View clinical trials related to Dystonia.
Filter by:Transcranial Ultrasound Stimulation (TUS) is an emerging non-invasive brain stimulation technique capable of targeting both superficial and deep brain areas with high spatial resolution, down to a few cubic millimeters. In this study, the investigators aim to use TUS to non-invasively modulate the globus pallidus internus (GPi) in patients with Parkinson's disease (PD) and dystonia. These patients have previously been implanted with deep brain stimulation (DBS) leads. The investigators plan to simultaneously record local field potentials (LFPs) from the DBS leads using the Percept PC device (Medtronic Inc.) while the DBS is turned off. The study's goal is to investigate the mechanism of action of TUS and its neuromodulatory effects on LFPs recorded from the GPi. This will enable us to compare the effects of TUS with those of DBS.
This study aims to develop a way of objectively measuring the neurological disorders, Essential Tremor (ET) and Dystonia, and whether it is possible to quantify ET and dystonia using a measurement system in a virtual reality (VR) environment.
Glucose transporter deficiency syndrome type 1 (GLUT1DS) is a rare, genetically determined, neurometabolic disorder . It is estimated that about 90% of affected patients present various pathological gait patterns. Ataxic, spastic, ataxo-spastic, or dystonic walking are the main manifestations described to date. The kinematic gait analysis with inertial sensors represents a method that is easily applicable in clinical practice, with possible application in numerous neurological syndromes of the pediatric and adult age. Through the kinematic gait analysis, it will be possible to obtain an accurate characterization of the gait of patients with GLUT1DS. This will allow, in the first place, a better knowledge of locomotor parameters in this rare cohort of patients. Given that kinematic analysis through a wearable sensor is a method that can be easily integrated into daily clinical practice, the data obtained could become prognostic biomarkers and significant outcome measures of the disease (also in relation to possible improvements deriving from treatment with a ketogenic diet or in the context of future pharmacological trials).
Study Description: We want to analyze the data collected under Protocol 04-N-0188. Objectives: To assess the eye blink rate (EBR) during different behavioral conditions. Study Population: No new subjects will be enrolled. Adult (greater than or equal to 18 years old) subjects in Protocol 04-N-0188 included the following: 1. patients with craniofacial dystonia, 2. first degree relatives of patients with craniofacial dystonia, 3. age matched control group. Description of Sites/Facilities conducting research: All data analysis will take place either on the NIH Main campus or remotely using NIH-provided computers and laptops. Study Duration: 12 months.
In this study, we will compare the degree of postoperative symptom improvement, postoperative complication rate, postoperative quality of life improvement degree of patients with Meige syndrome undergoing pallidotomy (unilateral globus palliotomy) and deep brain stimulation (unilateral globus pallidus) ,in order to get the conclusion of the comparison of the clinical efficacy of the two surgical plans. In addition, possible predictive factors such as age, gender, age of onset, length of disease course, scale baseline score, preoperative brain PET-CT function analysis and other possible predictive factors are added for analysis, in order to find predictive factors that can guide the choice of surgical options.
The first line of therapy for cervical dystonia patients is botulinum toxin injections, however injection parameter determination and optimization are challenging for physicians to do. In addition, some patients receiving this treatment long-term experience short duration of relief. Thus, Dysport (Ipsen Biopharmaceuticals), another BoNT-A formulation, may increase the duration of clinical benefit. The objective of this study is to compare the wearing off time of their original BoNT-A formulation (same injection parameters for at least 3 cycles) and the optimized treatment of Dysport (after 2 injection cycles). Ideally, the clinical benefits should last 2.5 - 3 months as injections are administered every 3 months. Conversion to Dysport will be conducted and optimization of Dysport dosing will be done using our sensor-technology assessment. It is unclear whether there are differences in the neurophysiological effects between BoNT-A formulations, such as blocking spinal afferent signals from proprioceptive mechanoreceptors of the injected muscles contributing to CD or the modulation of cortical activity [8]. The underlying pathophysiology of impaired motor control in CD is theorized to be caused by abnormal somatosensory processing that affects proprioceptive and tactile function [8]. By altering the processing of proprioceptive signals from the muscles to the cortical somatosensory-motor areas, proprioceptive perception can be modulated and possibly normalize activity of the somatosensory-motor areas in CD. Thus, it is hypothesized that BoNT-A may indirectly modulate these cortical pathways and Dysport may have a longer modulatory effect to produce a longer lasting clinical response.
