View clinical trials related to Drug Resistant Epilepsy.
Filter by: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.
Drug resistant epilepsy is best managed by surgery. The goal of presurgical evalution is to correctly identify the epileptogenic zone, defined by the extent of cortical tissue that needs to be removed is order to achieve seizure freedom. When no causative lesion is identified, careful study of interictal activity is mandatory. Complementary analysis methods exist, designed to identify the source of electrical activity recorded with surface electro-encephalogram. While results are interesting in retrospective studies, the real clinical added value needs to be demonstrated with prospective studies. The company Epilog (Epilog, Ghent, Belgium) offers, with EPILOG PreOp®, a long-term EEG analysis to automatically detect epileptiform activity, combined with an estimation of the electrical source localization using a sLORETA inverse solution model. We will propose the EPILOG PreOp analysis to refractory epileptic patients with non-contributive cerebral imaging, under presurgical evaluation. By comparing the therapeutic decision with and without knowledge of the results of EPILOG PreOp®, we will establish the added clinical value of EPILOG PreOp®.
The aim of the proposed pilot study is to investigate patient tolerability and efficacy of moderate term, repeated exposure of Pulsed Low-Intensity Focused Ultrasound (PLIFUS) in patients with drug-resistant temporal lobe epilepsy.
The purpose of this study is to obtain preliminary data in advance of a larger clinical trial aimed to test whether a single session of green light exposure can lead to a clinically significant reduction in epileptic spikes in patients with medically-refractory epilepsy. As this is a potentially fragile patient population, the study will test safety and tolerability as well as efficacy.
To compare the efficacy of two less restrictive dietary therapies - LGIT and MAD, used for treatment of drug resistant epilepsy in children
The main objective of MAPCOG_SEEG is to create a database including brain recordings of cognition performed in clinical routine in patients during the pre-surgical SEEG assessment. This aims to be able to propose the first atlas of human cognition with a high temporal and spatial resolution.
This study consist of define anatomo-functional reorganization (plasticity) profiles for the mentioned cognitive functions, before surgery (chronic plasticity induced by the epileptogenic zone) in patients with drug-resistant epilepsy. For that, patients will have 2 MRI examinations, one before surgery and the second, between 3 and 8 months after surgery.
Drug resistant epilepsy constitutes about one third of all children diagnosed with epilepsy. Although ketogenic diet is being used for drug resistant epilepsy for almost hundred years, its restrictiveness and adverse effects interferes with its compliance. So less restrictive alternatives like Low Glycemic Index Therapy diet is gradually becoming more popular and its effectiveness is well established. Still the restrictiveness of such monotonous diets is one of the most significant issues for long term maintenance of children on dietary therapy. In this study, we are planning to compare the efficacy of daily and intermittent Low Glycemic Index therapy Diet in children aged 1-15 years with drug resistant epilepsy in a open labelled randomized controlled non-inferiority trial. The children in intermittent LGIT arm will receive the dietary therapy for five days of each week, alternating with a liberal diet on the rest of the two days of the week.
Focal Cortical Dysplasias (FCDs) are neurodevelopmental disorders that represent a major cause of early onset drug-resistant epilepsies with cognitive and behavioral impairments, carrying a lifelong perspective of disability and reduced quality of life. Despite a major medical and socio-economic burden, rationale therapeutic strategies are still under debate. Surgical removal of the epileptogenic brain area (Epileptogenic Zone) is the most successful treatment, yet it fails to control FCD-associated seizures in as much as 40% of cases. Precise definition and complete resection of the Epileptogenic Zone are the main determinants of outcome. In current practice of French centers, up to 80% FCD-patients require an intracranial EEG (icEEG) recording to accurately define the epileptogenic zone. However, the indications for icEEG in MRI-visible FCD remain empirical and are essentially based on expert opinion.
Neurologic disease with loss of motor function is a major health burden. Brain-computer interfaces (BCI) are systems that use brain signals to power an external device, such as a communication board or a prosthetic device, which may help people with loss of motor function. Electrocorticography (ECoG) has been used to decode hand movements and as a control signal for brain-computer interface (BCI). This study hopes to use a smaller spacing of ECoG to see if a better motor signal can be found and used as a BCI control signal.