188 Clinical Trials for Various Conditions
This study will use transcranial magnetic stimulation (TMS) and electrical stimulation of nerves to examine how the brain controls muscle movement in focal hand dystonia (writer's cramp). Normally, when a person moves a finger, the brain's motor cortex prevents the other fingers from moving involuntarily. Patients with focal hand dystonia have difficulty with individualized finger movements, possibly due to increased excitability of the motor cortex. Musicians, writers, typists, athletes and others whose work involves frequent repetitive movements may develop focal dystonia of the hand. Healthy normal volunteers and patients with focal dystonia 18 years of age and older may be eligible for this study. For the TMS procedure, subjects are seated in a comfortable chair with their hands placed on a pillow on their lap. An insulated wire coil is placed on the scalp. A brief electrical current is passed through the coil, creating a magnetic pulse that stimulates the brain. This may cause muscle, hand or arm twitching if the coil is near the part of the brain that controls movement, or it may induce twitches or transient tingling in the forearm, head or face muscles. Subjects will be asked to move a finger. Just before this movement, a brief electrical stimulation will be applied to the end of either the second or fifth finger. Metal electrodes will be taped to the skin over the muscle for computer recording of the electrical activity of the hand and arm muscles activated by the stimulation. The testing will last 2-3 hours. ...
This study will use transcranial magnetic stimulation (TMS) to examine how the brain controls muscle movement in dystonia. Dystonia is a movement disorder in which involuntary muscle contractions cause uncontrolled twisting and repetitive movement or abnormal postures. Dystonia may be focal, involving just one region of the body, such as the hand, neck or face. Focal dystonia usually begins in adulthood. Generalized dystonia, on the other hand, generally begins in childhood or adolescence. Symptoms begin in one area and then become more widespread. Healthy normal volunteers and patients with focal \[or generalized\] dystonia \[between 21 and 65 years of age\] may be eligible for this study. Participants will have transcranial magnetic stimulation. For this test, subjects are seated in a comfortable chair, with their hands placed on a pillow on their lap. An insulated wire coil is placed on the scalp. A brief electrical current is passed through the coil, creating a magnetic pulse that stimulates the brain. (This may cause muscle, hand or arm twitching if the coil is near the part of the brain that controls movement, or it may induce twitches or transient tingling in the forearm, head or face muscles.) During the stimulation, subjects will be asked to either keep their hand relaxed or move a certain part of the hand in response to a loud beep or visual cue. Metal electrodes will be taped to the skin over the muscle for computer recording of the electrical activity of the hand and arm muscles activated by the stimulation. There are three parts to the study, each lasting 2-3 hours and each performed on a separate day.
This study will use transcranial magnetic stimulation to examine how the brain controls muscle movement in focal and generalized types of dystonia. Dystonia is a movement disorder in which involuntary muscle contractions cause uncontrolled twisting or abnormal postures. Dystonia may be focal, involving just one region of the body, such as the hand, neck or face. Focal dystonia usually begins in adulthood. Generalized dystonia, on the other hand, generally begins in childhood or adolescence. Symptoms begin in one area and then become more widespread. Healthy normal volunteers and patients with focal or generalized dystonia 8 years of age and older may be eligible for this study. First-degree relatives of patients will also be enrolled. In transcranial magnetic stimulation, an insulated wire coil is placed on the subject's scalp and brief electrical currents are passed through the coil, creating magnetic pulses that pass into the brain. These pulses generate very small electrical currents in the cortex-the outer part of the brain-briefly disrupting the function of the brain cells in the stimulated area. The stimulation may cause muscle twitching or tingling in the scalp, face and limbs. During the stimulation, the subject will be asked to either keep the hand relaxed or to slightly tense certain muscles in the hand or arm. The test will last about 1.5 hours. The cause of dystonia is unknown. It is hoped that a comparison of brain activity in normal volunteers, patients and their relatives not affected by dystonia will help scientists learn why some people develop dystonic movements.
This study will examine the effectiveness of Braille reading as a sensory training program for improving symptoms of focal (localized) dystonia, a movement disorder caused by sustained muscle contractions. Musicians, writers, typists, athletes and others whose work involves frequent repetitive movements may develop focal dystonia of the hand. Dystonia patients have an impaired sense of touch, and it is thought that symptoms may improve with sensory tactile (touch) training. Patients with task-specific dystonia and healthy normal volunteers may be eligible for this 8-week study. Patients will undergo evaluation of their dystonia and a complete neurologic examination. Healthy volunteers will have a complete physical examination. On the first day of the study, after 4 weeks and after 8 weeks, all participants will have a gap detection test for sensory perception testing. The test uses eight plastic devices called JVP-Domes with ridges of different widths on the surface. The subject's arm and hand are held in palm-up position and the right index finger is tested for about 1 second 20 times with each dome. The subject is asked to report whether the direction of the dome is vertical or horizontal. The test takes about 30 minutes. Patients with dystonia will also have a their symptoms evaluated at these visits. The evaluation involves completing a written questionnaire and writing a paragraph. All participants will be trained in Braille reading at NIH. Sessions will be given every day the first week, twice a week the second and third weeks, and once a week the following weeks.
