View clinical trials related to Epilepsy.
Filter by:This is a a study to identify inherited disease genes. The study will use molecular techniques to map genetic diseases using techniques such as Affymetrix SNP chips. The powerful combination of the information generated by the Human Genome Project and technical advances such as microarrays enables attempts to identify genes responsible for inherited disorders more possible than ever before. Starting with even modest pedigrees of only a few individuals, or even single individuals, it is possible to identify the gene(s) involved. It is proposed to collect up to 20 ml of peripheral blood and/or buccal cell samples from subjects and relevant family members. Currently the following disorders are approved for investigation. The current list of disorders: Aarskog-Scott syndrome, Café-au-Lait spots, Cerebral cavernous malformation, delXp, del2q, del10p, del11q, del12p, del13q, del14q, del16q, del17q, del18q, del Xp21, Choreoathetosis, Congenital Vertical Talus (CVT), Clubfoot, Tarsal coalition and other congenital limb deformities, Cystic Fibrosis (CF)-like disease, Desbuquois syndrome, Droopy Eyelid syndrome (Ptosis), Fanconi-Bickel syndrome (FBS), FENIB (familial encephalopathy with neuroserpin inclusion bodies), FG syndrome, Idiopathic generalised epilepsy (IGE), Renpenning syndrome, transient neonatal diabetes with 6q UPD, translocation (13;14), translocation (3;8), translocation (2;18), Uncharacterized familial dementia and X-linked mental retardation (XLMR).
The goal of this study is to determine whether there are unique markers on neuroimaging that are associated with depression in epilepsy.
The primary goal is to determine whether hippocampal electrical stimulation (HS) is safe and more effective than simply implanting an electrode in the hippocampus without electrical stimulation (HI), in patients with mesial temporal lobe epilepsy (MTLE). This will be assessed by the rate of complex partial seizures per person-month over 6 months of follow-up in HS vs. HI. There are two treatment arms: 1) Hippocampal Electrode Implantation with Stimulation (HS). 2) Hippocampal Electrode Implantation without stimulation (HI). The investigators expect to demonstrate that HS is safe and superior to HI in controlling seizures in patients with MTLE.
Antiepileptic Drugs (AEDs) are the main treatment for epilepsy; however, only a limited number of AEDs are approved for use as monotherapy. The objective of this study is to evaluate the efficacy of BRV in the conversion of partial onset seizure patients from combination treatment to monotherapy.
Antiepileptic drugs (AEDs) are the main treatment for epilepsy; however, only a limited number of AEDs are approved for use as monotherapy. The objective of this study is to evaluate the efficacy of Brivaracetam (BRV) in the conversion of partial onset seizure patients from combination treatment to monotherapy
This study is intended to provide evidence that zonisamide is safe and effective in the treatment of myoclonic seizures. The total planned trial duration will be 6.5 months. After that, subjects who have completed the study will be eligible to enroll in an open-label extension study until zonisamide is marketed for this indication or further development in this indication stops. This extension study will be described in a separate protocol (E2090-E044-318).
Zonisamide is already marketed for the treatment of partial seizures in epilepsy. This study is intended to provide evidence that zonisamide is safe and effective in the treatment of primary generalised tonic-clonic seizures. The total trial duration will be 5.5-6.5 months. After that subjects who have completed the study will be eligible to enrol in an open-label extension study until zonisamide is marketed for this indication or further development in this indication stops. This extension study will be described in a separate protocol (E2090-E044-316).
The study is being done to understand why some patients with epilepsy (disease of recurrence of seizures) do not respond very well to drug treatment with anticonvulsants. Despite the availability of many anticonvulsants, about 30% of patients with epilepsy are resistant to them. The cause of the resistance is not clear, but one of the reasons could be an increased amount of proteins in the cells of the body called transporter proteins. Transporter proteins are a group of proteins that help to defend the body against toxins, including drugs, by pumping them out of the cells. Studies have shown that the number of transporter proteins is higher in the parts of the brain that trigger seizures when compared to other parts of the brain. Studies in animals have shown that taking an anticonvulsant with an inhibitor (meaning "to stop" or "to reduce") of a transporter protein can increase the concentration of that anticonvulsant inside the brain cells. The main purpose of the study is to determine if taking an anticonvulsant and a transporter protein inhibitor will change the brain concentration of the anticonvulsant. In this study, a single dose of phenytoin (Dilantin® is a brand name anticonvulsant which has phenytoin as its active ingredient), a commonly used anticonvulsant, will be given once by itself, and then will be given a separate time with a single (i.e. one time only) dose of probenecid. Probenecid, a medicine used commonly to treat gout (a disease of increased uric acid), is known to be an inhibitor of transporter proteins. The study will use electroencephalogram or EEG (recording of brain wave activities) to determine if the EEG pattern when probenecid is given, will be different from the EEG pattern when phenytoin is given alone. This will suggest that probenecid has affected the brain concentration of phenytoin.
Our hypothesis is that topiramate will reduce acute seizures after traumatic brain injury and will help prevent the development of epilepsy after traumatic brain injury.
This study will look for evidence that a virus called HHV-6B may be related to seizures and to a form of brain injury called mesial temporal sclerosis that is associated with seizures. The study will use new, more sensitive brain scans to try to detect brain regions that might be affected by the virus and will examine cerebrospinal fluid (CSF, the fluid that bathes the brain and spinal cord) for evidence of the virus as well. Healthy volunteers and people with seizures uncontrolled by anti-epileptic drugs who are between 18 and 45 years of age may be eligible for this study. Candidates are screened with a physical examination and laboratory tests. Participants undergo the following procedures: - PET scan. This test uses a radioactive chemical called 18FDG, which is detected by the PET scanner to obtain images of the brain. The subject lies on a table with his or her head positioned in the scanner. A swimming cap with a small light reflector is placed on the head to monitor the position of the head during the scan. A catheter (plastic tube) is inserted into an artery at the wrist or elbow crease of the arm for obtaining blood samples during the scan, and a second catheter is placed in a vein in the other arm for injecting the 18FDG. The scan takes up to 2 hours. A second scan may be done over an additional 15 minutes. - MRI. This test uses a strong magnetic field and radio waves to obtain images of the brain. The subject lies on a table that can slide in and out of a metal cylinder surrounded by a magnetic field. Most scans last between 45 and 90 minutes. - Lumbar puncture. The subject sits upright or lies on a table with the knees curled to the chest for this procedure. A local anesthetic is injected to numb the skin and a needle is inserted in the space between the bones in the lower back where the CSF circulates below the spinal cord. A small amount of fluid is collected through the needle. - Blood tests. About 4 tablespoons of blood are drawn for viral tests.