Active clinical trials for "Epilepsy"

This is a retrospective non-interventional study to describe the HCRU and clinical outcomes before and after AspireSR® device implantation in subjects with drug resistant epilepsy at the Queen Elizabeth Hospital, Birmingham (QEHB).

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 Phase 2 of the project will comprise of an EEG-registration with the different types of electrodes in healthy volunteers. For each volunteer the EEG-recording with dry electrodes will be compared to the EEG-recordings with conventionally used wet electrodes (bridge and cup electrodes). In addition each volunteer will undergo a somato-sensory evoked potential (SSEP) measurement with different types of electrodes. Analogously to the EEG-registrations, for each volunteer the SSEP measurement with the dry electrodes will be compared to the SSEP measurement with conventionally used wet electrodes (bridge and cup electrodes). Each EEG-registration will take between 5 and 10 minutes. Minimum 2 - maximum 10 healthy volunteers will be included. There will be an visual and clinical evaluation of the EEG-signals (blinded) and a technical evaluation of the EEG-signals. User experience will also be collected.

This research is a feasibility study on a new generation of brain magnetic activity sensor which should allow the development of this modality, until now limited by its cost to a few large university centers. The measurement of magnetic activity allows the detection and localization of abnormal activities such as paroxysmal events occurring between seizures in patients with epilepsy as well as research into brain function. It is the only one, along with EEG and related techniques, to provide data related to the speed of the brain. MEG, by virtue of the properties of magnetic fields, has a greater potential than EEG for the detection and localization of the neuronal sources which cause it. The MEG sensors used until now use Superconducting Quantum Interference Devices (SQUID) components that are extremely sensitive but require complex instrumentation and only operate under superconducting conditions, resulting in prohibitive maintenance and cost. The alternative could come from a new magnetic activity sensor: the optical pumping magnetometers of the alkaline type. This preliminary study proposes to compare SQUID sensors with MPO He4 sensors for their ability to detect abnormal activities recorded in epileptic patients. Measurements that cannot be recorded simultaneously Two types of measurement will be compared with the reference that constitutes in-depth recording (Stereotactic-EEG or SEEG) used to precisely define the region of the brain to be resected in order to cure epileptic patients of their seizures. The expected results are a capacity of this type of sensors to detect epileptic activities equivalent to that of SQUIDs.

This study evaluates to what extend electrical source imaging (ESI) provides nonredundant information in the evaluation of epilepsy surgery candidates. Epilepsy surgery normally requires an extensive multimodal workup to identify the epileptic focus. This workup includes Magnetic Resonance Imaging (MRI), electroencephalography (EEG) without source imaging, video monitoring and when needed Positron Emission Tomography (PET), Magnetoencephalography (MEG), Single Photon Emission Computed Tomography (SPECT) and invasive EEG recordings using implanted electrodes. ESI estimates the location of the epileptic source with a high sensitivity and specificity using inverse source estimation methods on non-invasive EEG recordings. This study aims to investigate the clinical utility of ESI using low-density (LD, 25 channels) and high-density (HD, 256 channels) EEG. Clinical utility is defined in this study as the proportion of patients in whom the patient management plan was changed, based on the results of ESI. Should ESI be added to the routine work-up of epilepsy surgery candidates.

Children with refractory epilepsy who are candidates for a treatment with vagus nerve stimulation will be prospectively randomized into 2 arms. Vagus nerve stimulation parameters are programmed and adjusted during outpatient clinic visits, within the normal clinical practice.

The knowledge of encephalitis associated with antibodies targeting intracellular antigens, and neuronal surface antibody syndromes has expanded considerably in recent times. The primary purpose of the investigators protocole is to determine the incidence of anti-neuronal antibodies (blood and CSF) in a population of patients suffering from focal epilepsy of unknown cause to guide the management of these patients. The investigators hypothesis is that dysimmune encephalitis is more common than is suggested by the current literature, and that sometimes forms of encephalitis dysimmune "at minimum" can be observed only in the form of focal epilepsy without further manifestation associated.

