View clinical trials related to Epilepsy.
Filter by:The study aimed at detection of autonomic dysfunction among cases with temporal lobe epilepsy; using different electrophysiological techniques. Moreover, it aimed at finding any correlation between electrophysiological tests and SUDEP risk.
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.
We don't know a great deal about why some people develop seizures in adulthood, but some researchers think that it might tell us something about the brain. A small number of people with first seizure in adulthood go on to experience problems like stroke or dementia later in life. However, stroke and dementia are common diseases, so we don't know whether there is a real association between these conditions. When people develop their first seizure in adult life, this is sometimes called Late-Onset Epilepsy. Through the NeuroFrailty study, we will observe 'brain health' over the years following the onset of a seizure, and I hope that it might give us more information about people with these kinds of seizures. The NeuroFrailty study involves observing people from the time of diagnosis of first seizure. At this time, we will look at investigations such as blood tests, blood pressure, brain scans, alongside other diagnoses which might tell us whether there are differences compared to people without seizures. For some people, we will also look in greater depth at lifestyle including exercise, driving, family planning, and memory assessments. Over the following years, we will look at how things change: for example whether there are changes in memory, new diagnoses, medication changes and how lifestyle has changed. Because there is so little research in this area, it is very difficult to predict what might happen. For example, some people can experience worse memory because of medication side effects; on the other hand, good seizure control following a diagnosis can sometimes lead to improved memory. Over years, it may become clear that some diseases are more likely in people with late-onset epilepsy than in people without such a diagnosis. You will receive a yearly newsletter to keep you updated on everything we learn about late-onset epilepsy. Purpose and Background Most of the time, we do not know why an adult develops epilepsy. Some researchers think there may be a connection between epilepsy which starts in adulthood, and increased risk of stroke or dementia in the future. However, there is very little research or evidence in this area, so we cannot say whether this is true. What does taking part involve? This study is an observational study, which means that the management of participants' seizure disorder will not be affected if they choose to take part in this study. The purpose of this study is to watch participants over the course of several years, to find out more about seizures which start in adulthood. Participants can choose the level of involvement that is right for them. 1. LOW involvement. A researcher will check hospital and General Practice (GP records) once or twice per year, for the LIMITED AND SPECIFIC purpose of checking: medications, any new diagnoses, investigations associated with stroke risk (such as cholesterol, blood pressure, heart trace) and any brain scans that have been performed. I will not have access to more detailed information, such as conversations between a participant and their GP. 2. HIGH involvement. This involves being contacted by telephone once per year for 15-30 minutes to ask questions assessing memory and enquiring about lifestyle, such as exercise, smoking and alcohol use. 3. VERY HIGH involvement. These participants will be contacted for a longer telephone conversation 30-45 minutes once per year about their experience of how epilepsy has affected home life, work and medications. If someone decides in the future that they don't want to be involved, they can withdraw from the study. However, once the study is completely finished, the information will be completely anonymous, which means that I won't be able to find individual's information in order to delete it. Glossary Seizure disorder = any disorder which involved having experienced at least one seizure. First seizure and epilepsy both can be classed as a form of seizure disorder. Neurofrailty = A condition whereby a person is at risk of stroke or dementia.
The goal of this clinical trial is to assess whether Lemborexant can improve sleep in patients with epilepsy.
This study was conducted on thirty children aged from12 months to 18 years newly diagnosed with drug resistant epilepsy and following up at Pediatric Nutrition and Neurology Outpatient Clinics assigned randomly into 2 groups, group1: patients who started ketogenic diet with L-carnitine and group2: patients who started ketogenic diet only.
Purpose: The purpose of this pilot study is to investigate the dynamics between theta and alpha oscillations in the control of working memory. These findings will be informative of what types of brain stimulation are most effective at modulating brain activity. Deep brain stimulation and transcranial magnetic stimulation are used for an increasing number of neurological and psychiatric disorders. Participants: Eligible participants are patients who have previously had electrodes implanted to monitor epilepsy (outside of research activity). 50 participants will be recruited, 25 participants for each phase of the study. Procedures (methods): The participants will perform a cognitive control task. During the task, rhythmic trains of direct cortical stimulation will be delivered to the frontal cortex alone or to the frontal and parietal cortex. Electrocorticography will be collected concurrent with stimulation.
Magnetic Resonance Imaging (MRI) is an excellent method for diagnosis and staging of brain disease. However, lengthy scan times and sensitivity to patient motion limit its efficacy. To address this, a novel method has recently been demonstrated, called MR Fingerprinting (MRF). The investigators' improved implementation of MRF, featuring fully-quantitative data and a reduced sensitivity to patient motion, can be used to acquire an anatomical exam in less than five minutes at a standard resolution. The potential for wide applicability of this technique, combined with an implied reduction in complexity and cost of MRI exams, has generated wide interest. However, published studies have been limited to demonstrations in healthy volunteers, and the effectiveness of MRF in the clinical practice has not yet been proven. Here, the investigators aim to assess the efficacy of MRF in performing diagnostic exams avoiding sedation in children and for increasing diagnosis rates in challenging adult patients.
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.
The expression of hypokinetic and hyperkinetic motor symptoms is accompanied by pathological synchronous oscillations of neuronal activity in this cortico-subcortical network with a wide frequency range. The purpose of this research is to study cortico-subcortical oscillations and their synchronization in two pathologies emblematic of hypokinetic (Parkinson's disease) and hyperkinetic (epilepsies) phenomena using a simple motor task and comparing different situations.