The goal of this clinical trial is to better understand the effects of intrathecal baclofen (ITB) on children with dystonic cerebral palsy (CP). The main questions this study aims to answer are: (1) Determine if ITB reduces dystonia while identifying other potential benefits, (2) Identify the characteristics of children with the best response to ITB (3) Develop a holistically representative composite outcome measure for dystonic CP. This study will evaluate patient improvement by using a standardized titration, or medication management, protocol to gradually increase the childs ITB dosages over a 12-month period until they achieve maximum benefit with minimal to no side effects. This titration protocol mimics what is currently done through routine care but with more precision. This study will also directly measure the global effects of ITB, taking into account spasticity, known dystonia triggers (e.g. pain), and patterns of CNS injury that cause dystonia. Participants will: 1. Complete a total of 4 additional clinic visits outside usual care. These appointments will be with physical and occupational therapists as well as the study PI to complete evaluations for dystonia, spasticity, and function. 2. Complete several questionnaires at these visits. The total duration of the study for an individual child will be 12 months.
This research involves retrospective and prospective studies for clinical validation of a DystoniaNet deep learning platform for the diagnosis of isolated dystonia.
The researchers will examine functional neural correlates that differentiate between laryngeal dystonia and voice tremor and contribute to disorder-specific pathophysiology using a cross-disciplinary approach of multimodal brain imaging.
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.
This study will examine the prevalence of four previously identified non-motor markers in a population of cervical dystonia patients, unaffected family members, and healthy volunteers in an attempt to identify a distinct combination of non-motor symptoms that may be indicative of disease development.
The purpose of this study is to (1) investigate the effect of known dystonia-causing mutations on brain structure and function, to (2) identify structural brain changes that differ between clinical phenotypes of dystonia, and to (3) collect DNA, detailed family history, and clinical phenotypes from patients with idiopathic dystonia with the goal of identifying new dystonia-related genes. Investigators will be recruiting both healthy control subjects and subjects with any form of dystonia. For this study there will be a maximum of two study visit involving a clinical assessment, collection of medical and family history, task training session, an MRI using the learned tasks, and finally a blood draw for genetic analysis. In total, these visits will take 3-5 hours. If the dystonia subjects receive botulinum toxin injections for treatment, the participants and their matched controls will be asked to come for a second visit.
This study occurs during five visits that are already scheduled as part of "Biomarkers to Guide Directional DBS for Parkinson's Disease" (ClinicalTrials.gov Identifier: NCT03353688). If participants have dystonia associated with Parkinson's disease, the investigators will consent and administer one additional rating scale (Burke-Fahn-Marsden Dystonia Rating Scale) to assess the severity of dystonia.
This study will determine if posture and heart rate variability will significantly improve in Parkinsons disease with camptocormia after osteopathic manual treatments dystonia.
Background: Dystonia is a movement disorder in which a person s muscles contract on their own. This causes different parts of the body to twist or turn. The cause of this movement is unknown. Researchers think it may have to do with a chemical called acetylcholine. They want to learn more about why acetylcholine in the brain doesn t work properly in people with dystonia. Objective: To better understand how certain parts of the brain take up acetylcholine in people with dystonia. Eligibility: Adults at least 18 years old who have DYT1 dystonia or cervical dystonia. Healthy adult volunteers. Design: Participants will be screened with a medical history, physical exam, and pregnancy test. Study visit 1: Participants will have a magnetic resonance imaging (MRI) scan of the brain. The MRI scanner is a metal cylinder in a strong magnetic field that takes pictures of the brain. Participants will lie on a table that slides in and out of the cylinder. Study visit 2: Participants will have a positron emission tomography (PET) scan. The PET scanner is shaped like a doughnut. Participants will lie on a bed that slides in and out of the scanner. A small amount of a radioactive chemical that can be detected by the PET scanner will be given through an IV line to measure how the brain takes up acetylcholine. ...
