Active clinical trials for "Epilepsy"

Almost all patients with epilepsy living in the region of Paris have vitamin D deficiency, which is severe in 1/3 of the cases. The impact of this deficiency on epilepsy is unknown, despite the suggested benefits of vitamin D therapy including better seizure control and improvement of comorbidities (fatigue, anxiety, depression) in drug-resistant patients. Recommendations for vitamin D supplementation based on the serum level in the general population cannot be applied to patients with epilepsy due to interference of antiepileptic drugs in the vitamin D metabolism. Animal models, mechanisms of action studies and ecological information provide objective data for a direct antiepileptic effect of vitamin D. Human studies seem to confirm the antiepileptic effect of vitamin D but there are no controlled studies on large populations. The investigators aim to assess prospectively the effect of the treatment of vitamin D deficiency providing a high level of evidence. The investigators propose a multicentre placebo controlled randomized double-blind study, testing vitamin D supplementation against placebo in 400 drug-resistant patients to assess the short-term (3 months) and long-term (1 year) benefits on epilepsy. The investigators hypothesize that the treatment of vitamin D deficiency will result in significant reduction of seizure frequency, and improvement of comorbid symptoms as well as quality of life. The impact on the care of patients is important because better epilepsy control allows reduction of the antiepileptic drugs and side effects. This again is a key for the recovery of social and professional activities, and reduction of costs related to the disease.

Benign epilepsy with centro-temporal spikes is the most common type of focal epilepsy in children. It is known to be age-dependent and presumably genetic. Age of onset ranges from one to fourteen years and it represents fifteen percent to twenty five percent of epilepsy in children under 15 years of age.

Epilepsy is a neurological disease that can cause many comorbid psychiatric disorders, among them: generalized anxiety disorder and depression. Many studies suggest a temporal relationship between exposure to a traumatic event and the development of epilepsy. The objective of this research is to study the symptoms of post-traumatic stress disorder (PTS) in patients with epilepsy, and their relation to anxiety and depression in these patients. The investigators also wish to study how such symptoms may be associated with the subjective semiological manifestations of epileptic seizures. In addition, it has been shown that patients with epilepsy are able, from the identification of different warning signs, to anticipate their vulnerability to having an epileptic seizure allowing them to set up different types. strategies to control them. The investigators also wish to study the cognitive processes involved in this control and the influence of PTS symptoms, in particular hypervigilance on this behavior. The investigators propose a protocol using different types of measures: emotional, cognitive and physiological in order to answer our questions. In addition to patients with epilepsy, two groups of patients will be included: a group of patients with another chronic non-neurological disease to compare the prevalence of PTS symptoms and a group of patients with post-traumatic stress disorder ( PTSD) to compare with patients with epilepsy, cognitive and physiological measures. Finally, the results of this study should allow to develop tools for assessing PTS symptoms in epilepsy and to develop specific management approaches

This study is designed to investigate whether light therapy may be an effective treatment for some people with epilepsy. Light treatment is already an established treatment for depression. The chemical systems in the brain that are disrupted when someone becomes depressed, overlap with some of those that can be affected during some epileptic seizures. The investigators have designed this study to see whether light therapy may also lead to a decrease in seizures in people who have epilepsy. The study will be a placebo controlled trial. This means that half of the participants will receive a therapeutic dose of light therapy from a light box, whilst the other half will only receive a placebo light treatment.

Background: People with epilepsy often have auditory processing disorders that affect their ability to hear clearly and may cause problems with understanding speech and other kinds of verbal communication. Researchers are interested in developing better ways of studying what parts of the brain are affected by hearing disorders and epilepsy, and they need better clinical tests to measure how individuals process sound. These tests will allow researchers to examine and evaluate the effects of epilepsy and related disorders on speech and communication. A procedure called a magnetoencephalography (MEG) can be used to measure the electrical currents involved in brain activity. Researchers are interested in learning whether MEG can be used to detect differences in the processing of simple sounds in patients with epilepsy, both with and without hearing impairments. Objectives: - To measure brain activity in hearing impaired persons with epilepsy and compare the results with those from people with normal hearing and epilepsy as well as people with normal hearing and no epilepsy. This research is performed in collaboration with Johns Hopkins Hospital and epilepsy patients must be candidates for surgery at Johns Hopkins. Eligibility: Individuals between 18 to 55 years of age who (1) have epilepsy and have hearing impairments, (2) have epilepsy but do not have hearing impairments, or (3) are healthy volunteers who have neither epilepsy nor hearing impairments. Participants with epilepsy must have developed seizures after 10 years of age, and must be candidates for grid implantation surgery at Johns Hopkins Hospital.. Design: This study will require one visit of approximately 4 to 6 hours. Participants will be screened with a full physical examination and medical history, along with a basic hearing test. Participants will have a magnetic resonance imaging (MRI) scan of the brain, followed by a MEG scan to record magnetic field changes produced by brain activity. During MEG recording, participants will be asked to listen to various sounds and make simple responses (pressing a button, moving your hand or speaking) in response to sounds heard through earphones. The MEG procedure should take between 1 and 2 hours. Treatment at NIH is not provided as part of this protocol.

