165 Clinical Trials for Epilepsy
This study aims to better understand how epilepsy alters brain function through neuroimaging of healthy people and people with epilepsy. The study investigates how changes in brain metabolism (sugar consumption, measured by positron emission tomography \[FDG-PET\], and blood flow, measured by functional magnetic resonance imaging \[fMRI\]) relate to abnormal interictal electrical activity associated with epilepsy (measured by electroencephalography \[EEG\]). The study will also compare how the three imaging modalities localize regions of abnormal function in the brain.
This (DEEp OLE Study) is a multicentre, open-label study to investigate the long-term safety, efficacy, tolerability, and pharmacokinetics (PK) of LP352 in the treatment of seizures in children and adults with DEE who completed Study LP352-301 or LP352-302. The study consists of 3 main phases: Screening, Titration period and Maintenance period, followed by a Taper period and Follow-Up. The total duration of the study will be approximately 14 months.
This (DEEp OCEAN Study) is a double-blind, randomized, placebo-controlled, multicenter study to investigate the efficacy, safety, and tolerability of LP352 in the treatment of seizures in children and adults with DEE. The study consists of 3 main phases: Screening, Titration period, Maintenance period, followed by a Taper period and Follow-Up. The total duration of the study will be approximately 24 months.
The purpose of this study is to examine the feasibility and acceptability of an online group Neuro-behavioral Therapy (NBT) with text messaging intervention for Veterans with epilepsy and major depressive disorder (MDD).
The goal of this multi-site clinical trial is to determine the effectiveness of two components of a web-based intervention (Epilepsy Journey) to improve executive functioning in adolescents with epilepsy. The two components include web-based modules and problem-solving telehealth sessions with a therapist focused on executive functioning. This trial aims to answer the following questions: 1. Which components of Epilepsy Journey (web-based modules or telehealth sessions with a therapist) are essential for improving executive functioning in adolescents with epilepsy? 2. Which components of Epilepsy Journey (web-based modules or telehealth sessions with a therapist) are essential for improving quality of life in adolescents with epilepsy? Participants will be randomly assigned to one of four groups: 1) Epilepsy Journey web-based modules and telehealth sessions, 2) Epilepsy Journey web-based modules only, 3) telehealth sessions with a therapist only, or 4) treatment as usual. Participants will: * Independently review Epilepsy Journey web-based modules focused on executive functioning skills (\~15-30 minutes) and/or have weekly telehealth sessions (\~30-45 minutes) with a therapist for 14 weeks. * Complete measures of executive functioning (parent and teen-report) and quality of life (teen-report) at the start of the study, 14-, 26-, and 66- weeks after randomization. The NIH toolbox will be completed at the start of the study and 26-weeks after randomization. Additional measures will also be collected.
The Epilepsy-Dyskinesia Study aims to advance the understanding of the clinical and molecular spectrum of epilepsy-dyskinesia syndromes, monogenic diseases that cause both movement disorders and epilepsy. Addressing challenges in rare disease research -such as small, geographically dispersed patient populations and a lack of standardized protocols- the study employs a multinational retrospective survey endorsed by the International Parkinson and Movement Disorder Society. This survey seeks to collect comprehensive data on clinical features, disease progression, age of onset, genetic variants, and concurrent neurological conditions, standardizing data collection across countries to provide a unified understanding of these conditions. Through retrospective review and molecular data analysis, the study aims to identify patterns and correlations between movement and seizure disorders, uncovering genotype-phenotype relationships. The initiative\'s goals are to enhance understanding of epilepsy-dyskinesia syndromes, inform precision medicine approaches, and foster international collaboration.
Youth with epilepsy (YWE) are significantly more likely than their peers without epilepsy to experience isolation, interpersonal victimization, and low relationship satisfaction. This is a serious health concern. Poor social support, real or perceived, is consistently correlated to worsened outcomes in every domain of health-related quality of life. As YWE are two to five times more likely than their peers without epilepsy to develop a mental health condition, poor social support is likely a bidirectional risk factor. Currently, there are no best practices or recommendations for clinicians or other youth-serving professionals to reference when it comes to improving the perceived social support of YWE specifically. The research team has drawn from multiple fields of scientific knowledge to develop a novel intervention that aims to provide YWE with knowledge, skills, connections, and positive emotional support that can help them to bolster their support system at every level of the social ecological model (SEM). The proposed study is a pilot of this intervention to test its acceptability and appropriateness according to YWE participants ages 12 to 26. The intervention's impact on participants social-emotional learning skills and the feasibility of expanding the study protocol for use in a large, multisite randomized control trial will also be explored. The goal of this research study is to help evaluate a new program for young people diagnosed with epilepsy that will build up young people's social opportunities, interpersonal skills, and sources of emotional support. The investigators want to research the impact of this program. From this study, the investigators hope to learn what the program does well, and in what ways it could be improved from the perspective of YWE.
The purpose of this study is to determine whether BHV-7000 is effective in the treatment of idiopathic generalized epilepsy with generalized tonic-clonic seizures and includes an additional open-label extension (OLE) phase.
