View clinical trials related to Dystonic Disorders.
Filter by:the aim of this study protocol is to describe, using a longitudinal study, a multimodal approach of treatment of cervical dystonia with botulinum toxin (BoNTA) and a new rehabilitation protocol named SPRInt (Sensory-motor perceptive rehabilitation integrated) approach based on motor learning techniques and spatial rehabilitation.
Writer's cramp (WC) is a form of focal dystonia, a movement disorder characterized by sustained or intermittent muscle contractions causing abnormal, often repetitive movements, postures, or both. It typically manifests while writing, making handwriting impossible in the most severe cases. Treatment can be difficult, but one effective and well-tolerated treatment consists in local muscle injections with botulinum toxin. Although clinical improvement seems to be related to focal muscle chemodenervation, central plasticity changes may occur. The main aim of the study is to characterize and quantify the changes in intrinsic hand muscle cortical representations at rest and during isometric contractions of the finger muscles before and after treatment with botulinum toxin and the changes in sensorimotor integration in patients with writer's cramp.
In certain neurosurgical procedures, the use of a stereotaxic frame is required. It is then possible to set a precise target (depending of the type of the surgery) to be reached by the surgeon. The fixation of the stereotactic frame on the awake patient's head is done under local anesthesia by screwing the frame directly into the skull. This procedure is reported as "painful" to "extremely painful" by patients. The objective of this study is to determine whether the hypnosis is effective in decreasing the pain perceived by the patient during the disposal of the stereotactic frame.
The contribution of genetic risk factors to the development of focal dystonias is evident. However, understanding of how variations in the causative gene expression lead to variations in brain abnormalities in different phenotypes of dystonia (e.g., familial, sporadic) remains limited. The research program of the investigators is set to determine the relationship between brain changes and genetic risk factors in laryngeal dystonia (or spasmodic dysphonia). The researchers use a novel approach of combined imaging genetics, next-generation DNA sequencing, and clinical-behavioral testing. The use of a cross-disciplinary approach as a tool for the discovery of the mediating neural mechanisms that bridge the gap from DNA sequence to the pathophysiology of dystonia holds a promise for the understanding of the mechanistic aspects of brain function affected by risk gene variants, which can be used reliably for the discovery of associated genes and neural integrity markers for this disorder. The expected outcome of this study may lead to better clinical management of this disorder, including its improved detection, accurate diagnosis, and assessment of the risk of developing dystonia in family members.
Dystonia is increasingly being considered as a multi-nodal network disorder involving both basal ganglia and cerebellar dysfunction. The aim of this study is to determine if "Multi-Target" Thalamic and Pallidal Deep Brain Stimulation improves hemi-dystonia patients who are receiving inadequate therapy from GPi DBS.
To compile characteristics of real-world outcomes of Boston Scientific Corporation's commercially approved VerciseTM Deep Brain Stimulation (DBS) Systems for the treatment of dystonia.
Primary cranial-cervical dystonia is managed mainly by repeated botulinum toxin injections.This study is to establish whether subthalamic nucleus neurostimulation could improve symptoms in patients not adequately responding to chemodenervation or oral drug treatment. Investigators compared this surgical treatment with sham stimulation in a randomized, controlled clinical trial.
A clinical trial is planned to study the effects of cannabis on dystonia and spasticity in children with neurological diseases. The clinical trial will include 40 children divided into two groups: children with spasticity and dystonia due to cerebral palsy, and children with spasticity and dystonia due to genetic neurodegenerative diseases. Each group will be randomly divided into two arms and will receive Avidekel cannabis oil 6-to-1 ratio of CBD to THC or enriched Avidekel cannabis oil 20-to-1 ratio of CBD to THC. During the study, various variables will be collected including: medication intake, spasticity, dystonia score, pain scale, restlessness scale, quality of life measures, safety tests, side effects, and an addiction test. The investigators hypothesize that cannabis consumption will reduce dystonia and spasticity in children with motor disability related to genetic neurodegenerative diseases and cerebral palsy and as a result improve motor function, non-motor functions and quality of life.
The purpose of this study is to investigate the impact of botulinum toxin treatment in quality of life(QoL) in cervical dystonia patients
Background: - Deep brain stimulation (DBS) is an approved surgery for certain movement disorders, like Parkinson's disease, that do not respond well to other treatments. DBS uses a battery-powered device called a neurostimulator (like a pacemaker) that is placed under the skin in the chest. It is used to stimulate the areas of the brain that affect movement. Stimulating these areas helps to block the nerve signals that cause abnormal movements. Researchers also want to record the brain function of people with movement disorders during the surgery. Objectives: - To study how DBS surgery affects Parkinson s disease, dystonia, and tremor. - To obtain information on brain and nerve cell function during DBS surgery. Eligibility: - People at least 18 years of age who have movement disorders, like Parkinson's disease, essential tremor, and dystonia. Design: - Researchers will screen patients with physical and neurological exams to decide whether they can have the surgery. Patients will also have a medical history, blood tests, imaging studies, and other tests. Before the surgery, participants will practice movement and memory tests. - During surgery, the stimulator will be placed to provide the right amount of stimulation for the brain. Patients will perform the movement and memory tests that they practiced earlier. - After surgery, participants will recover in the hospital. They will have a followup visit within 4 weeks to turn on and adjust the stimulator. The stimulator has to be programmed and adjusted over weeks to months to find the best settings. - Participants will return for followup visits at 1, 2, and 3 months after surgery. Researchers will test their movement, memory, and general quality of life. Each visit will last about 2 hours.