View clinical trials related to MELAS Syndrome.
Filter by:The purpose of this study is to assesses the efficacy of oral supplementation with glutamine over three months on several amino acids and lactate concentration measured in cerebrospinal fluid and cerebral lactate measured by magnetic resonance spectroscopy.
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.
Mitochondrial diseases, estimated prevalence 1 in 4,300 adults, is caused by pathogenic mutations in genes finally encoding for mitochondrial proteins of the various enzyme complexes of the OXPHOS. Among these mutations, the 3243A>G nucleotide change in the mitochondrially encoded transfer RNALeu(UUR) leucine 1 gene (MT TL 1) is the most prevalent one. The OXPHOS dysfunction resulting from such mutations leads to increased production of reactive oxygen species (ROS), ultimately leading to irreversible oxidative damage of macromolecules, or to more selective and reversible redox modulation of cell signaling that may impact (adult) neurogenesis. Despite advances in the understanding of mitochondrial disorders, treatment options are extremely limited and, to date, largely supportive. Therefore, there is an urgent need for novel treatments. KH176, a new active pharmaceutical ingredient (API), is an orally bio-available small molecule under development for the treatment of these disorders (see Section 1.4). The current study will further evaluate the effect of KH176 in various cognitive domains and evaluate the effect of different doses of KH176 (See Section 1.5). In view of the growing recognition of the importance of mitochondrial function in maintaining cognitive processes in the brain, as well as the understanding of the safety profile and pharmacokinetics of KH176 following the two clinical studies described above, a more detailed study is indicated of the effects of KH176 in various cognitive domains, using the confirmed safe and well-tolerated KH176 dose of 100 mg bid, as well as a lower dose of 50 mg bid. The primary objective is an evaluation of KH176 in the attention domain of cognitive functioning, as assessed by the visual identification test score of the Cogstate computerised cognitive testing battery.
This will be a double blind, randomised, placebo controlled, single and multiple oral dose study conducted in 3 parts: Part A, Part B and Part C. Part A and Part B include healthy volunteers only and will be completed before Part C including patients with primary mitochondrial disease will be initiated. The starting dose in the first cohort of Part A will be 25 mg. The dose level in the additional cohorts will be decided following review of data of the previous cohorts.
The purpose of this First In Human study is to investigate the safety and tolerability of KL1333 after a single oral dose and to investigate the pharmacokinetic characteristics of KL1333 after a single oral dose.
This pilot clinical study, funded by the National Institutes of Health, will evaluate the safety and metabolic responses to a licensed inactivated seasonal influenza vaccine (TIV). This single arm study will consist of two cohorts: MELAS syndrome volunteers (a specific identified disorder of mitochondrial dysfunction: mitochondrial encephalopathy, lactic acidosis, and stroke-like episodes) between 13-60 years for OR adult control volunteers between 18-65 years of age. Both cohorts will receive the same treatment: a single vaccination with an FDA-licensed intramuscular seasonal trivalent inactivated influenza vaccine (TIV).
MELAS patients suffer from exercise intolerance, weakness, poor vision or blindness, poor growth, developmental delay, and deafness. They also have unique 'stroke-like' episodes (SLEs) which are not due to blockages of large or medium arteries. These 'strokes' are thought to be due to energy failure of very small brain blood vessels combined with energy failure in the mitochondria (cell battery) of the brain cells, especially in the back region of the brain in the vision centre. This leads to visual loss and paralysis. The overall goal of this study is to better understand the mechanism of these SLEs at the level of the brain cells and small blood vessels.
Introduction Baylor College of Medicine and Texas Children's Hospital are recruiting individuals with MELAS syndrome for a clinical study. MELAS syndrome is a mitochondrial disease; patients with this disease have muscle weakness and often develop brain strokes, where blood does not flow normally to different parts of the brain. It is believed that these strokes could be due to decreased production of nitric oxide, a naturally occurring compound important for normal blood vessel function. Nitric oxide is made from arginine and citrulline that are normally found in our bodies. What is the purpose of this study? The purpose of this study is to measure nitric oxide in individuals with MELAS and see if giving arginine or citrulline will increase the formation of nitric oxide. Nitric oxide is thought to be helpful in preventing strokes. Therefore, if arginine and/or citrulline are shown to increase the formation of nitric oxide, they could be used to prevent or treat the strokes in patients with MELAS syndrome.
The current study is a prospective evaluation of the ability of ketosis to shift mitochondrial DNA (mtDNA) heteroplasmy in subjects harboring a known mutation in their mtDNA at position 3243 (A>G). Subjects will be given supplemental medium chain triglycerides (MCTs) for a period of 6 months. mtDNA heteroplasmy will be measured 3 months prior to treatment, at treatment initiation, and 6 months after initiation. The primary objective of the current study is to determine if there is a shift in heteroplasmy in patients harboring the 3243 A>G mtDNA mutation to a more favorable (higher wild-type) profile while in a state of ketosis.
The purpose of this study is to compare the efficacy of two (2) different doses of idebenone with that of a placebo over a one month period on cerebral lactate concentration as measured by magnetic resonance spectroscopy.