This will be a prospective, open-label, single-arm, multi-center, pilot study to evaluate the safety, tolerability, and preliminary efficacy of low-intensity focused ultrasound (LIFU) neuromodulation using NaviFUS System in patients with drug-resistant unilateral or bilateral temporal lobe epilepsy (DR-TLE).
This study will be done in two phases. Using stakeholder input (community advisory board (CAB)), the study team will adapt the SMART program to incorporate education and self-management support for use of Rescue Medication (RM) to manage seizure occurrence among Persons With Epilepsy (PWE) who have repetitive seizures. Additional content/support materials, pending input stakeholder might include posters/hand-outs that present information on the use of RM in a way that is engaging and salient to PWE. It is expected that participants will be in Phase 1 for about 3 months and participate in the CAB 2 or 3 times via zoom for 60-90 minutes/meeting. The advisory board will provide input on needed refinement of an adapted version of SMART based on their individual experiences. It is anticipate the total time commitment to be no more than 6 hours over 3 months, spread out over 2-3 meetings with review of materials possible in between meetings. Phase 2: The investigators will use a 6-month prospective trial design to test engagement with and effects of SMART-RM among approximately 35 adult (≥ 18 years) PWE who have repetitive seizures.
The purpose of this study is to determine whether BHV-7000 is effective in the treatment of refractory focal epilepsy.
This study is a non-randomized, open label, phase 1 clinical trial to evaluate the fesibility and safety of intrathalamic delivery of MSCs during standard of care DBS surgery for epilepsy. Subjects will be screened at our outpatient clinic and interested qualified subjects will be consented and offered participation in this trial. Once consent has been obtained, patients will undergo a standard preoperative evaluation which includes baseline laboratory values and a high-definition MRI. Patients will then undergo a stereotactic procedure for bilateral thalamic implantation of DBS leads through the ClearPoint® system. After the thalamic target for DBS is identified, cells will be infused directly into the anterior nucleus of the thalamus previous to lead implantation. Patients will be followed in the outpatient setting for up to a year after therapy application. Surgical, clinical, and radiographic data will be obtained during these visits
The Epilepsy Learning Health System (ELHS) is a quality improvement and research network to improve outcomes for people with epilepsy. The ELHS is designed as a model of value-based chronic care for epilepsy as envisioned by the National Academies of Medicine Committee in their landmark reports "The Learning Health System" and "Epilepsy Across the Spectrum: Promoting Health and Understanding". The ELHS network is a collaboration among clinicians, patients and researchers that promotes the use of data for multiple purposes including one-on-one clinical care, population management, quality improvement and research. The ELHS Registry includes data on children and adults with epilepsy collected during the process of standard epilepsy care. These data are used to create population health reports and to track changes in outcomes over time. ELHS teams use quality improvement methods, such as Plan-Do-Study-Act (PDSA) cycles, to continuously learn how to improve care.
The goal of this clinical trial is to assess whether Lemborexant can improve sleep in patients with epilepsy.
The purpose of this study is to determine whether BHV-7000 is effective in the treatment of refractory focal epilepsy.
Overall, this observational cohort study aims too: 1. Implement rapid trio WGS for all children presenting to our health systems with epilepsy onset under 12 months of age. 2. Utilize electronic healthcare records and research databases to unite phenotypic and genomic data and to create a "virtual" registry across all institutions that will promote ongoing discovery. 3. Assess the impact of early genetic diagnosis on epilepsy, developmental, and health economic outcomes through formal longitudinal assessments of all children enrolled.
The main goals of this clinical study are to learn if AMT-260 is safe and tolerable and works to reduce the frequency of seizures in adults with unilateral mesial temporal lobe epilepsy (MTLE).
The goal of this clinical trial is to learn if new educational program prior to epilepsy surgery can either decrease the risk of cognitive decline after surgery or be a help to those patients who experience a decline after undergoing epilepsy surgery. Participants will participate in 2 individual virtual sessions and 4 virtual group sessions over the course of 5-6 weeks prior to their epilepsy surgery. They will asked to fill out online surveys and questionnaires at various times throughout the study, up to 12 months after their surgery. To see if the educational program works, researchers will compare those participating in the educational program with those that are receiving the standard epilepsy care prior to surgery.
The goal of this clinical trial is to test if cognitive interventions in those with diagnosed epilepsy can help lessen cognitive lapses and improve overall brain health. Participants will participate in weekly, virtual group sessions led by a neuropsychologist for 12 weeks. After the 12-week mark, participants will be asked to practice what they learned for 9 more months. Participants will be asked to complete online questionnaires at certain times during the study. Researchers will compare this intervention group to another group that did not get the intervention to see if the intervention improves brain health. Participation in each of these groups will be randomly assigned. Participation in the study will last for one year.
Focal Epilepsy (FE) patients and healthy controls will wear an actigraph at home for one week and a home sleep study device at home for one night. Participants will then undergo two nights of testing (at least one week apart) at California Sleep Solutions (CSS) in Sacramento, CA. During the overnight stays, participants will have EEG leads placed and possibly a headband. They will undergo cognitive testing before they go to sleep and again in the morning. During one night of testing, sounds will be played in the room (acoustic stimulation). The sounds should not wake the participants.