The purpose of this study is to test microelectrodes in intracranial monitoring to see if they will provide novel information on the epileptic potential of the implanted brain tissue. A secondary objective is to investigate the activity of single neurons during specific cognitive tasks.

Epilepsy is a common disease affecting 0.5 to 1% of the general population. Epilepsies refractory to drug treatment lead to increased morbidity, mortality and high costs for public health (representing 75% of the costs associated with epilepsy is among the most costly diseases in Neurology). The only curative therapy is surgical removal or disconnection of the epileptogenic network. To do this, a comprehensive presurgical evaluation is essential to accurately define the location of the epileptogenic zone (EZ) and its relationship with the functional areas that must be preserved. This approach requires in some cases intracerebral EEG recordings. This latter technique, expensive and invasive, remains at present, the standard method in the location of the ZE. In this context, the development of non-invasive and inexpensive methods is a priority in the field. Moreover, many fundamental studies have shown changes in ion homeostasis including sodium associated with hyperexcitability related to epilepsy. The investigators team at CEMEREM, CHU Timone, specialized in the development and validation of innovative methods in MRI, has developed an in vivo sodium MRI acquisition and processing of data unique in France, capable of quantifying the intracerebral sodium concentration in three dimensions in a completely non-invasive and non-irradiating manner

Epilepsy is a major neurological disorder, affecting of the order of 0.5 to 1% of the population. It is a very invalidating disease, with high impact on quality of life. In a large proportion of cases, medication cannot prevent seizures; surgical removal of the regions responsible for seizures is then the only way to cure patients. However, results crucially depend on the correct delineation of the epileptogenic zone. In this context, computational modeling, under the form of a "virtual brain" is a powerful tool to investigate the impact of different configurations of the sources on the measures, in a well-controlled environment. In this project, the simulate in a biologically realistic way MEG (Magnetoencephalography) and EEG (Electroencephalography) fields produced by different configurations of brain sources, which will differ in terms of spatial and dynamic characteristics will be offered to participants. The research hypothesis is that computational and biophysical models can bring crucial information to clinically interpret the signals measured by MEG and EEG. In particular, the hypothesis can help to efficiently address some complementary questions faced by epileptologists when analyzing electrophysiological data. The strategy will be three-fold: i) Construct a virtual brain models with both dynamic aspects (reproducing both hyperexcitability and hypersynchronisation alterations observed in the epileptic brain) and a realistic geometry based on actual tractography measures performed in patients ii) Explore the parameter space though large-scale simulations of source configurations, using parallel computing implemented on a computer cluster. iii) Confront the results of these simulations to simultaneous recordings of EEG, MEG and intracerebral EEG (stereotactic EEG, stereoelectroencephalography (SEEG)). The models will be tuned on SEEG signals, and tested versus the surface signals in order to validate the ability of the models to represent real MEG and EEG signals. The project constitutes a translational effort from theoretical neuroscience and mathematics towards clinical investigation. A first output of the project will be a database of simulations, which will permit in a given situation to assess the number of configurations that could have given rise to the observed signals in EEG, MEG and SEEG. A second - and major - output of the project will be to give the clinician access to a software platform which will allow for testing possible configurations of hyperexcitable regions in a user-friendly way. Moreover, representative examples will be made available to the community through a website, which will permit its use in future studies aimed at confronting the results of different signal processing methods on the same 'ground truth' data.

This study will evaluate a type of Magnetic Resonance Imaging (MRI) sequence called arterial spin labeling (ASL). The investigators hope that ASL can better localize areas of the brain (lesions) that cause epilepsy. This type of MRI does not require contrast, does not use any radiation, and adds on 4 minutes to the routine MRI that is done for patients with epilepsy. The study hypothesis is that in patients with refractory epilepsy, Arterial Spin Labeling (ASL) MRI will show areas of abnormality in the brain to the same degree as single-photon emission computerized tomography (SPECT) and positron emission tomography (PET) studies.