View clinical trials related to Ataxia.
Filter by:This study will determine the highest dose of idebonone that can safely be given to patients with Friedrich's ataxia, an inherited degenerative disease that causes loss of muscle coordination, speech problems, weakness and sensory loss. Enlargement of the left ventricle (the large pumping chamber of the heart) is also common in this disease. In studies in France and Canada, patients with Friedrich's ataxia who were given idebonone, an antioxidant similar to the dietary supplement coenzyme Q, had a decrease in the size of their left ventricle. Patients 5 years and older with Friedrich's ataxia may be eligible for this study. Pregnant and lactating women may not participate. Candidates will be screened with a medical history and physical examination and a review of genetic studies. Patients who have not had genetic studies will be offered genetic counseling and testing to confirm or rule out Friedrich's ataxia. Participants will be admitted to the NIH Clinical Center for 3 days. They will have blood and urine tests and a heart evaluation, including an echocardiogram-a procedure that uses sound waves to produce images of the heart, and an electrocardiogram-a study of the electrical activity of the heart. When these tests have been completed, patients will take an idebonone capsule. They will be monitored for side effects for 72 hours. Blood samples will be collected through an intravenous catheter (flexible plastic tube placed in a vein) 0.5, 1, 2, 3, 4, 6, 12, 24, 48 and 72 hours after the drug is taken to determine how long it takes for the drug to be eliminated from the body. Patients will return for a follow-up visit within 1 to 8 weeks. Those who experienced no serious side effects may receive another, higher dose of the drug, with at least 6 days between doses.
This study will screen patients with cerebellar ataxia to check for antibodies that indicate allergy to gluten (wheat protein) and will study the effect of a gluten-free diet in patients with these antibodies. Patients with cerebellar ataxia have problems with coordination, resulting in "clumsiness" and unsteadiness of posture and walking. There are many known causes of cerebellar ataxia, but in many patients the cause is unknown and there are no available treatments. Cerebellar ataxia has been recognized as a complication of celiac disease, a syndrome characterized by sensitivity to gluten. Recognizing gluten sensitivity in patients with cerebellar ataxia would be important for two reasons: it would be one of the rare causes of the disease that are potentially treatable, and it would identify patients at risk for developing gastrointestinal cancers, particularly intestinal lymphoma. Patients with cerebellar ataxia of known or unknown cause and normal healthy volunteers of any age are eligible for this study. All participants will have a medical history, physical examination, blood drawn (30 milliliters, or 2 tablespoons) to check for celiac disease antibodies, and possibly other lab tests. This completes the participation of normal volunteers. All patients will have magnetic resonance imaging (MRI) of the brain. This diagnostic tool uses a strong magnetic field and radio waves instead of X-rays to show structural and chemical changes in tissues. During the scanning, the patient lies on a table in a narrow cylinder containing a magnetic field. He or she can speak with a staff member via an intercom system at all times during the procedure. Scanning times vary from 20 minutes to 2 hours. Patients who have celiac disease antibodies will have an upper gastrointestinal (GI) endoscopy intestinal biopsy. For this procedure, a flexible tube is inserted into the mouth and down the throat into the stomach and duodenum (the upper part of the small intestine), where a small tissue sample is taken for microscopic examination. Patients with these antibodies will be put on a gluten-free diet and will be followed at NIH every 3 months for 12 months. On the first visit, patients will have their ataxia evaluated using NINDS's ataxia scale and will meet with a dietitian for instructions for a gluten-free diet. On the second through fifth visits (after 3, 6, 9 and 12 months, respectively, on the gluten-free diet), patients will have their ataxia evaluated, speak with a dietitian to assess their nutritional status, weight, and compliance with the diet, and provide a blood sample for celiac disease antibody testing. At the completion of the study, patients may choose to continue or stop the gluten-free diet. If the ataxia assessments show improvement, patients will be advised to continue the gluten-free diet permanently.
OBJECTIVES: I. Clinically evaluate members from families with a dominantly inherited ataxia and collect blood, skin and muscle samples for detailed molecular studies. II. Perform detailed clinical evaluations on patients with recessively inherited ataxias.
Positron Emission Tomography (PET) is a technique used to investigate activity in areas of the brain. The PET technique allows researchers to study the normal processes in the brain (central nervous system) of normal individuals and patients with neurologic illnesses without physical / structural damage to the brain. When a region of the brain is active, it uses more fuel in the form of oxygen and sugar (glucose). As the brain uses more fuel it produces more waste products, carbon dioxide and water. Blood carries fuel to the brain and waste products away from the brain. As brain activity increases, blood flow to and from the area of activity also increases. This is known as regional cerebral blood flow (rCBF). Knowing these facts, researchers can use radioactive water (H215O) and PET scans to observe what areas of the brain are receiving more blood flow. In this study researchers plan to investigate the changes in regional cerebral blood flow (rCBF) as patients participate in different activities. The activities are designed to stimulate the areas of the brain responsible for voluntary motor activity and sensation. By comparing the results of PET scans performed in different conditions, researchers can locate regions of the brain responsible for specific tasks. This study should provide new information about voluntary movements in humans and the preparation involved in controlling them.