View clinical trials related to Drug Resistant Epilepsy.
Filter by:The investigators propose a behavioral experiment with SEEG recording and stimulation, to both confirm the role of a brain region known as the anterior insula in identifying surprise, and disambiguate between competing principles behind adaptation: optimizing and satisficing. Optimizers continue to learn and adapt if performance can be improved, while satisficers are satisfied with a good enough performance and will cease adapting once that is reached. To study surprise signals in the anterior insula, a brain structure where these signals have been very prominent, the investigators will employ an experiment with subjects who are under SEEG (stereoelectroencephalogram) recording, that is, recording from electrodes which have been surgically implanted in the brain. These recordings will be done as patients perform a task where they try to anticipate the movements of a target on a line in two different learning environments (conditions). The experimenters will then determine whether these signals reflect surprise relative to past engagement with the environment, or surprise that reveals that the agent no longer feels in control because uncertainty is not in line with the reference model. If evidence is consistent with the former, adaptation reflects traditional reinforcement and aims at optimizing behavior. If evidence instead is consistent with the latter, behavior is guided by a prior model (a reference model) and behavior is satisficing. An fMRI study by d'Acremont and Bossaerts provides initial evidence that activation in the anterior insula supports the satisficing hypothesis, however it lacks the temporal granularity to completely rule out optimizing. In the current project, the investigators propose to use the higher time resolution of SEEG recordings to confirm these findings and reject the optimizing hypothesis. Additionally, stimulations of the anterior insula during a subset of trials will be used to determine whether insular activation following surprise signals and preceding changes in behavior (learning) is merely correlational or in fact causal. Stimulation will allow us to determine to what extent the subjects' sense of control and subsequent behavior can be influenced in accordance with surprise-based modeling of behavior. The cohort for this study will be patients with drug-resistant, focal epilepsy and who are hospitalized at the Hôpitaux Universitaires de Genève (HUG) for pre-surgical evaluation of their epilepsy using SEEG. The protocol will run in parallel with the patients' clinical procedures.
To evaluate the performance of automatic stimulation mode of a new rechargeable implantable vagus nerve stimulation system for drug-refractory epilepsy
Exploring the efficacy and safety of oral minocycline combined with antiepileptic drugs in the treatment of drug-resistant epilepsy in NORSE patients, obtaining preliminary research data, and providing evidence and data support for the next large-scale randomized controlled clinical study.
The basis of this project is the application of cathodal tDCS in patients with drug-resistant focal epilepsy including patients whose seizures persist after epilepsy surgery, who rejected epilepsy surgery, and/or who are not suitable for surgery. For this purpose, 5-day consecutive cathodal electrical stimulation sessions will be used with personalized electrode montage according to the patient's seizure focus. In this context, the changes in seizures frequency and epileptic discharges will be examined for the first week and 12th week after the tDCS sessions through the seizure diary of the patients and the electroencephalogram (EEG) recordings to be taken. In addition, changes in cognitive functions, mood, and quality of life will be examined in patients after the intervention.
Participants with drug-resistant epilepsy (DRE) enrolled in this study will receive focused ultrasound (FUS) treatment with the NaviFUS System, guided by the neuronavigation system to evaluate the safety and efficacy of using NaviFUS System. During the treatment, the FUS will electronically scan and target to the assigned zones on one or both of the hippocampi. The study consists of a 60-day screening period for baseline observation prior to treatment, a FUS treatment period of 2 weeks for Cohort 1 or 3 weeks for Cohort 2 with 2 FUS treatments per week using the NaviFUS System, and a safety follow-up period of 81 days.
The purpose of this project is to conduct a trial to assess whether patients that receive a tablet-based waiting room priority communication tool (the "Epilepsy Visit Planner") have improved outcomes compared to patients that do not receive the tool. The project's hypotheses are: - Patients that receive the Epilepsy Visit Planner will have improved patient-provider communication compared to the non-planner group. - Patients that receive the Epilepsy Visit Planner will have improved quality of life scores. - The Epilepsy Visit Planner will score highly on process measures of feasibility and acceptability, demonstrating suitability for future larger scale study. Additionally, there is a related survey project that is not part of the clinical trial and will not be included in this registration information.
Epilepsy is the fourth overall neurologic disorder, regardless of age and gender. It encompass a wide spectrum of conditions, intensities and seizure types; therefor, several drugs have proven to treat different types of seizures. However, around 22.5 % of patients are unable to attain control regardless of the drug used or even a combination of several of them. TDCs offers a non-invasive approach with a focal effect for those patients. The focus of this study is to define the role for tDCS in the treatment of drug-resistant epilepsy on children.
In our previous cross-over study--the continuous θ burst stimulation (cTBS) targeting cerebellum dentate nucleus of 44 drug-refractory epilepsy (DRE) patients, a significant reduction in seizure frequency was observed. However, the mechanism of this target to reduce seizures is still unknown. This study aims to explore the mechanism of cTBS targeting cerebellum dentate nucleus for DRE, in order to provide theoretical support for this treatment method. A total of 50 patients with DRE will have 2-week cTBS treatment via accurate navigation to bilateral cerebellar dentate nucleus. Participants will be took TMS-EEG, functional magnetic resonance imaging, and diffusion tensor imaging (DTI) pre- and post- treatment. These three examinations will help to analyze the brain functional connectivity and suggest the mechanism of action of this treatment.
Interoception, or sensation from inside the body, is involved in a variety of clinical symptoms, such as tics, compulsions and negative mood. This study uses invasive recordings of brain activity and brain stimulation to better understand basic neural mechanisms of interoception and related behaviors. Outcomes of this study provide critical tools for future investigation into clinical symptoms that emerge from abnormal interoception.
In this exploratory trial, the potential anti-seizure activity of clioquinol in a small cohort of adolescents with drug-resistant epilepsy will be examined. Subjects will be exposed to clioquinol add-on for a period of maximum 8 weeks (2 weeks low dose, 6 weeks higher dose). The main hypothesis of the study is that 30% of the included subjects will be responders and that the median seizure frequency reduction will be at least 30%.