Efficacy and Safety of Deep Brain Stimulation (DBS) of the Pallidal (GPi) in Patients With Tardive...
DystoniaMovement DisorderThe purpose of this randomized, double blind, multi-center study is to assess the efficacy and safety of bilateral pallidal deep brain stimulation in patients with tardive dystonia.
Efficacy and Safety of DBS of the GPi in Patients With Primary Generalized and Segmental Dystonia...
DystoniaThe purpose of this study is to evaluate the efficacy and safety of bilateral deep brain stimulation of the internal globus pallidus for treating idiopathic generalized or severe segmental dystonia.
A Multimodal Approach to Cervical Dystonia Treatment With Association of Botulinum Toxin and Motor...
Cervical Dystonia,Primarythe 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.
Video-supervised Motor and Awareness Training in Writer's Cramp
Writer's CrampWriter's cramp is the most common task-specific dystonia. It is characterized by involuntary co-contraction of antagonistic muscles during writing. This disabling condition may force patients to give up their occupation. In this study the efficacy of a twelve months long-term training in patients with writer's cramp will be investigated. Two different programs will be offered: The first one will consist of a sensorimotor, the second one of an awareness training. All patients will benefit from video-based supervision with the aim to establish a practice-oriented therapeutic approach that will be available to all patients independently of their home location. The treatment effect will be measured primary with the patient-centered Canadian Occupational Performance Measure (COPM) and secondary with clinical scales to assess the clinical efficacy and everyday constraints. Writing will be assessed with a computer-based kinematic writing analysis. To evaluate the influence on the brain network, several functional magnetic resonance imaging (fMRI) evaluations will be performed. This project is of minimal risk without negative side effects from the training. The risks for the MRI experiment are equal to a non-contrast standard MRI investigation.
SUNDYS: A Multicenter, Randomized, Double-blind, Sham-controlled, Parallel-group Trial
DystoniaDystonia is a group of movement disorders characterized by twisting, repetitive movements, or abnormal postures caused by involuntary muscle contractions and is characterized by a young age of onset and a high disability rate. Early intervention can reduce disability incidence, improve the patient's quality of life, and reduce the burden on families and society. Multiple international guidelines on dystonia have found deep brain stimulation (DBS) to be a safe and effective treatment for refractory dystonia. The globus pallidal internus (GPi) is the mostly widely used target for dystonia. However, there are limitations on the GPi DBS treatment, including slow onset of beneficial effects, poor improvement of axis symptoms, and potential stimulation-related side effects. Previous studies have described the highly successful use of subthalamic nucleus deep brain stimulation (STN DBS) in patients with refractory dystonia, suggesting that STN DBS is an effective and persisting alternative to pallidal deep brain stimulation. However, all STN DBS treated cases have been analyzed in open-label uncontrolled cohort studies, leading to limited data with a high level of evidence on the STN DBS in dystonia. Further, the investigators hypothesized STN has potentially more effectiveness when compared with GPi, and may be more power-saving and quick-acting. In this study, the investigators will organize a prospective randomized, double-blind, parallel-group, multicenter study comparing active versus sham stimulation in isolated segmental or generalized dystonia to evaluate the effectiveness and safety of STN DBS by measuring the impact on motor status, mental status, quality of life, the rate of response of the patients (the number of patients with ≥30% improvement in the movement score on the Burke-Fahn-Marsden Dystonia Rating Scale) and the rate of adverse events during the trial.
Clinical and Kinematic Assessment for Determination of Botox® Injection Parameters in Cervical Dystonia...
Cervical DystoniaThis study investigates the use of a kinematic measurement device to quantify the abnormal head movements and postures in patients with cervical dystonia (CD) in order to individualize and optimize botulinum toxin type A (BoNT-A) injection therapy. A single sensor captures five degrees of freedom of the neck and head that distinguish which muscle(s) contribute to CD and the amount of BoNT-A to inject into these muscle(s). The efficacy, relief and improvements in social, occupation and function by injections will be investigated. The efficacy of BoNT-A therapy using either BoNT-A injection parameters from clinical-based assessments and kinematically-based assessments will be investigated in CD patients. Individuals clinically diagnosed with CD will be randomized for two treatment conditions: A) injection parameters from a kinematic assessment only, or B) injection parameters from a clinical assessment only.