The progressive myoclonus epilepsy of the Unverricht-Lundborg disease (ULD) type is an autosomal recessive disease characterized by progressive stimulus-sensitive and action-related myoclonic jerks. The mainstay of the current treatment in myoclonic epilepsies including ULD are valproic acid and clonazepam among several other antiepileptic drugs. Unfortunately the disease may often be resistant to antiepileptic drugs leading to major reductions in daily activities and disability to walk without assistance. Therefore new treatment modalities are needed. Experimental treatments of ULD patients with dopamine agonists have relieved myoclonic symptoms. Further, in accordance with this, a recent study indicates decreased dopaminergic neurotransmission in the basal ganglia of ULD patients, determined by PET. The purpose of this study is to investigate the effect of dopaminergic medication (ropinirole hydrochloride, Requip ®) on relieving the symptoms of ULD patients. Patients will undergo sixteen weeks intervention period. The main efficacy determinants are changes in unified myoclonus rating scale (UMRS), nerve conduction, multi-modality evoked potentials including visual evoked potential (VEP), somatosensory evoked potential (SSEP) and brainstem auditory evoked potential (BAEP), blink reflex habituation and electroencephalography (EEG). Tolerability and the safety of the medication are determined. The study setting is placebo controlled, crossover, two-group and double blind study.

This is an open randomized controlled study in children with mental retardation and refractory epilepsy in which treatment with ketogenic diet (KD) is compared with treatment with the antiepileptic drug (AED), not tried by the patient before, which we consider to be the most appropriate AED for the patient.

This study will investigate the role that a brain chemical called serotonin plays in seizures. Serotonin, present naturally in the brain, helps transmit signals between nerve cells. Glucose is a sugar that is the main fuel of the brain. Studying these two chemicals may help explain why people with epilepsy get seizures and are more likely to be depressed. Healthy volunteers and patients 18 to 60 years of age who have epilepsy with or without depression and whose seizures are not controlled by medication may be eligible for this study. Candidates are screened with a review of their medical history, a physical examination and an electroencephalogram (EEG, brain wave recording). Participants undergo the following procedures: Positron emission tomography (PET) scans: The first of three PET scans measures brain blood flow and the activity at some of the brain serotonin receptors (the parts of brain cells to which serotonin attaches). A second scan measures the amount of serotonin transported between brain cells. A third scan measures glucose use. The PET scanner is shaped like a doughnut. The subject lies on a bed that slides in and out of the scanner with his or her head inside the opening. A special mask is fitted to the subject s head to help keep it still during the procedure so the images will be clear. For the first scan, catheters (plastic tubes) are placed in an arm vein to inject a radioactive substance and in an artery in the wrist to collect blood samples. The other two scans require only the catheter in the arm. Magnetic resonance imaging: This test uses a strong magnetic field and radio waves to obtain images of the brain. The scanner is a metal cylinder surrounded by a strong magnetic field. The subject lies on a table that can slide in and out of the cylinder. Most scans last between 45 and 90 minutes. Subjects wear earplugs to muffle loud knocking noises that occur during scanning. Psychological evaluation: Subjects are interviewed and fill out questionnaires to help study sadness and depression in epilepsy. Blood draw: Blood tests look for differences in genes between people with epilepsy who are depressed and those who are not.

The purpose of the study is to examine the clinical safety, tolerability, and efficacy of clobazam (Onfi) when it replaces the pre-existing clonazepam therapy in patients with refractory epilepsy.

This protocol has three purposes: 1) to screen patients with seizures for participation in research studies of NINDS s Clinical Epilepsy Section (CES), 2) to follow the natural course of seizure disorders, and 3) to train CES fellows in evaluating and treating epilepsy. Only standard diagnostic tests and treatments will be used in this study. Patients of any age with seizures who are referred to CES may participate in this study. At the end of the study, patients may be discharged to the care of their referring physician, offered participation in another NINDS research protocol, or followed for teaching purposes. Participants will undergo standard diagnostic procedures used to determine the type of their seizures, what part of the brain they are coming from, what is causing them, and whether standard drug treatments can help them. These may include some or all of the following: Physical and neurological examination Neuropsychological tests tests of learning and memory Electroencephalography (EEG) brain wave recording Evoked potentials tests of nerve reactions to lights and sounds Polysomnography simultaneous recordings of brain waves, breathing and eye movements Video-EEG monitoring simultaneous recording of seizures using a video camera and brain waves Video-EEG monitoring with extra electrodes to record muscle activity, breathing and eye movements for analyzing sleep patterns Imaging studies, such as magnetic resonance imaging (MRI) and positron emission tomography (PET) scans to examine the structure and function of the brain Frequent blood tests to measure blood levels of anti-seizure drugs