We aim to determine the clinical utility of 'dynamic tractography': a novel method for visualizing electrical neural transfers that incorporates the underlying white matter tracts and supporting linguistic processing. We will also determine how well objective electrophysiology biomarkers will improve the prediction of language outcomes following epilepsy surgery. This project will ultimately optimize understanding of how the human brain develops its language network dynamics.
The goal of this observational study is to learn about the impact of the diabetes drug glibenclamide (glyburide) on neurodevelopment in individuals with iDEND (developmental delay, epilepsy and neonatal diabetes) due to the V59M mutation in the KCNJ11 gene. The main question it aims to answer is whether initiating sulphonylurea (SU) therapy in the first year of life results in better neurodevelopmental outcomes in affected individuals, in comparison to starting therapy later than 12 months of age. Participants will undergo a neurodevelopmental assessment comprising parental and teacher completion of standardised questionnaires, and where possible face to face neuropsychological testing. Researchers will compare the outcomes of these standardised tests in the individuals who started SU therapy \<12 months of age in comparison to those who started \>12 months of age.
The goal of this trial is to learn about the effect of PRAX-222 in pediatric participants with early onset SCN2A developmental and epileptic encephalopathy (DEE), aged 2 to 18 years.
This is a randomized effectiveness/implementation trial comparing a 24-week neurology-based collaborative care intervention to usual neurology care among 60 adults with epilepsy.
To examine the effects of haloperidol, chlorpromazine, valproic acid and placebo, in conjunction with standardized non-pharmacologic interventions, in the first line treatment of agitated delirium in hospitalized patients with cancer. This double-blind, randomized clinical trial aims to provide evidence on various therapeutic options for palliating delirium, thereby reducing delirium-related distress and ultimately alleviating suffering.
The NSR-GENE study is a longitudinal cohort study of approximately 300 parent-child trios from the Neonatal Seizure Registry and participating site outpatient clinics that aims to evaluate whether and how genes alter the risk of post-neonatal epilepsy among children with acute provoked neonatal seizures. The researchers aim to develop prediction rules to stratify neonates into low, medium, and high risk for post-neonatal epilepsy based on clinical, electroencephalogram (EEG), magnetic resonance imaging (MRI), and genetic risk factors.
The purpose of this research is to evaluate a 6 month change in quality of life in subjects who receive collaborative care calls compared to those subjects who receive usual neurology care. This is a 2-site trial comparing a 24 week neurology-based collaborative care program to usual neurology care among a total of 60 adults with post-traumatic epilepsy.
This is a prospective open label study assessing the efficacy and tolerability of pharmaceutical grade cannabidiol--Epidiolex (R), for the treatment of anxiety in pediatric patients with pediatric epilepsy that has been difficult to treat and requires ongoing use of anticonvulsant medication.
This is a single group prospective study to determine the feasibility for generating brain maps that localize cerebral functions and inter-regional information flow in partial epilepsy in adult patients.
Humans have a remarkable ability to flexibly interact with the environment. A compelling demonstration of this cognitive flexibility is human's ability to respond correctly to novel contextual situations on the first attempt, without prior rehearsal. The investigators refer to this ability as 'ad hoc self-programming': 'ad hoc' because these new behavioral repertoires are cobbled together on the fly, based on immediate demand, and then discarded when no longer necessary; 'self-programming' because the brain has to configure itself appropriately based on task demands and some combination of prior experience and/or instruction. The overall goal of our research effort is to understand the neurophysiological and computational basis for ad hoc self-programmed behavior. The previous U01 project (NS 108923) focused on how these programs of action are initially created. The results thus far have revealed tantalizing notions of how the brain represents these programs and navigates through the programs. In this proposal, therefore, the investigators focus on the question of how these mental programs are executed. Based on the preliminary findings and critical conceptual work, the investigators propose that the medial temporal lobe (MTL) and ventral prefrontal cortex (vPFC) creates representations of the critical elements of these mental programs, including concepts such as 'rules' and 'locations', to allow for effective navigation through the algorithm. These data suggest the existence of an 'algorithmic state space' represented in medial temporal and prefrontal regions. This proposal aims to understand the neurophysiological underpinnings of this algorithmic state space in humans. By studying humans, the investigators will profit from our species' powerful capacity for generalization to understand how such state spaces are constructed. The investigators therefore leverage the unique opportunities available in human neuroscience research to record from single cells and population-level signals, as well as to use intracranial stimulation for causal testing, to address this challenging problem. In Aim 1 the investigators study the basic representations of algorithmic state space using a novel behavioral task that requires the immediate formation of unique plans of action. Aim 2 directly compares representations of algorithmic state space to that of physical space by juxtaposing balanced versions of spatial and algorithmic tasks in a virtual reality (VR) environment. Finally, in Aim 3, the investigators test hypotheses regarding interactions between vPFC and MTL using intracranial stimulation.