View clinical trials related to Mitochondrial Diseases.
Filter by:MITOMICS aims to determine which RNA-Seq results (from muscle or fibroblasts) are the most informative for the interpretation of VUS identified by WES for patients suspected of mitochondrial myopathy. Analysis of RNA-Seq and WES results will performed with a computational approach using an autoencoder-based method
Mitochondrial DNA (mtDNA) depletion syndromes (MDS) are a genetically and clinically heterogeneous group of autosomal recessive disorders that are characterized by a severe reduction in mtDNA content leading to impaired energy production in affected tissues and organs. MDS are due to defects in mtDNA maintenance caused by mutations in nuclear genes that function in either mitochondrial nucleotide synthesis. MDS are phenotypically heterogeneous and usually classified as myopathic, encephalomyopathic, hepatocerebral or neurogastrointestinal. No efficacious therapy is available for any of these disorders. Affected individuals should have a comprehensive evaluation to assess the degree of involvement of different systems. Treatment is directed mainly toward providing symptomatic management. No treatment for MDS. Clinical trials studies and in vitro/in vivo research studies showed that the enhancement of the salvage pathway by increasing the availability of deoxyribonucleosides needed for each specific genetic defect prevents mtDNA depletion. Early recognition and immediate therapy to restore mitochondrial function could potentially improve clinical course. Confirming the benefit of deoxynucleosides as a safe and potentially efficacious therapy, will lead to the availability of the first specific and effective treatment for Mitochondria Depletion Disorders. In this phase II Trial a mix of Deoxynucleosides Pyrimidine (Deoxycytidine dC and Deoxythymidine dT) will be used as early treatment of MDS. The dose used has been already used in other clinical trials, and appears to effective and well-tolerated. The subjects included are children (0-18Y), with positive MDS diagnosis and express mutations in one of the following genes: POLG, C10orf2, RRM2B, MPV17, SUCLA2, SUCLG1, FBXL4. Subjects with MDS expressing neurological phenotypes dysfunction.
This project is a randomized controlled trial to use a mobile health journal, called Zamplo (formerly known as MyHealthJournal or ZoeInsights), to record patient reported outcomes (PROM) in patients with metabolic disorders. The objective of the study is to assess the feasibility, acceptability and potential effectiveness of the Zamplo. The primary hypothesis is as follows: The Zamplo platform will significantly increase patient activation at 6 months post-baseline, defined as an individual's knowledge, skill, and confidence for managing their health and health care. The primary outcome is as follows: Patient activation following the use of Zamplo will serve as the primary outcome of interest and will be measured by the Patient Activation Measure (PAM) 13. The PAM 13 shows the degree of the patient's ability to manage their health with confidence by providing a total patient activation score. Brief Background: This project is a randomized controlled trial to use a mobile health journal, called Zamplo, to record patient reported outcomes (PROM) in patients with metabolic disorders. Zamplo is a software as a service (SaaS) digital platform on both iOS and Android platforms that allows real-time entry of patient symptoms and response to medications. It provides the patients with an interface to see their progress, store questions that they will ask at the next clinic visit, record their health data and use their data to engage in their health outcomes. MAGIC Clinic Ltd., which is the largest clinic in Alberta that manages metabolic disorders such as Fabry disease, Pompe disease, and Gaucher disease, will provide access to Zamplo to patients free-of-charge to evaluate its utility in managing the symptoms of their disease. Brief Study Design: The study is a two-armed randomized controlled design with 1:1 allocation to treatment (Zamplo app group) or control (usual care) arms, with assessments at four time points: baseline, 1 month, 3 months (primary outcome), 6 months and 12 months follow-up post-baseline. This is an open-label trial. The investigators intend to recruit 150 participants in this study, with 75 of them being controls. Inclusion Criteria: Adult patients with a diagnosis of metabolic disease Access to a smartphone with data connection Willingness to devote 10-15 mins of time in a day to log medications and notes Able to speak and write English sufficiently to complete questionnaires. Exclusion Criteria: Insufficient cognitive function to participate in the study The use of any electronic application requires some competency with the software on a cellphone, downloading the application and entering the data. Some patients who are elderly may not be familiar with this technology and would be excluded.
