View clinical trials related to Drug Resistant Epilepsy.
Filter by:The goals of this study are (1) to evaluate the rate of stereoEEG brain-computer interface (BCI) classification accuracy and (2) to collect the dataset of neuronal signals recorded from stereoEEG electrodes during motor performance, motor imagery or brain-computer interface control. The study enrolls hospitalised patients suffering from resistant epilepsy with already implanted intracranial stereoEEG electrodes for medical reasons (i.e. for preoperative localization of the epileptogenic foci). The number and location of electrodes are determined solely for the clinical purposes of stereoEEG monitoring and are not related to the protocol of the current study. After obtaining informed consent to participate in the study, each patient will participate in one experimental session lasting no more than 60 minutes, recording brain signals associated with hand movement, motor imagery, and BCI control. All tasks and instructions presented during the study session are not pro-epileptogenic and cannot provoke an epileptic attack. The experiments will take place in the patient's room, without interruption of observation by the department's medical staff. The data recorded in this study will be used to improve or develop new algorithms for decoding motor signals from deep brain structures for their potential use in invasive BCIs.
Recent studies have shown that the aperiodic part of the signal (neuronal avalanches) of electroencephalography (EEG) contains important information about the dynamics of neuronal networks. Indeed, this has helped to identify functionally altered areas in patients with temporal epilepsy by simply using the resting EEG signal. Furthermore, it has been seen that the propagation of neuronal avalanches (VNs) correlates with the morphological organization of the cerebral cortex. Therefore, NAs represent a measure with direct utility for studying functional reorganization pre and post drug/surgical treatment. In addition, the aperiodic portion of the signal may represent a noninvasive measure of the excitation/inhibition relationship, which is known of being altered both in epilepsy and in some rare neurodevelopmental syndromes (example: Angelman and Dup15q)
This study aims to evaluate the efficacy of a ketogenic diet in treating pediatric intractable epilepsy and to explore its relationship with changes in inflammatory markers. The investigators plan to recruit 59 participants with intractable epilepsy, 39 of whom will receive a combination of ketogenic diet and conventional antiepileptic drugs, while 20 will receive only conventional drugs. The study will assess the impact of the ketogenic diet on epilepsy control and inflammatory markers, hoping to discover new treatment strategies.
The goal of this observational study is to learn about the clinical and nutritional effectiveness of ketogenic diet (KD) in pediatric patients with genetic, neurological or metabolic conditions requiring KD. The main question[s] it aims to answer are: - does KD support adequate growth? - does KD improve clinical symptoms? - how does KD impact quality of life? Participants will be followed up as per clinical practice
Vagus nerve stimulation (VNS) is an adjunctive treatment for refractory epilepsy. Although widely used, there is still a substantial number of patients with insufficient response. Light, and particularly blue light, can stimulate alertness, attention and cognition through modulation of anatomical targets which are common to the vagal afferent network. This project aims at understanding how exposure to blue enriched light may influence VNS effects in patients with refractory epilepsy by exploring the modulation of a series of biomarkers of VNS action. This could possibly lead to new therapeutic strategies to increase efficacy of VNS.
Focused ultrasound (FUS) has been shown to differentially lesion or modulate (excite and inhibit) brain circuit and neural activity across a broad range of acoustic stimulus parameters (intensity, duty cycle, pulse repetition frequency and pulse duration) for decades. From our previous study, FUS sonication may suppress the number of epileptic signal bursts observed in EEG recordings after the induction of acute epilepsy. The presence of the suppressive effect was found in terms of the number of epileptic EEG spikes from the analysis of the unfiltered and theta-band EEG activity, and further discontinue the seizure attacks. EEG activity has also been consistently reported to have a positive correlation with the level of epilepsy, and FUS-mediated reduction of epileptic EEG activity was most notably observed, no matter lesioning or modulating effects. The aims of this study are to demonstrate the safety and efficacy of FUS technology in epilepsy patients and to estimate the optimal parameters of focused ultrasound exposure that will be used in the case of epilepsy.
The primary objective of this research is to study the efficacy and safety of deep brain stimulation (DBS) of subthalamic nucleus (STN) as adjunctive therapy for reducing the frequency of seizures in drug-resistant focal motor epilepsy.
To observe the clinical effect and safety of transcranial electrical stimulation on patients with refractory epilepsy before and after treatment and analyze its therapeutic mechanism.
Epilepsy is one of the most common neurological diseases, affecting between 0.5% and 1% of the general population. Therefore, new diagnostic and treatment methods are having a big impact on society. Epilepsy is also one of the most commonly diagnosed pediatric neurological disorders, with long-term implications for the quality of life of those affected and their relatives. In only two-thirds of cases, seizures can be adequately controlled with anticonvulsant drug therapy. For other patients with a drug-resistant focal epilepsy (up to around 2 million in Europe) epilepsy surgery is currently the most effective treatment. However, only 15-20% of these drug-resistant patients are eligible for epilepsy surgery. This is either because the cortical epileptogenic zone cannot be localized with sufficient precision with standard diagnostic means, or because the epileptogenic zone overlaps meaningful cortical areas, so that it cannot be surgically removed without considerable neurological deficit.
Open-loop electrical stimulation has been found to reduce spike activity and seizures, but determining the optimal parameters to achieve these effects requires a brute force trial-and-error approach that relies on subjective physician discretion. We will compare the performance of stimulation parameters identified in rodent models to the recommended parameters for neuromodulation used in clinical practice.