Active clinical trials for "Epilepsy"

Onchocerciasis is a neglected tropical disease associated with epilepsy, particularly in areas of high Onchocerciasis volvulus transmission. Onchocerciasis-associated epilepsy is characterised by seizures that start between the ages of five to 18 years. The tropical disease can be controlled through community-directed treatment with ivermectin (CDTi). Mahenge, in Tanzania, had a high prevalence of onchocerciasis and epilepsy despite more than 20 years of annual CDTi. Hence, the Tanzanian Neglected Tropical Diseases Control Programme has switched from annual to bi-annually CDTi since 2019. After this switch, the CDTi coverage increased and was sustained in both ivermectin rounds in 2021, and the number of new epilepsy cases decreased. The latter were persons who did not take ivermectin the year they had the first seizures. Hence, all ivermectin-eligible children at risk of onchocerciasis should take ivermectin at least annually. Overall, increasing the frequency and coverage of the CDTi programme should be considered in onchocerciasis-endemic areas with a high prevalence of epilepsy.

Clinically validate a biopotential and motion recording wearable device (Byteflies Sensor Dot) for detection of epileptic seizures in the epilepsy monitoring unit (EMU) and at home.

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 1 of the project epilepsy patients and their family will be interviewed about their personal experiences with the condition, EEG registrations, daily life, ... . In addition EEG-technologists and neurologists will be interviewed about their experience with EEG registrations and what features their dream EEG-cap would have. The purpose is to gain insight in the wishes and expectations of the end users so we can take this into account when designing of the EEG-cap. This interview is anticipated to take approximately 1 hour. Minimum 5 - maximum 50 patients and their family will be interviewed. Minimum 5 - maximum 50 EEG-technologists or neurologists will be interviewed. The results of the interviews will be analysed by the design company pilipili nv.

This prospective research aims to develop the use of Spectral Imaging in addition Dynamics of cortical electrical stimulation to identify major anatomical and functional networks in epileptic patients candidates for surgery and explored by stereoencephalography, to minimize risk of post-surgical cognitive deficits.

The SEMAINE project will investigate intracranial EEG (icEEG) simultaneously recorded with either fMRI or MEG to 1) improve identification of the epileptogenic zone in patients suffering from drug-resistant partial epilepsy, and 2) define the functional organization of neural networks underlying human perception and cognition in order to prevent inadvertent deficits resulting from neurosurgical resection. In particular, high-frequency activity (HFA), as measured with icEEG, has been demonstrated in recent years as a relevant index for both epileptogenic tissue and healthy cortical processing, but its correlates in fMRI and MEG require further investigation. This will be a pioneering effort in several respects, as the first to directly measure high-frequency neural activity in tandem with fMRI, and among the first to do so with MEG. In addition to their attractiveness as noninvasive imaging techniques, fMRI and MEG have the potential to examine whole-brain networks that are not accessible to icEEG's necessarily limited spatial coverage. Furthermore, such a campaign of simultaneous recordings will take unprecedented advantage of icEEG as the bridge between the two noninvasive techniques, providing compelling evidence for the links between all three measurements with respect to underlying high-frequency neural activity in both health and disease. This project will therefore lead to improved selection of epilepsy surgery candidates and improved neurosurgical outcomes from the precise mapping of epileptogenic and healthy brain networks. The same techniques will be immediately applicable to functional mapping of other types of neurosurgery populations as well as diagnostic neuroimaging of neurological and psychiatric populations.

In this pilot study, the researchers investigated the feasibility of a closed-loop electroencephalography (EEG) / transcranial direct current stimulation (tDCS) system for treatment of epilepsy. They looked to see the feasibility of triggering tDCS stimulation within 10 seconds of a detected EEG partial-onset seizure, and also a proof-of-principle determination of whether tDCS applied during this vulnerable period may be feasible to prevent the oncoming seizure. This study required 5 visits over the course of approximately 8 weeks. Each visit was separated by at least 2 weeks. Two of the visits had 24-hour EEG monitoring sessions. During these two sessions, the EEG and tDCS were hooked into a closed loop system, such that when seizure activity wasdetected, the tDCS was triggered to deliver stimulation. Subjects received active stimulation or sham stimulation sessions during the first 24-hour visit, and the opposite during the second. The subjects were randomized and counterbalanced. We have also added a healthy subjects cohort to assess the feasibility of the closed loop system. In order to test the proof-of-concept of this system, the experiment will focus on detecting and acting upon alpha- and beta-band changes traced in the EEG activity that is being recorded, and provide tDCS stimulation based upon those changes. We will enroll 6 subjects who will have 2 visits each. During these two visits subjects will be randomized to active or sham stimulation sessions and receive the opposite during their second visit.

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. Phase 3 of the Project will be divided into a Phase 3a and Phase 3b. Phase 3a of the project will comprise of an EEG-registration with the different types of electrodes in epilepsy patients with prominent interictal epileptiform discharges (IEDs) on EEG. For each epilepsy patient the EEG-recording with dry electrodes will be compared to the EEG-recordings with conventionally used wet electrodes (bridge and cup electrodes). Each EEG-recording will take approximately 10 minutes. Minimum 2 - maximum 10 epilepsy patients 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.

The first aim of this study are to evaluate the lobar concordance of FDG-PET and MEG with intracranial electrographic study in children with intractable partial epilepsy. The second aim is to determine if the combined role of FDG-PET and MEG improve detection of epileptogenic zone as defined by invasive intracranial recordings.

The purpose of the study in Part 1, is to evaluate (under fasted conditions) the plasma pharmacokinetics (PK) of padsevonil (PSL) using 4 PSL product variants against a PSL reference tablet and in Part 2, to evaluate the PK of PSL using a PSL reference tablet under fed and fasted conditions at 200 mg and 400 mg.

In this study, the investigator aims to perform cortical stereo electroencephalogram (sEEG) recordings during simultaneous anterior nucleus of the thalamus (ANT) recording and stimulation to better understand the following: 1) how the ANT is involved in various seizure types; 2) which cortical regions are modulated by established ANT stimulation patterns; and 3) how novel ANT stimulation patterns modify epileptogenic cortical activity. Together, this knowledge will advance ANT deep brain stimulation (DBS) therapy by providing a physiologic basis for patient selection for ANT DBS, while identifying brain signals and stimulation patterns that can be used to develop novel methods for ANT DBS. Up to 15 adult patients (18 and older) who present to Duke Neurosurgery for routine seizure localization using sEEG will be asked to enroll in this pilot study of ANT recording and stimulation. In the course of surgical epilepsy treatment, patients routinely undergo surgical placement of sEEG electrodes for the purposes of seizure localization. During this procedure, 2 additional leads will be placed in the ANT. These patients remain hospitalized for 7-14 days after sEEG placement, during which time their seizure medications are tapered. Concurrent video monitoring is performed while continuous neural recordings are made through the sEEG electrodes. Additionally, continuous recordings will be performed through the electrodes placed in the thalamus. Periodically, standard intermittent high-frequency stimulation (130 Hz, 90-ms pulse width, and 2 mA intensity) will be performed with a 60-s on and a 300-s off cycle after surgery. These standard ANT stimulation parameters are employed clinically. Data will include the sEEG recordings marked for ANT stimulation, any side effects, medications, past medical history (PMH), and tests/procedures during the hospital stay. Risks involved are as described for the standard depth electrode surgery with the addition of the possible side effects from the stimulation which include sensations of numbness and tingling, and possibly increased seizure activity.