Mitochondrial diseases (MDs) are the commonest group of inborn errors resulting from primary dysfunction of mitochondrial respiratory chain (MRC). High phenolics-containing extra-virgin olive oil (EVOO) can be one of the potential dietary supplements for the treatment of MD. Previous reports demonstrated that phenolics including oleuropein, oleocanthal, hydroxytyrosol and tyrosol found in EVOO have strong antioxidant properties against the oxidative stress in brain tissue and showed a protective effect on mitochondria by restoring mitochondrial enzymatic activities. This proposed study is an open-label pilot/ feasibility clinical trial using hydroxytyrosol (HT) as dietary supplements in a cohort of 12 MD patients recruited from the Hong Kong Children's Hospital (HKCH). The objective is to explore the longitudinal effect of receiving hydroxytyrosol (HT) as dietary supplements over a 12-month period and the change on a 6-month period after withdrawal. The applicability of the outcome measures will be evaluated in the current trial for future clinical studies and obtain relevant data for the next phase of the clinical trial on hydroxytyrosol (HT) efficacy. Besides, the tolerability of hydroxytyrosol (HT) in MD patients will be evaluated. The primary outcome measure is the functional assessment of the patient's clinical outcomes by International Paediatric Mitochondrial Disease Score (IPMDS). Secondary outcome measures included the measurement of biochemical and radiological parameters. Besides, tolerability and quality of life of the subjects will be determined. Relevant data including the feasibility of subject recruitment, withdrawal rate, feasibility of data collection of outcome measures, longitudinal effect of hydroxytyrosol (HT) on the outcome measures in the trial can be collected and analysed in this pilot study providing important information for the future clinical trials. The ultimate goal is to develop effective therapies to lower mortality, improve the clinical outcomes and quality of life in MD patients.
Background: Mitochondrial disease is a rare disorder. It can cause poor growth, developmental delays, muscle weakness, and other symptoms. The disease is usually inherited. It can be present at birth or develop later in life. Infection is a major cause of disease and death in people with this disease. Researchers want to learn more about how infection and the declining health of people who have this disease may be related to the COVID-19 pandemic. To do this, researchers will study the DNA of people who become ill with suspected or confirmed coronavirus. Their DNA will be compared to the DNA of their family members. Objective: To learn more about how genes may play a role in how COVID-19 affects people with mitochondrial disease. Eligibility: People age 2 months and older with mitochondrial disease and a suspected or confirmed diagnosis of COVID-19.<TAB> Design: Participants will complete a questionnaire about their health history. Their medical records may be reviewed. They will give a blood sample. If the participant becomes ill, they may have a videoconference with a doctor or nurse at the NIH to perform a physical exam. They may be contacted after their illness to give updates on their health. They may be asked to give extra blood samples or complete extra questionnaires. Participants genetic data will be put into a database. The data will be labeled with a code and not their name. The data will be shared with other researchers. Participation lasts about 1 year. This may be extended if the participant is very ill.
This study evaluates metabolic and functional parameters in the skeletal muscle of Parkinson's disease patients for comparison to a set of healthy age-matched controls.
Oxygen is required for an optimal muscle function. In patients with diabetes mellitus, hyperglycemia can cause vascular complications. The endothelium (inter layer of the blood vessels) can be damaged leading to a reduced oxygen flow towards the muscle cells. Besides, it is possible that mitochondrial dysfunction is occuring leading to reduced extraction of oxygen. Both conditions will lead to a reduced flow of oxygen towards the muscle and this can have impact on the production of energy necessary for optimal functioning. In this study, the investigators will examine the functionality of the blood vessels (1) and the uptake of oxygen into the muscles (2) in patients with diabetes mellitus type 1 and type 2 (with and without vascular complications) compared to healthy persons.
The Investigator proposes to record the fetal and postnatal development of children conceived using Mitochondrial Donation (MD) and to perform expert assessment of development at 18 months (corrected for gestational age) using the internationally validated Bayley-III developmental assessment tool.
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.
The MiDiSeq project will enroll 20 unresolved index patients with suspected mitochondrial disease prioritized for genomic analysis.