically present in their 1st two years of life (most in infancy) with anemia and/or pancreatitis. Most individuals with Pearson Syndrome die in childhood. Those who survive evolve to Kearns-Sayre Syndrome/Chronic Progressive External Ophthalmoplegia (KSS/CPEO) although accurate survival estimates are not yet known.
The purpose of this study is to learn about the use of nutritional supplements in patients with mitochondrial disease.
The m.3243A>G mutation is the most frequent cause of mitochondrial disease in adults, for which currently no therapy is available and treatment is solely supportive. Since both malnutrition and obesity are frequently seen in these patients, an adequate nutritional intervention to improve body composition and function might improve the quality of life of these patients. Hypothesis / research questions Hypothesis part 1: Patients with mitochondrial disorders caused by the m.3243 A>G mutation have an increased risk for malnutrition. Hypothesis part 2 : Intervention study: Dietary intervention in adults with a mitochondrial disorder caused by the m.3243 A>G mutation has a positive effect on nutritional status, activity, hand grip strength, body composition, food intake, fatigue and quality of life.
The investigators are conducting a research study on nutrition in mitochondrial disease. The investigators are interested in the kind of carbohydrates that people eat. Carbohydrates are an important source of energy. Certain kinds of carbohydrates tend to raise blood sugar more in healthy people, and others tend to raise blood sugar less in healthy people. The investigators would like to know if by eating the "right" type of carbohydrate, people with mitochondrial disease can avoid high lactate levels, high blood sugar levels, and, later, low blood sugars. In this study, this question will be answered by finding out how people with mitochondrial disease respond to two different test meals containing different kinds of carbohydrates. Neither participants nor the investigators will know which kind of test meal participants are eating.