Active clinical trials for "Drug Resistant Epilepsy"

Drug-resistant partial epilepsies are disabling diseases for which surgical treatment may be indicated. The determination of the area to be operated (or 'epileptogenic zone') is based on a bundle of clinical arguments and neuroimaging, having a direct impact on surgical success. Epileptic patients have electrical abnormalities that can be detected with surface electrophysiological examinations such as surface EEG or MagnetoEncephalography (MEG). The intracerebral source of these abnormalities can be localized in the brain using source modeling techniques from MEG signals or EEG signals if a sufficient number of electrodes is used (> 100, so-called high EEG technique Resolution = EEG HR). EEG HR and MEG are two infrequent state-of-the-art techniques. The independent contribution of EEG HR and MEG for the localization of the epileptogenic zone has been shown in several studies. However, several modeling studies have shown that MEG and EEG HR have a different detection capacity and spatial resolution depending on the cortical generators studied. Modeling studies suggest that MEG has better localization accuracy than EEG for most cortical sources. No direct comparison of the locating value of MEG and EEG HR for the localization of the epileptogenic zone has been performed to date in a large-scale clinical study. In this prospective study, 100 patients with partial epilepsy who are candidates for epilepsy surgery, and for some of them with intracranial EEG recording, will benefit from two advanced electrophysiological examinations including magnetoencephalographic recording (MEG). ) interictal electrophysiological abnormalities and high-resolution EEG recording (128 electrodes) in addition to the usual examinations performed as part of the pre-surgical assessment, prior to cortectomy and / or intracranial EEG recording. Based on recent work conducted in humans, we postulate: that the MEG and the EEG HR make it possible to precisely determine the epileptogenic zone, by using two approaches of definition of the epileptogenic zone (zone operated in the cured patients, zone at the origin of the crises during the intracranial recordings), but that the MEG is a little more precise than the EEG HR for the determination of the epileptogenic zone (we will try to highlight a difference of about 10%) that the quantitative study of the complementarity between EEG HR and MEG for modeling sources of epileptic spikes will show an added value in the use of both methods compared to the use of only one of the two methods that it is possible to determine the epileptogenic zone by determining the MEG model zone having the highest centrality value (hub) within the intercritical network by studying networks using graph theory.

The purpose of this study is to map the acute, short-term cortical evoked responses to thalamic electrical stimulation in persons with intractable epilepsy

The incident of epilepsy still very high in Indonesia, thus many patients become drug resistant epilepsy. As vitamin D has some anticonvulsant effect, the investigators want to study if an additional dose of vitamin D can help with the therapy responses.

Anxiety disorders have the highest prevalence among mental disorders and cause considerable individual and financial costs. Current treatments do not relieve mental suffering of many patients. Understanding neurobiological mechanisms involved in pathological anxiety is a major scientific challenge.

Epilepsy is a disorder of the brain which is associated with disabling seizures and affects 100,000 people under 25. Many children with epilepsy also have a learning disability or problems with development. Although better outcomes occur in children who are successfully treated early for their epilepsy, 25% continue to have seizures despite best medical treatment. One potential treatment is a neurosurgical operation to remove parts of the brain that generate seizures. A proportion of these children have electrodes inserted into their brains as part of their clinical assessment, termed stereoelectroencephalography (SEEG), to help localise these regions. Subsequent surgery is not always successful - up to 40% of children will have ongoing seizures 5 years after surgery. The purpose of this study is to assess the utility of specially designed SEEG electrodes which can measure signals from single brain cells. These electrodes record the same clinical information as normal SEEG electrodes and are implanted in the same way, but can give the research team extra information at the same time. The investigators aim to assess whether studying the changes in the firing of individual cells, both during and between seizures, improves our ability to localise seizures and therefore improve outcomes following surgery. As part of this research project, the investigators will not be doing anything that is not already part of the normal investigation and treatment for these children. Children will be recruited to the study during routine outpatient clinic visits. Surgical planning and execution will not be affected. The electrodes are CE licensed for clinical use and do not alter the risks of the operation. Following the period of monitoring, the care of these children would not be altered in any way. The investigators aim to recruit 30 patients over 3 years. In addition to dissemination via scientific publications and presentations, the findings will be shared with participants and the public.