The purpose of this study is to use an investigational device to record brain activity for 12-24 months following surgical implantation of deep brain stimulation (DBS) systems. The goal of the study is better understanding of brain activity in movement disorders and how they relate to DBS, not to bring new devices to market.
The purposes of this study are to identify persons with rapid-onset dystonia-parkinsonism (RDP) or mutations of the RDP gene, document prevalence of the disease, and map its natural history.
This study will investigate differences among people with focal dystonia (FD), complex regional pain syndrome (CRPS) and people who have both conditions to learn more about the cause of both disorders. Participants undergo the following procedures in five visits: * Electroencephalography (EEG). Electrodes (metal discs) are placed on the scalp with an electrode cap, a paste or a glue-like substance. The spaces between the electrodes and the scalp are filled with a gel that conducts electrical activity. Brain waves are recorded while the subject lies quietly and sensory stimulation is applied to the thumb or finger. * Magnetic resonance imaging (MRI). This test uses a magnetic field and radio waves to obtain images of body tissues and organs. The patient lies on a table that can slide in and out of the scanner, wearing earplugs to muffle loud knocking and thumping sounds that occur during the scanning process. The procedure lasts about 45 minutes, during which time the patient will be asked to lie still for up to 15 minutes at a time. * Transcranial magnetic stimulation (TMS). An insulated wire coil is placed on the scalp and a brief electrical current is passed through the coil. The current induces a magnetic field that stimulates the brain. There may be a pulling sensation on the skin under the coil and a twitch in muscles of the face, arm or leg. During the stimulation, subjects may be asked to keep their hands relaxed or to contract certain muscles. * Peripheral electrical stimulation. In two experiments, TMS is combined with peripheral electrical stimulation, similar to what is used in nerve conduction studies, to the median nerve at the wrist. There may be muscle twitching. * Surface electromyography. For TMS tests and peripheral electrical stimulation, electrodes are filled with a conductive gel and taped to the skin to record the electrical activity of three muscles on the right hand. * Needle EMG. A needle is inserted into a muscle to record the electrical activity. * Nerve conduction studies. A probe is placed on the skin to deliver a small electrical stimulus, and wires are taped to the skin record the nerve impulses. These studies measure the speed with which nerves conduct electrical impulses and the strength of the connection between the nerve and the muscles. * Skin biopsy. Two sites are biopsied. A local anesthetic is given to numb the area and a 1/4-inch piece of skin is removed with a special tool. * JVP domes. Subjects are tested for their ability to discriminate sensory stimuli in the affected region and on the other side of it. They are asked to discriminate between stamps with grooves of different widths that are applied to the hands or feet.
This study will examine how chemical changes in the brain produce symptoms of hand dystonia. Patients with dystonia have muscle spasms that cause uncontrolled twisting and repetitive movement or abnormal postures. In focal dystonia, just one part of the body, such as the hand, neck or face, is involved. The study will use positron emission tomography (PET) to find our which areas of the brain in patients with focal hand dystonia differ from healthy volunteers without focal hand dystonia. Healthy volunteers and patients with focal hand dystonia between 18 and 65 years of age may be eligible for this study. Candidates are screened with a medical history and physical and neurological examinations. Participants undergo the following procedures: * PET scanning: The PET scanner is shaped like a doughnut. The subject lies on a bed that can slide in and out of the scanner. A custom-molded plastic mask is placed on the face and head to support the head and prevent it from moving during scanning. Two radioactive substances - five doses (one per scan) of \[15 O\] water and one dose of \[11C\] flumazil are injected into the body through a vein. The dose of injected radioactive substance is very small, and they are not harmful to the body. The \[15 O\] water doses are injected during the first hour and scans are taken every 10 minutes. The \[11C\] flumazil is injected during the second hour. The radioactive substances are detected by the PET scanner and provide information on the functioning of the brain chemistry. * MRI scanning: MRI uses a magnetic field and radio waves to produce images of body tissues and organs. The patient lies on a table that is moved into the scanner (a narrow cylinder), wearing earplugs to muffle loud knocking and thumping sounds that occur during the scanning process. Scanning time for this study will be less than one hour. Subjects may be asked to lie still for up to 10 minutes at a time.
