View clinical trials related to Dystonia.
Filter by:This Phase 2 trial will evaluate the safety and efficacy of ABP-450 for the treatment of cervical dystonia in adults. The study will enroll 60 patients across approximately 30 sites in the United States. Study subjects will be divided evenly across a low dose group, a medium dose group, a high dose group, and a placebo group for one treatment cycle.
The purpose of this study is to evaluate the accuracy of the Neurolocate recording system of the neurosurgical robot Neuromate, marketed by Renishaw, in order to optimize surgical procedures, costs and patient comfort.
To study electrophysiological and imaging correlations of the clinical effectiveness of zolpidem in task-specific dystonia and to elucidate mechanisms underlying its therapeutic effects, patients with focal dystonia will be clinically evaluated and will undergo transcranial magnetic stimulation and FDG-PET CT brain imaging after a single 5 mg dose of zolpidem and placebo, in two separate sessions. Resting motor threshold (RMT), active motor threshold (AMT), resting and active input/output (IO) curve, short-interval intracortical inhibition (SICI) curve, long interval intracortical inhibition (LICI), intracortical facilitation (ICF), and cortical silent period (CSP) will be measured. Objective clinical improvement will be rated using Burke-Fahn-Marsden Dystonia Rating Scale-movement (BFM-M) and writer's cramp rating scale (WCRS). Subjective improvement will be measured using the visual analog scale (VAS). Only a subset of patients (10 patients) will undergo positron emission tomography with 18F-2-fluoro-2-deoxy-D-glucose (18F-FDG PET) brain imaging after a single 5 mg dose of zolpidem and placebo.
24-Week Prospective, Double-Blinded, Randomized, Cross-over design in Multicenter Study of 50 unit of Neubotulinum Toxin Type A (Neuronox) and 100 unit of Neubotulinum Toxin Type A (Neuronox) injection for Cervical Dystonia in patient diagnosed with cervical dystonia according to clinical diagnosis. It was designed to evaluate the efficacy, safety, tolerability, quality of life and the comparesion the improvement after treatment by of 50 unit of Neubotulinum Toxin Type A (Neuronox) and 100 unit of Neubotulinum Toxin Type A (Neuronox) injection.
Deep Brain Stimulation (DBS) is an effective therapy for patients with medically refractory primary dystonia. However, DBS programming for dystonia is not standardized and multiple clinic visits are frequently required to adequately control symptoms. We aim to longitudinally record brain signals from patients using a novel neurostimulator that can record brain signals. We will correlate brain signals to clinical severity scores to identify pathological rhythms in the absence of DBS, and we will study the effects of DBS on these signals in order to guide clinical programming. We are going to recruit patients who receive the Medtronic Percept device, which allows for brain signal recordings (this feature is FDA approved). The investigators will be conducting an observational study using this device to collect data that the subjects receive as standard of care.
The study will include subjects diagnosed with Dystonic Tremor (DT), Essential Tremor (ET), and healthy controls in the age range of 21-80 years. Electroencephalography (EEG) will be used as the primary outcome measure. Transcranial Magnetic Stimulation (TMS) will be used over the motor cortices or cerebellar cortices as an intervention that is expected to have short-term (less than an hour) electrophysiological effects.
To determine the efficacy and safety of Botulax® in treatment of cervical dystonia
Many cervical dystonia (CD) patients are limited in their ability to travel to the clinic for follow-up in between injection visits. A telemedicine visit at the time of peak effectiveness of neurotoxin treatment may be valuable in informing the neurologist's choice of muscle selection and/or dose for the next injection visit. The primary objective of this study is to investigate both patient and physician satisfaction with the use of our telemedicine tool for this type of follow-up. After assessment of the subject, the neurologist will decide whether or not the telemedicine visit was informative to the upcoming injection visit. Subjects will answer questions at the end of the visit regarding their satisfaction with the follow-up and overall telemedicine communication. The principle investigator will complete a similar survey with additional questions about information gathered from the visit to assess the primary objective. A secure video communications platform will be used for the visit, which will occur 2-4 weeks after the patient's last neurotoxin injection (around the time of peak effectiveness). The investigating neurologist will remotely assess the patient and make notes for the next injection visit.
Botulinum toxin injections are the treatment of choice for cervical dystonia. Even if this treatment is successful for most of the patients, partials or completes failures still remained. Usually, botulinum toxin injections are realized by clinical localization techniques (observation and palpation of target muscles). The use of Ultrasonography to guide injections of Botulinum toxin has theoretical benefits (as an improved precision, an improved reproducibility, the targeting of deep-seated muscles, and a lower risk of adverse events) but its interest has never been demonstrated.
Efficient gait requires effective postural control, both static and dynamic. Hence, postural disorders may affect gait. Yet, very little is known about the specific effects of focal postural disorders such as cervical dystonia (CD) and blepharospasm (BS) on patients' mobility. The present research therefore aims at analyzing gait characteristics in patients presenting with these conditions in order to document possible gait alterations. In addition, the investigators will explore the effect of botulinum toxin treatment, which the most frequently used therapeutic option, on the patients' gait characteristics. Indeed, while the treatment improves both dystonia and pain, and therefore quality of life, its influence on gait is presently unknown. the investigators aim at filling this knowledge gap