Vagal nerve stimulation (VNS) can be indicated in patients with drug-resistant epilepsy who are not eligible for resective epilepsy surgery with responders rates about 50% (≥50% seizure reduction). At the moment, there is not a widely-accepted possibility to predict VNS efficacy in a given patient based on pre-implantation data, which can lead to unnecessary surgery and improper allocation of financial resources. The principal aim of PRECISE (PRediction of vagal nerve stimulation EfficaCcy In drug-reSistant Epilepsy) study is to verify the predictability of VNS efficacy by analysis of pre-implantation routine EEG. The PRECISE relies on the results of our previous work, which developed a statistical classifier for VNS response (responders vs. non-responders) based on differences in EEG power spectra dynamics (Pre-X-Stim). PRECISE is designed as a prospective multicentre study in which patients indicated to VNS therapy will be recruited. Patients will be classified as predicted responders vs. predicted non-responders using pre-implantation EEG analyses. After the first and the second year of the study, the real-life outcome (responder vs. non-responder) will be determined. The real-life outcome and predicted outcome will be compared in terms of accuracy, specificity, and sensitivity. In the meantime, the patients will be managed according to the best clinical practice to obtain the best therapeutical response.

This study will utilize computerized algorithms in combination with real-time intracranial neurophysiological and neurochemical recordings and microstimulation to measure cognitive and affective behavior in humans. Questionnaires or simple behavioral tasks (game-like tasks on a computer or an iPad) may also be given to additionally characterize subjects on related cognitive or affective components. Importantly, for the purposes of understanding the function of the human brain, neural activity can be recorded and probed (i.e. microstimulation) while subjects are performing the same computerized cognitive and affective tasks. These surgeries allow for the in vivo examination of human neurophysiology and are a rare opportunity for such research. In addition to computerized testing, the investigators plan to characterize subjects' behavior on related cognitive or affective components. Some neuropsychological questionnaires, many of which are administered for clinical reasons (listed below under study population), may also be given to patients and healthy control subjects. All patients undergoing epilepsy surgery (the population from which subjects will be selected) undergo a standard clinical neuropsychological battery to assess aspects of cognitive function. This is a regular aspect of their clinical assessment carried out prior to consideration for study inclusion. All participants are selected uniformly because they are undergoing surgery for subdural electrode implantation. No particular ethnic group or population is targeted by or excluded from the study. Those to be considered for inclusion in the proposed study performing more than 2 standard deviations below the mean on any aspect of cognitive functioning as determined by standard preoperative neuropsychological testing will be excluded from the study. No additional neuropsychological testing will be necessary as part of the study itself.

The goal of this clinical trial is to improve non-invasive identification of epileptogenic networks in drug-resistant epileptic patient. The investigators aim to compare epileptogenic network identification with stereo-EEG (used as glod standard) with the identification of the same network using advanced MRI (rs-fMRI, microstructural analysis of white matter, ...). The main goals are to: Compare the accuracy of network identification. Analyse the effect of the MRI sequences on candidates selection and target identification. Participants will already have been selected for stereoEEG and will undergo a supplementary MRI (about 1h) with the additional MRI sequences. Follow-up MRI are scheduled for patient undergoing a second, therapeutic epileptic surgery.

Background: - The blood-brain barrier separates the brain from the rest of the body. Epilepsy is a neurological disease that causes seizures. It can affect this barrier. Researchers think a contrast agent called mangafodipir might be better able to show areas of the brain that epilepsy affects. Objective: - To see if mangafodipir is well tolerated and safe. To see if it can show, on an MRI, areas of the brain that epilepsy affects. Eligibility: People ages 18-60 who: Have epilepsy not controlled by drugs Prior or concurrent enrollment in 18-N-0066 is required Design: Participants will be screened with: Medical history Physical exam Blood and urine tests Participants will have up to 6 visits in 1-3 months. Those with epilepsy will have an inpatient stay lasting 2-10 days. Visits may include: Video-EEG monitoring for participants with epilepsy An IV catheter put in place: a needle guides a thin plastic tube into an arm vein. Getting mangafodipir through the IV. 5 MRI scans over a 10-day period: a magnetic field and radio waves take pictures of the brain. Participants lie on a table that slides into a metal cylinder. They are in the cylinder for 45-90 minutes, lying still for up to 10 minutes at a time. The scanner makes loud knocking sounds. Participants will get earplugs. A final MRI at least 2 weeks after receiving mangafodipir. Gadolinium is given through an IV catheter....

This project forms a multi-site research collaboration to carry out verbal and spatial memory experiments in patient volunteers to better understand the neural bases of human memory, employing direct electrical brain stimulation as a tool to study those dynamics and their relationship to memory performance.