Active clinical trials for "Epilepsy"

The goal of this study is to determine whether there are unique markers on neuroimaging that are associated with depression in epilepsy.

This is a multinational, multicentre, non-interventional, retrospective data collection (manual Medical Chart Review).

Epilepsy is a group of neurological disorders characterized by propensity for spontaneous epileptic seizures. Epileptic seizures are the result of excessive and abnormal nerve cell activity in the brain. About 0.7-1% of the world population suffers from seizures. The most common treatment is based on seizure medications that enables about 2/3 of the patients to control their seizures. However, about 20 million patients worldwide, suffer from unpredictable seizures without remedy, and are resistant to medication. In this study EEG and other physiologic signals are collected using wearable sensors, from Epilepsy patients who are at risk of experiencing seizures. The collected signals will be used for developing algorithms that may identify pre-seizure and seizure related periods.

The principle aim of this project is to characterize the changes in relative stability of the intrinsic brain dynamics during onset of sleep and induction of general anesthesia. The investigators hypothesize that brain dynamics in the awake state are critical akin to physical systems close to a second order phase transition and that during loss of consciousness the dynamics move away from the critical point.

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.

The goal of this project is the development of an EEG-cap (min. 21 electrodes) with user-friendly active dry electrodes that meets the expectations of the users regarding comfort and esthetics, without losing sight of the functional and technical demands for recording high quality EEG signals. The purpose is to use the EEG-cap to investigate clinical neurological disorders (e.g. epilepsy). The EEG-cap could also be used at home so that hospital admission in the EMU can be avoided for some patients and an increasing number of patients can be examined. In this stage of the project video-EEG recording with the prototype will be compared to the conventional way (cup-electrodes and collodion) of recording in the EMU. Minimum 1 - maximum 10 patients with prominent IEDs will be included. After the conventional recording is completed, the patient will undergo a recording of maximum 5 hours with the prototype. There will be an visual and clinical evaluation of the EEG-signals (blinded) and a technical evaluation of the EEG-signals. User experience and experience of the EEG-technologists will also be collected.

This is an open label prospective study of the impact on healthcare utilization of a surface Electromyography (sEMG) based seizure detection system for detecting Generalized Tonic-Clonic (GTC) Seizures.

The mortality rate is increased in patients with epilepsy, and especially among patients with drug-resistant epilepsy. This increased mortality is mainly related to the risk of SUDEP whose incidence is between 3.5 and 9 per 1,000 for patients with drug-resistant epilepsy. The term SUDEP refers to a sudden death occurring in a patient with epilepsy in whom anamnestic and post-mortem evidence does not identify a particular cause. Experimental and clinical data strongly suggest that most of SUDEP result from a postictal respiratory dysfunction progressing to terminal apnea. Due to the major role of serotonin in regulating breathing rhythms and data in animal models of epilepsy, it is envisaged that an alteration of serotonergic systems of the brainstem and limbic regions may play a central role in the occurrence of SUDEP. The objective of this work is to look for abnormalities of the serotonergic transmission within regulatory regions of respiratory and autonomic functions in brain samples prospectively collected in patients died from SUDEP.

Refractory epilepsy, meaning epilepsy that no longer responds to medication, is a common neurosurgical indication in children. In such cases, surgery is the treatment of choice. Complete resection of affected brain tissue is associated with highest probability of seizure freedom. However, epileptogenic brain tissue is visually identical to normal brain tissue, complicating complete resection. Modern investigative methods are of limited use. An important subjective assessment during surgery is that affected brain tissue feels stiffer, however there is presently no way to determine this without committing to resecting the affected area. It is hypothesized that intra-operative use of a tonometer (Diaton) will identify abnormal brain tissue stiffness in affected brain relative to normal brain. This will help identify stiffer brain regions without having to resect them. The objective is to determine if intra-operative use of a tonometer to measure brain tissue stiffness will offer additional precision in identifying epileptogenic lesions. In participants with refractory epilepsy, various locations on the cerebral cortex will be identified using standard pre-operative investigations like magnetic resonance imagin (MRI) and positron emission tomography (PET). These are areas of presumed normal and abnormal brain where the tonometer will be used during surgery to measure brain tissue stiffness. Brain tissue stiffness measurements will then be compared with results of routine pre-operative and intra-operative tests. Such comparisons will help determine if and to what extent intra-operative brain tissue stiffness measurements correlate with other tests and help identify epileptogenic brain tissue. 24 participants have already undergone intra-operative brain tonometry. Results in these participants are encouraging: abnormally high brain tissue stiffness measurements have consistently been identified and significantly associated with abnormal brain tissue. If the tonometer adequately identifies epileptogenic brain tissue through brain tissue stiffness measurements, it is possible that resection of identified tissue could lead to better post-operative outcomes, lowering seizure recurrences and neurological deficits.

The DNA and Cell Bank of Instituts Federatifs de Recherche (IFR) of Neurosciences has been running for the last 15 years at the Institut National de la Santé Et de la Recherche Médicale (INSERM) Unit 679 (former unit 289). Since its creation, this structure has been the support of research projects in genetics for neurological and psychiatric disorders. The cohorts established have led to discoveries in monogenic disorders, such as cerebellar ataxias, spastic paraplegias, frontotemporal dementias, epilepsies, Parkinson's and Alzheimer's disease, Charcot-Marie-Tooth disease and related entities. The research projects based on the study of the genetic bases in Parkinson's disease and epilepsies are especially developed for this grant. Concerning Parkinson's disease, the project is based on the extension of the existing cohort throughout the French Parkinson's Disease Study Group network. Concerning epilepsies, this project is the occasion to build this network with the constitution of a new cohort. The specific aims of the scientific projects are the following for Parkinson's disease: to evaluate the frequency, the nature and the phenotype associated with parkin mutations in familial or sporadic forms of the disease, according to the age at onset, and to identify the genetic susceptibility factors in Parkinson's disease with the study of affected sibpairs and with case/controls association studies. For epilepsies, the aims are: to evaluate the frequency, the nature and the phenotype associated with SCN1A, SCNab and GABR2 gene mutations in familial or sporadic forms of the affection associated with febrile seizures, and to search for an intervention SCN1A, SCN1B and GABRG2 as susceptible genes in these forms of epilepsies.