This is a single-center, open-label study of AUSTEDO in study subjects with dystonia. The study will provide preliminary experience of the safety, tolerability, and clinical activity of AUSTEDO in study subjects with dystonia. Study duration will be up to 13 weeks from screening (Visit 1) to the post treatment evaluation (Visit 5). Treatment period from drug initiation to final on-treatment Visit will be 12 weeks, or less, as follows: during the ramp-up period, study drug will start at 12 mg/day (6 mg twice daily) and will be titrated weekly by 6 mg/day increments until either 1) the maximal allowable dose (48 mg/day) is reached, or 2) dose-limiting side-effects occur. In study subjects receiving a strong CYP2D6 inhibitor, the maximum allowed dose of AUSTEDO will be 36 mg/day, reducing study duration (due to a reduction in the ramp-up period) to 11 weeks. Study subjects who experience dose-limiting side effects will be maintained on their maximum tolerated dose. Once the maximal dose is established for each participant, they will complete 6 continuous weeks on this dose (maintenance period), followed by a 1-week washout. For study subjects unable to titrate up to 48 mg/day due to side effects, the 6 weeks of maintenance will start once they reduce the study drug back to the maximum well-tolerated dose. Adverse events will be monitored throughout the study and will be reported after drug initiation. Dose reductions, suspensions, and withdrawals due to adverse events will be recorded. ECG readings will be measured at screening, during week 2, during the first week of the maintenance period (whenever this is established to be, typically week 7 for subjects able to titrate up to 48 mg/day), immediately before washout (week 12 for those study subjects who are able to titrate up to 48 mg/day) and during week 13. Assessment of Columbia Suicide Severity Rating Scale and Epworth Sleepiness Scale scores will occur at screening and all clinic Visits. The Mini Mental (MMSE) Scale will be performed at screening and at the final on-treatment Visit (week 12). A video examination of the study subjects will be made at screening (right before initiation of the study drug), and after 6 weeks on AUSTEDO at a steady dose (right before drug cessation). Part III of the MDS-UPDRS will be performed at both of these Visits as well to screen for the appearance of drug-induced parkinsonism. Videos will be sent to raters blinded to treatment, Visit number and recording date.
This is an exploratory pilot study to identify neural correlates of specific motor signs in Parkinson's disease (PD) and dystonia, using a novel totally implanted neural interface that senses brain activity as well as delivering therapeutic stimulation. Parkinson's disease and isolated dystonia patients will be implanted unilaterally or bilaterally with a totally internalized bidirectional neural interface, Medtronic Summit RC+S. This study includes three populations: ten PD patients undergoing deep brain stimulation in the subthalamic nucleus (STN), ten PD patients with a globus pallidus (GPi) target and five dystonia patients. All groups will test a variety of strategies for feedback-controlled deep brain stimulation, and all patients will undergo a blinded, small pilot clinical trial of closed-loop stimulation for thirty days.
In this study, using computerized cognitive assessments combined with multi-modal neuroimaging approach investigators aim to address three specific questions on patients with cervical and myoclonus dystonia: (i) investigate various aspects of the sense of agency and relationship to the severity of dystonia symptoms, (ii) characterize the possible link between abnormalities of movement perception and alteration of sense of agency in dystonia, (iii) (identify the neuronal underpinnings of the defective sense of agency in dystonia.
Researchers want to test a procedure called deep brain simulation (DBS) to treat focal hand dystonia (FHD). A device called a neurostimulator is placed in the chest. It is attached to wires placed in brain areas that affect movement. Stimulating these areas can help block nerve signals that cause abnormal movements. Objectives: To test DBS as treatment for FHD. To learn about brain and nerve cell function in people with dystonia. Eligibility: People ages 18 and older with severe FHD who have tried botulinum toxin treatment at least twice Design: Participation lasts 5 years. Participants will be screened with: Medical history Physical exam Videotape of their dystonia Blood, urine, and heart tests Brain MRI scan Chest X-ray Neuropsychological tests: answering questions, doing simple actions, and taking memory and thinking tests. Hand movement tests Participants will have surgery: A frame fixes their head to the operating table. A small hole is made in the skull. Wires are inserted to record brain activity and stimulate the brain while they do simple tasks. The wires are removed and the DBS electrode is inserted into the hole. The neurostimulator is placed under the skin of the chest, with wires running to the electrode in the brain. They will have CT and MRI scans during surgery. Participants will recover in the hospital for about 1 week. The neurostimulator will be turned on 1 4 weeks after discharge. Participants will have regular visits until the study ends. Visits include: Checking symptoms and side effects MRI Movement, thinking, and memory tests If the neurostimulator s battery runs out, participants will have surgery to replace it. ...