View clinical trials related to Tay-Sachs Disease.
Filter by:The Myelin Disorders Biorepository Project (MDBP) seeks to collect and analyze clinical data and biological samples from leukodystrophy patients worldwide to support ongoing and future research projects. The MDBP is one of the world's largest leukodystrophy biorepositories, having enrolled nearly 2,000 affected individuals since it was launched over a decade ago. Researchers working in the biorepository hope to use these materials to uncover new genetic etiologies for various leukodystrophies, develop biomarkers for use in future clinical trials, and better understand the natural history of these disorders. The knowledge gained from these efforts may help improve the diagnostic tools and treatment options available to patients in the future.
The purpose of this study is to learn more about the natural history of Late Onset GM2 Gangliosidosis (Tay-Sachs disease and Sandhoff Disease) to inform future clinical trials.
Leukodystrophies, and other heritable disorders of the white matter of the brain, were previously resistant to genetic characterization, largely due to the extreme genetic heterogeneity of molecular causes. While recent work has demonstrated that whole genome sequencing (WGS), has the potential to dramatically increase diagnostic efficiency, significant questions remain around the impact on downstream clinical management approaches versus standard diagnostic approaches.
The primary objective of the study is to determine the safety and feasibility of intrathecal administration of DUOC-01 as an adjunctive therapy in patients with inborn errors of metabolism who have evidence of early demyelinating disease in the central nervous system (CNS) who are undergoing standard treatment with unrelated umbilical cord blood transplantation (UCBT). The secondary objective of the study is to describe the efficacy of UCBT with intrathecal administration of DUOC-01 in these patients.
The investigators hypothesize that a combination therapy using miglustat and the ketogenic diet for infantile and juvenile patients with gangliosidoses will create a synergy that 1) improves overall survival for patients with infantile or juvenile gangliosidoses, and 2) improves neurodevelopmental clinical outcomes of therapy, compared to data reported in previous natural history studies. The ketogenic diet is indicated for management of seizures in patients with seizure disorders. In this study, the ketogenic diet will be used to minimize or prevent gastrointestinal side-effects of miglustat. A Sandhoff disease mouse study has shown that the ketogenic diet may also improve central nervous system response to miglustat therapy (see Denny in "Citations" list below). Patients with infantile and juvenile gangliosidoses commonly suffer from seizure disorders, and use of the ketogenic diet in these patients may therefore also improve seizure management.
The investigators have developed a new website to educate persons of Ashkenazi Jewish ancestry about their increased risk for having children with certain genetic conditions, and the genetic testing the investigators offer. This study aims to pilot the website to find out whether it is effective and to learn what the investigators can improve. Participants in the study will be assigned to one of two conditions: 1. Standard in-person genetic counselling session to learn about inheritance of Ashkenazi Jewish genetic conditions and genetic testing. Participants will fill out two short questionnaires, one before and one after the genetic counselling session. They will then be given a requisition form to undergo blood draw for genetic testing at the Montreal General Hospital test centre. 2. Use of a web-based pre-test genetic counselling tool to learn about inheritance of Ashkenazi Jewish genetic conditions and genetic testing. They will fill out two short questionnaires, one before, and one after using the web-based tool. They will then be electronically sent a requisition form to undergo blood draw for genetic testing at the Montreal General Hospital test centre. In both conditions, genetic test results will be communicated by telephone once they are available. Participants' genetic test results will not be used in any way for the study.
Hypothesis: To study the natural history of Tay-Sachs disease and evaluate therapeutic interventions. This study is intended to work in collaboration with NCT00668187 "A Natural History Study of Hexosaminidase Deficiency." Because so few patients with Tay-Sachs disease present annually, we will maximize both research projects by enrolling patients in both studies. For this present study, we will perform retrospective medical record review to gather data. Through this medical record review, we will collect biomarker analysis results, neuroimaging report data, quality-of-life questionnaire data and ophthalmology exam findings. If the subject has undergone therapy or treatment, the results will be noted.
The goal of this research study is to establish chimerism and avoid graft-versus-host-disease (GVHD) in patients with inherited metabolic disorders.
The objectives of this clinical trial are to assess the safety and tolerability, as well as efficacy, of a stepwise dosing regimen of pyrimethamine, starting at 25 mg/day, given as a single dose daily for 4 weeks in patients affected with chronic Tay-Sachs or Sandhoff variants.
Adult Tay-Sachs disease and Sandhoff diseases are caused by deficiency of an enzyme called β-hexosaminidase A, or Hex A in short. This enzyme is located in a particular cellular component, called lysosomes, inside the brain cells. The reason that Hex A of patients with Adult Tay-Sachs disease or Sandhoff disease is deficient is because this enzyme had gone through mutation, resulting in it not working very well. In healthy people, Hex A efficiently breaks down GM2-ganglioside, which is a by-product from cells of our body. However, patients with Adult Tay-Sachs disease or Sandhoff disease cannot efficiently break down GM2-ganglioside in the body. Therefore, these patients have high levels of this by-product in the brain cells, which causes the brain to be unable to function normally. There is a drug called Pyrimethamine. This drug is used by doctors to treat specific types of infections called malaria and toxoplasmosis. Our laboratory test tube studies have shown that Pyrimethamine can help the Hex A enzyme to function in a normal manner. If Hex A can function normally in presence of Pyrimethamine, this drug should be able restore the brain malfunction of these patients since Hex A can now efficiently break down GM2-ganglioside with Pyrimethamine treatment. Although results from laboratory test tube studies are promising and Pyrimethamine should theoretically restore brain function of these patients, we do not know if Pyrimethamine is safe or if it would actually work in patients. This study is the first study (a Phase I study) of testing Pyrimethamine to treat Adult Tay-Sachs and Sandhoff diseases. The objective of this study is to see if Pyrimethamine is safe in these patients and to see if it can restore the brain function of these patients.