This study will use various methods to measure the activity of the motor cortex (the part of the brain that controls movements) in order to learn more about focal hand dystonia. Patients with dystonia have muscle spasms that cause uncontrolled twisting and repetitive movement or abnormal postures. In focal dystonia, just one part of the body, such as the hand, neck or face, is involved. Patients with focal hand dystonia and healthy normal volunteers between 18 and 65 years of age may be eligible for this study. Each candidate is screened with a medical history, physical examination and questionnaire. Participants undergo the following procedures: Finger Movement Tasks Subjects perform two finger movement tasks. In the first part of the study, they move their index finger repetitively from side to side at 10-second intervals for a total of 200 movements in four blocks of 50 at a time. In the second part of the study, subjects touch their thumb to the other four fingers in sequence from 1, 2, 3 and 4, while a metronome beats 2 times per second to help time the movements. This sequence is repeated for a total of 200 movements in four blocks of 50 at a time. Electroencephalography This test records brain waves. Electrodes (metal discs) are placed on the scalp with an electrode cap, a paste or a glue-like substance. The spaces between the electrodes and the scalp are filled with a gel that conducts electrical activity. Brain waves are recorded while the subject performs a finger movement task, as described above. Magnetoencephalography MEG records magnetic field changes produced by brain activity. During the test, the subjects are seated in the MEG recording room and a cone containing magnetic field detectors is lowered onto their head. The recording may be made while the subject performs a finger task. Electromyography Electromyography (EMG) measures the electrical activity of muscles. This study uses surface EMG, in which small metal disks filled with a conductive gel are taped to the skin on the finger. Magnetic resonance imaging MRI uses a magnetic field and radio waves to produce images of body tissues and organs. The patient lies on a table that can slide in and out of the scanner (a narrow metal cylinder), wearing earplugs to muffle loud knocking and thumping sounds that occur during the scanning. Most scans last between 45 and 90 minutes. Subjects may be asked to lie still for up to 30 minutes at a time, and can communicate with the MRI staff at all times during the procedure. Questionnaire This questionnaire is designed to detect any sources of discomfort the subject may have experienced during the study.
This study will use a technique called blink reflex to study and compare how the brain controls muscle movement in patients with craniofacial dystonia, their first-degree relatives, and healthy, normal volunteers. People with dystonia have sustained muscle contractions that cause twisting and repetitive movements or abnormal postures. In focal dystonia, this happens in one area of the body, such as the hand, neck, or face. Three groups of people may be eligible for this study: 1) patients 18 years of age and older with craniofacial dystonia; 2) first-degree relatives of patients with craniofacial dystonia; and 3) normal volunteers matched in age to the patients. Candidates are screened with physical and neurological examinations. Participants undergo a blink reflex study. Patients with dystonia who are receiving botulinum toxin injections must stop the medication 3 months before participating in the study and must stop any other dystonia medications, such as benzodiazepines and anticholinergics, for 12 hours before the study. For the blink reflex procedure, subjects are seated in a comfortable chair with their hands placed on a pillow on their lap. Metal electrodes are taped to the forehead for delivering small electrical shocks that feel like very brief pinpricks. Subjects receive 25 to 50 electrical stimuli, some as single shocks and some in pairs. The electrical activity of muscles that respond to the stimuli is recorded with a computer. The study takes from about 1 to 2 hours.
This 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.
This study will evaluate the effect of motor training on focal hand dystonia in people with writer's cramp and will examine whether this training affects excitability of the motor cortex of the brain. In dystonia, muscle spasms cause uncontrolled twisting and repetitive movement or abnormal postures. Focal dystonia involves just one part of the body, such as the hand, neck or face. Patients with focal hand dystonia have difficulty with individualized finger movements, which may be due to increased excitability of the motor cortex. Patients with hand dystonia 21 years of age or older may be eligible for this 2-month study. Those taking botulinum toxin injections must stop medication 3 months before entering the study. Participants will undergo a complete neurologic examination. They will undergo motor training with "constraint-induced movement therapy." This therapy involves constraining some fingers while allowing others to move. Participants will have the following tests and procedures at baseline (before motor training), after 4 weeks of motor training, and again after 8 weeks: * Handwriting analysis - A computerized program evaluates the degree of "automatic movements" the patient uses in writing, as well as writing pressure and speed. * Symptoms evaluation - Patients fill out a written questionnaire about symptoms and rate their improvement, if any, after training. * Transcranial magnetic stimulation - The patient is seated in a comfortable chair, and an insulated wire coil is placed on the scalp. Brief electrical currents pass through the coil, creating magnetic pulses that travel to the brain. These pulses generate very small electrical currents in the brain cortex, briefly disrupting the function of the brain cells in the stimulated area. The stimulation may cause muscle twitching or tingling in the scalp, face, arm or hand. During the stimulation, the patient is asked to slightly tense certain muscles in the hand or arm or perform simple actions. Electrodes are taped to the skin over the muscles activated by the stimulation, and the electrical activity in the muscles will be recorded with a computer. * Electroencephalogram (EEG) - Wire electrodes are taped to the scalp or placed on a Lycra cap the patient wears to record the brain's electrical activity. Participants will have 50-minute motor training sessions 3 times during the first week of the study, twice the second week and once each in weeks 3 and 4. In addition, they will be required to practice the training at home for 25 minutes each day during week 1 and 50 minutes each day for the remaining 3 weeks. Fingers not being trained will be splinted.