Somatosensory Processing in Focal Hand Dystonia
Focal Hand DystoniaMusician's Dystonia2 morePatients with focal dystonia experience uncontrollable movements of the hand during certain types of skilled movements. Though the origin of the disorder is not fully understood, it is thought that brain areas involved in moving the hands and receiving touch information from the hands, are involved. For example, patients with dystonia affecting the hand show changes in their ability to perceive touch - this is something that typically escapes the patients own awareness. Further, the area of the brain receiving touch information has a disrupted representation of the finger skin surfaces. The goal of our research is to improve dystonia symptoms in patients with hand dystonia. We will attempt to achieve this goal by implementing an intensive training treatment that requires patients to attend to, and use touch information applied to specific fingertips. Previous work has attempted to alter touch perception using sensory training and improvements in motor control (hand writing) of dystonia patients were observed. For example, learning to read Braille improves tactile perception and handwriting in focal hand dystonia. A different approach to treat focal hand dystonia involves a technique called repetitive transcranial magnetic stimulation (rTMS), and this can also temporarily improve hand writing in dystonia patients. The proposed research will attempt to alter touch processing using touch training alone, or in combination with rTMS. Rather than train using Braille reading, the sensory training will be applied using a systematic, experimenter controlled stimulus set that focuses on touch stimuli applied to individual digits. Importantly patients will have to associate certain types of touch information with rewards and other touch input with the lack of a reward. The study will first involve measuring the location and representation of the touch in the brain using multiple brain mapping tools. These tools include functional magnetic resonance imaging and magnetoencephalography; when both tools are used a very accurate picture of finger representation can be obtained, and we also know what brain areas respond to touch stimuli. Dystonia symptoms and touch perception will also be assessed. Next, patients will participate in a training intervention that involves 15 days(2.5 hr/day) of touch training applied to the fingertips of the dystonia affected hand. Patients will identify the touch targets amongst distractors and receive on-line performance feedback. The goal of the training is to provide the cortex with regular boundaries of fingers and in this way, attempt to re-shape the sensory cortex to accept these boundaries. Another group of patients will receive rTMS. The goal of the rTMS is to create an environment in sensory cortex that is open or 'ready' to accept changes induced by tactile stimulation. The rTMS will be immediately followed by the tactile training. A third group of patients will receive a placebo version of rTMS followed by tactile training. The latter group will allow us to understand if rTMS has a definite effect on the physiology of the patient. Following the 15-day training, we will assess the brains representation of fingertips, changes in dystonia symptoms and changes in the perception of touch stimuli. This research will advance the treatment of focal hand dystonia and assist the design of precise remediation training tailored to the dystonia patient.
Brain Anatomy in Dystonia
DystoniaHealthyThis study will use high-resolution magnetic resonance imaging (MRI) to look for subtle differences in brain anatomy between patients with focal hand dystonia (also called writer s cramp) and healthy normal volunteers. Patients with hand dystonia have prolonged muscle contractions that cause sustained twisting movements and abnormal postures. These abnormal movements often occur with activities such as writing, typing, playing certain musical instruments such as guitar or piano, or playing golf or darts. Patients with focal hand dystonia and healthy volunteers will be enrolled in this study. Patients will be recruited from NINDS s database of patients with focal hand dystonia. Volunteers will be selected to match the patients in age, sex and handedness. This study involves two visits to the NIH Clinical Center. The first visit is a screening visit, in which patients and volunteers will have a medical history, physical examination, neurological examination, and assessment of handedness. Women of childbearing age will be screened with a pregnancy test. Pregnant women are exclude from this study. Those who join the study will return for a second visit for magnetic resonance imaging. MRI uses a magnetic field and radio waves to produce images of the brain. For the procedure, the participant lies still on a stretcher that is moved into the scanner (a narrow cylinder containing the magnet). Earplugs are worn to muffle loud noises caused by electrical switching of radio frequency circuits used in the scanning process. The scan will last about 45 to 60 minutes, at most. Some volunteers may be asked to return for a third visit to obtain a second MRI on a different scanner.
The Effects of Cannabis on Dystonia and Spasticity on Pediatric Patients
SpasticityDystoniaA 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.
Depotentiation in People With Focal Hand Dystonia
Focal DystoniaHealthy VolunteersBackground: - Focal hand dystonia (FHD) causes muscles to contract, leading to abnormal movements or postures. Musicians, writers, and athletes often get it. Researchers want to study how patients with this condition learn, a process of the brain that depends on a property called plasticity. Objective: - To study brain plasticity in people with FHD. Eligibility: Right-handed adults 18 years and older with FHD. Healthy, right-handed adult volunteers. Design: Participants will be screened with medical history, physical exam, pregnancy test, and questionnaire about their right-handedness. Participants will have 2 study visits on 2 different days. Participants will sit in a chair and have up to 30 Transcranial Magnetic Stimulation (TMS) pulses on the left side of the head. A brief electrical current passes through a wire coil on the scalp. They will hear a click and may feel a pulling on the skin or muscle twitches. They may have to keep their eyes open and remain alert, tense certain muscles, or perform simple finger movements. Forty more pulses, with 10 seconds between, will be given on the left side of the head. Some will be small, some big. Researchers will measure muscle response through small electrodes taped to the right hand. A cloth cap will be put on the participant s head. Researchers will write on tape on the cap. Participants will have the r-PAS. An electrical stimulator will be placed on the nerve at the right wrist. Repeated magnetic pulses will be delivered in trains or short bursts together with electrical stimulation of nerve. Participants will receive up to 840 pulses. Participants will be contacted after a few days for a follow-up check.