Active clinical trials for "Dystonia"

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 examine the action of sensory tricks on an occurrence known as surround inhibition when there is a disorder of muscle tone affecting a single body part in isolation. Surround inhibition refers to a situation that suppresses unwanted movements, known as dystonia, in surrounding muscles during voluntary actions. There are tricks-various actions-that people use to temporarily stop those unwanted movements. Such tricks can include touching the affected body part, placing an object in the mouth, pulling the hair, and others. Often these tricks are beneficial early in the illness but become less effective as it progresses. This study is guided by a hypothesis that sensory tricks will restore surround inhibition and by another hypothesis that it is the application of the tricks, not simply sensory input, that is effective in doing that restoring. Emphasis is on cervical dystonia, involuntary actions affecting the neck, in which the tricks commonly involve the cheeks and chin. The technique used in the study is transcranial magnetic stimulation (TMS). Patients ages 18 and older who have cervical dystonia with at least one effective trick and patients with no effective trick may be eligible for this study. There will also be a control group of healthy participants. Participants will be asked to show the sensory trick and may be asked to be videotaped. During the TMS procedure, they will be seated in a comfortable chair, with hands placed on a pillow on the lap. Small electrodes-soft strips that stick to the skin-will be placed on the skin to record the electrical activity of some muscles in the neck that are activated by the stimulation from TMS. In TMS, there will be a wire coil held over the scalp. A brief electrical current will be passed through the coil, creating a magnetic pulse that stimulates the brain. Patients will hear a click and may feel a pulling sensation on the skin under the coil. There may be muscle twitches of the face, arm, or leg. In addition, patients may be asked to tense certain muscles slightly or perform other simple actions so that the coil can be positioned appropriately. Patients will sometimes be asked to bite down and tap their teeth slightly for about 1-1/2 minutes at a time. They will be asked to show the sensory trick. The stimulation is usually not painful, although sometimes strong contractions of the scalp muscles can cause discomfort or a headache. Patients can ask to have the procedure discontinued at any time. The testing session takes about 2 hours, done on an outpatient basis.

This is a study of subjects with the St. Jude Medical Infinity deep brain stimulation (DBS) system who undergo an MRI imaging procedure. Enrollment may occur before DBS implant, or when an MRI scan is planned in a subject with an existing implant. There will be a follow-up visit one month after the MRI procedure to document any adverse events and verify device functionality.

There are two phases. Phase I: A single visit which includes a screening, clinical scales, and a MRI scan with simultaneous tES/sham tES in a randomized block design. Enrolls both Cervical Dystonia (CD) patients and healthy controls. Phase II: 5 consecutive days of 30-90 min visits to campus for tES or sham tES. Transcranial magnetic stimulation (TMS) measures and clinical scales will also be included on Day 1 and Day 5 visits. Enrolls only CD patients.

Dystonia is a disabling symptom affecting both patients with idiopathic Parkinson's disease (PD) and atypical parkinsonism (AP). Botulinum toxinum (BoNT), by blocking muscle contraction, is a possible treatment for focal dystonia. The benefit of BoNT treatment has been proven in some focal dystonia associated with PD or AP. The investigators aim to give an overview of the efficacy of BoNT in a variety of focal dystonia in a large cohort of parkinsonian patients.

Our hypothesis is that botulinum toxin injections (with onabotulinum toxin, incobotulinum toxin, and abobotulinum toxin) given at 10-week or shorter intervals for the indication of treatment of muscle spasms associated with neurological disorders are associated with equal safety and effectiveness as those given at 12-week or longer intervals. We also hypothesize that for those patients who would prefer a shorter inter-injection interval, but for whom their insurance carrier has prevented this, have worse health-related quality of life compared to patients who receive injections at a 10-week or shorter interval. We aim to investigate this hypothesis by collecting demographic and injection data and patient survey responses.

Background: Essential tremor is when a person has tremor, but no other neurological symptoms. Dystonic tremor is when a person also has dystonia. Dystonia is a condition in which muscle contraction causes changes in posture. Researchers do not fully know what areas of the brain cause these tremors, or how the types differ. They also do not know what tests can identify the differences. Objective: To look at differences between essential tremor and dystonic tremor. Eligibility: People ages 18 and older with or without tremor Design: Participants will be screened with medical history, physical exam, and urine tests. Those with tremor will complete questionnaires about how tremor affects them. The screening and study visits can be done on the same day or on separate days. Participants will have 1 or 2 study visits. These include magnetic resonance imaging (MRI) and tremor testing. For MRI, participants will lie on a table that slides in and out of a cylinder that takes pictures. Sensors on the skin measure breathing, heart rate, and muscle activity. This takes about 2 hours. Tremor testing will include transcranial magnetic stimulation (TMS), electrical stimulation of the fingers, doing a movement task, and recording of tremor movements. For TMS, two wire coils will be held on the scalp and a brief magnetic field will be produced. A brief electrical current will pass through the coils. For the other tests, small sticky pad electrodes will be put on the skin. Participants will move their hand when they hear a sound. They will get weak electrical shocks to their fingers. These tests will take 3-4 hours. Participants can take part in either or both parts of the study.

Background: Researchers have some data on how the brain controls movement and why some people have tremor. But the causes of tremor are not fully known. Researchers want to study people with tremor to learn about changes in the brain and possible causes of tremor. Objective: To better understand how the brain controls movement, learn more about tremor, and train movement disorder specialists. Eligibility: People ages 18 and older with a diagnosed tremor syndrome Healthy volunteers ages 18 and older Design: Participants will be screened with: Medical history Physical exam Urine tests Clinical rating scales Health questions They may have electromyography (EMG) or accelerometry. Sensors or electrodes taped to the skin measure movement. Participation lasts up to 1 year. Some participants will have a visit to examine their tremor more. They may have rating scales, EMG, and drawing and writing tests. Participants will be in 1 or more substudies. These will require up to 7 visits. Visits could include the following: EMG with accelerometry Small electrodes taped on the body give small electric shocks that stimulate nerves. MRI: Participants lie on a table that slides into a cylinder that takes pictures of the body while they do simple tasks. Small electrodes on the scalp record brain waves. A cone with detectors on the head measures brain activity while participants do tasks. A wire coil held on the scalp gives an electrical current that affects brain activity. Tests for thinking, memory, smell, hearing, or vision Electrodes on the head give a weak electrical current that affects brain activity. Photographs or videos of movement Participant data may be shared with other researchers.

The purpose of the protocol is to determine typical patient response to Dysport in the treatment of adult cervical dystonia (CD).

Botulinum toxin injection in the contracting muscles has proven to be a safe and effective method of relieving pain and lessening dystonic posturing. The current hypothesis is that botulinum toxin works on altering sensory input in the central nervous system in addition to its effects on the neuromuscular junction. Magnetoencephalography (MEG)of brain has been used in dystonia such as writer's cramp and musician's hand dystonia. However, no study has investigated the correlation of central signal changes via magnetoencephalography before and after treatment with botulinum in torticollis patients. Prior studies using somatosensory potentials indicated the possibility of differential activation of precentral cortex in patients with cervical dystonia. Cervical dystonia may result from a disorder of both cortical excitability and intracortical inhibition. The investigators hypothesis is that botulinum injection modulates central inhibition which improves clinical outcome for torticollis.