RATIONALE: Dystonia is a disorder in which the muscles that control voluntary movements are persistently or intermittently contracted (not relaxed). Deep brain stimulation is provided by a small, battery operated implant placed under the skin of the chest that delivers low voltage electrical pulses through a wire under the skin that is connected to a specific area of the brain. Deep brain stimulation may help lessen the symptoms of dystonia. PURPOSE: Phase II/III trial to study the effectiveness of deep brain stimulation in treating patients who have dystonia.
Study MTR-601-201 is an 8-week, randomized, placebo-controlled study to examine the safety, tolerability, and efficacy of MTR-601 in participants with cervical dystonia.
This project will apply transcranial direct current stimulation (tDCS) to multiple brain areas to evaluate the effects as a potential treatment for laryngeal dystonia (formerly spasmodic dysphonia).
The most common form of idiopathic dystonia is adult-onset cervical dystonia (CD), a focal form of dystonia affecting the muscles of the neck. CD is often associated with pain and limited range of motion, and frequently leads to reduced quality of life and disability. Effective long-term treatment options are extremely limited. Recurring botulinum neurotoxin (BoNT) injections can ease the symptoms of CD, but they frequently provide only partial relief and can be associated with intolerable side effects. Deep brain stimulation can be used to treat more severe cases of CD, but this neurosurgical procedure is invasive, on average only about 50% effective and may lead to serious adverse effects. Novel treatment approaches for CD are desperately needed to alleviate symptoms and improve the quality of life for the many who suffer from this chronic and disabling neurological disorder.
This study aims to apply a non-invasive brain stimulation technology called repetitive Transcranial Magnetic Stimulation (rTMS) in patients with focal hand dystonia (FHD). The goal of the study is to identify which cortical target (premotor cortex (PMC) or primary somatosensory cortex (PSC)) will show benefit after active rTMS compared to sham rTMS. A secondary goal of the study is to understand if 10 Hz rTMS can show behavioral benefit compared to sham rTMS. The study will evaluate rTMS response using measures if writing on a sensor tablet, examiner and patient dystonia rating scales and brain imaging scan (functional MRI) to understand brain changes after rTMS. Safety measures include adherence to TMS guidelines and thorough medical screening to prevent seizures.
The purpose of this study is to assess the safety and effectiveness of MRI-guided focused ultrasound (MRgFUS) for treating task specific focal hand dystonias (TSFD). TSFD is a type of dystonia that affects hand movements during specific tasks such as writing, playing instruments or typing, often causing involuntarily movements or cramping.
This study aims to investigate the impact of accelerated transcranial magnetic stimulation (TMS) on brain function and behavior in patients with focal cervical dystonia. Previous research demonstrated that individualized TMS improved writing behavior in focal hand dystonia after one session. In this study, we aim to expand the application on TMS on focal cervical dystonia. The current study administers four TMS sessions in a day. The research involves 9 in-person visits. The effect of TMS will be assessed using functional MRI brain scans and behavioral measurements. The risk of TMS includes seizures; the potential risk of seizures from TMS is mitigated through careful screening, adhering to safety guidelines. The study's main benefit is enhancing dystonic behavior and deepening the understanding of brain changes caused by TMS in cervical dystonia, paving the way for further advancements in clinical therapy for this condition.
This study aims to investigate the impact of accelerated transcranial magnetic stimulation (TMS) on brain function and behavior in patients with focal hand dystonia. Previous research demonstrated that individualized TMS improved dystonic behavior after one session. Building on this, the current study administers four TMS sessions in a day, with assessments conducted in four weeks, twelve weeks, and 20 weeks after each session. The research involves 8 in-person and 6 virtual visits focused on functional MRI brain scans and writing behavior analysis. The potential risk of seizures from TMS is mitigated through careful screening, adhering to safety guidelines. The study's main benefit is enhancing dystonic behavior and deepening the understanding of brain changes caused by TMS in focal hand dystonia, paving the way for further advancements in clinical therapy for this condition.
The purpose of this research study is to investigate how the brain and motor behavior changes in individuals with dystonia in response to exercise training.