View clinical trials related to Mitochondrial Diseases.
Filter by:In this study, 50 children between 3 and 12 years old with formally diagnosed autistic spectrum disorders (ASD) and also having significant mitochondrial dysfunction will be treated for a 3 month period with the Mitochondrial Cocktail, a combination of specific nutritional supplements and metabolite intermediates (including anti-oxidants) and bio-energy substrates. A series of neurological and psychological evaluations will be conducted by trained evaluators/clinicians to evaluate both the severity and the clinical presentation of the ASD/mitochondrial dysfunction with each subject at baseline prior to treatment, after the 3 month treatment and again at 6 months, after another 3 month non-treatment period. In addition, laboratory investigations will be conducted at the same time-points to assess the mitochondrial dysfunction and cellular biomarkers thought to be associated with autistic and mitochondrial disorders. These investigations will include the analysis of samples of blood and cheek/buccal swabs collected from each child to assess select biochemical markers of ASD. The Mitochondrial Cocktail treatment will be administered at home once a day continuously for a total of 3 months. All the children in the study will be treated with the same Mitochondrial Cocktail (an open label study).
This pilot study is a prospective, randomized clinical trial to evaluate the effect of anesthesia in the mitochondrial dysfunction patient.
CoRDS, or the Coordination of Rare Diseases at Sanford, is based at Sanford Research in Sioux Falls, South Dakota. It provides researchers with a centralized, international patient registry for all rare diseases. This program allows patients and researchers to connect as easily as possible to help advance treatments and cures for rare diseases. The CoRDS team works with patient advocacy groups, individuals and researchers to help in the advancement of research in over 7,000 rare diseases. The registry is free for patients to enroll and researchers to access. Visit sanfordresearch.org/CoRDS to enroll.
The Metabolism, Infection and Immunity (MINI) Study is a longitudinal natural history study at the National Institutes of Health (NIH) that aims to define the relationship between infection, immunity and clinical decline in individuals with mitochondrial disease. Mitochondrial diseases are a group of disorders caused by problems with the cell s ability to produce energy. Infection in individuals with mitochondrial disease can lead to worsening clinical symptoms, particularly neurologic symptoms. Goals: The main goal of our study is to understand the relationship between infection and clinical decline in patients with mitochondrial disease. Mitochondrial diseases can affect many different parts of the body, including the immune system and its ability to respond to infection. Therefore, we perform a comprehensive evaluation of participants including a detailed immunologic assessment. We are not testing any new medicine or procedure to treat or cure IEM or mitochondrial diseases. However, by understanding the relationship between infection and mitochondrial disease, we hope to develop treatments in the future. At the NIH, we are interested in research. Although we do provide advice and care for people enrolled in our study, we are not able to take over the long-term care of participants. To enroll in our study, you (your child) must already have a confirmed diagnosis of a mitochondrial disease. We are not able to provide a "first time" diagnosis or regular metabolic care. What is involved? Once you contact our team members, you will be asked to provide medical records to determine eligibility. Our team will review the records and notify you if you (your child is) eligible to join the study. -Onsite participation: You (your child) will be invited to visit the National Institutes of Health in Bethesda, Maryland. This first visit will typically last 3-5 days. Depending on the level of participation, additional visits may be requested. Our team members will work with you and your child to coordinate the supports needed during your stay at NIH. Study participants may be seen in the clinic, day hospital or inpatient setting. When you (your child) arrive at the NIH we will have an informed consent discussion to confirm willingness to participate, answer questions and review the risks and benefits of the study. You (your child) will meet with a physician who will ask about medical and family history and do a physical exam (like in any doctor's office). We will ask all study participants to allow us to collect urine, draw blood, swab your (your child s) nose, and perform a detailed assessment. We may suggest additional evaluations or specialty consults for some participants based on clinical manifestations, age and level of independence. We will explain these studies to you (your child). They may include items such as- imaging studies, DEXA or MRI scan, energy expenditure or metabolic testing, developmental neuropsychological logical testing, physiatry, ophthalmology, or other consults. In some cases, we may request a skin biopsy (if one has not been done). You will receive the results of your (your child's) clinical testing and notes from any clinical consultations. -Remote participation: If you (your child) are unable to travel, you (your child) may be enrolled remotely for records review, questionnaires, and telethealth exams. Blood or other samples collection may be requested in coordination with local providers or lab testing companies
The North American Mitochondrial Disease Consortium (NAMDC) maintains a patient contact registry and tissue biorepository for patients with mitochondrial disorders.
Mitochondrial diseases are a heterogeneous group caused by genetic defects in mitochondrial DNA or in nuclear genes. POLG is the most frequently involved gene in mtDNA instability diseases resulting in mtDNA multiple deletion and/or depletion. It encodes the DNA polymerase gamma (POLĪ³), the only known DNA polymerase found in mammalian mitochondria. Mutations in POLG could explain 45% of familial progressive external ophtalmoplegia associated with multiple mtDNA deletions. However, in more than 70%, the analysis of the genes involved in mtDNA instability remains unsuccessful. To date, these genes are screened by sequencing methods that are not able to detect large-scale rearrangements. In order to detect possible large-scale rearrangements, the investigators propose to develop a new assay based on QMPSF (Quantitative Multiplex PCR of Short fluorescent Fragments) able to detect exon deletions and duplications. the investigators propose to screen the POLG gene by QMPSF in at least twenty patients with either no mutation or only one mutation detected in POLG and no mutation in other genes such as TWINKLE and ANT1. This study would allow the investigators to know if large-scale rearrangements occur in the POLG gene and to estimate their frequency in patients with mtDNA instability. These data are important to know if the sequencing analysis of POLG should be completed by the screening for partial deletions and duplications to ensure an accurate molecular diagnosis of these syndromes. Moreover, this method could be extended to ANT1 and TWINKLE genes.