View clinical trials related to Dystonia.
Filter by:The purpose of this study is to evaluate if there is an improved response in CD symptoms when Keppra is used as adjunctive therapy to Botox.
This study will examine how the brain controls speech in patients with spasmodic dysphonia, a voice disorder that involves involuntary spasms of muscles in the larynx (voice box), causing breaks in speech. Although the causes of spasmodic dysphonia are unknown, recent studies found changes in brain function in patients with the disorder that may play a role in its development. People between 21 and 80 years of age with adductor spasmodic dysphonia may be eligible for this study. Candidates are screened with the following procedures: Medical history and physical examination. Nasolaryngoscopy to examine the larynx. For this test, the inside of the subject s nose is sprayed with a decongestant and a small, flexible tube called a nasolaryngoscope is passed through the nose to the back of the throat to allow examination of the larynx. The subject may be asked to talk, sing, whistle and say prolonged vowels during the procedure. The nasolaryngoscope is connected to a camera that records the movement of the vocal cords during these tasks. Voice and speech recording to measure the type and severity of voice disorder. Subjects are asked questions about their voice disorder and their voice is recorded while they repeat sentences and sounds. Participants undergo positron emission tomography (PET) and magnetic resonance imaging (MRI) of the brain, as follows: PET: A catheter is placed in a vein in the subject s arm to inject a radioactive substance called a tracer that is detected by the PET scanner and provides information on brain function. [11C]flumazenil is used in one scanning session and [11C]raclopride is used in another. For the scan, the subject lies on a bed that slides in and out of the doughnut-shaped scanner, wearing a custom-molded mask to support the head and prevent it from moving during the scan. For the first scan the subject lies quietly for 60 minutes. For the second scan, the subject lies quietly for 50 minutes and is then asked to say sentences during another 50 minutes. The amount of radiation received in this study equals to a uniform whole-body exposure of 0.9 rem, which is within the dose guideline established by the NIH Radiation Safety Committee for research subjects. The guideline is an effective dose of 5 rem received per year. MRI: This procedure uses a strong magnetic field and radio waves instead of X-rays to obtain images of the brain. The subject lies on a table that slides into the scanner, a narrow metal cylinder, wearing ear plugs to muffle loud knocking sounds that occur during the scan. Images of the brain structure are obtained while the subject lies still in the machine for 10 minutes. This is followed by functional MRI (fMRI) for 60 minutes, in which pictures are taken while the subject speaks, showing changes in brain regions that are involved in speech production.
The investigators wish to establish on a small scale the effectiveness of adding the physiotherapy programme developed by Jean-Pierre Bleton to the present standard treatment for cervical dystonia with a view to undertaking a larger UK-wide trial looking at overall cost-effectiveness. Specifically, the investigators wish to establish: 1. Whether this specific physiotherapy program for cervical dystonia improves patient outcomes in terms of neck position, pain, disability, and quality of life compared to simple physiotherapy advice? 2. What is the minimal clinically important change in the new CDIP-58 quality of life measure for cervical dystonia from a patient's perspective that could then be used to plan a definitive trial of this technique? 3. What are the economic implications of the specialized physiotherapy programme?
Five hundred patients with a confirmed clinical diagnosis of Cervical Dystonia (CD)are planned for enrollment into this open label study. These patients will be Type B toxin naive patients with CD. During this study patients will receive repeat injections of MYOBLOC when deemed appropriate by the Investigator. However, it will be recommended that injections occur not more frequently than every 12 weeks. Total duration of exposure to MYOBLOC will be targeted for at least two years, with potential exposure for up to 7 years in patients with earliest enrollment
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.
To test the hypothesis that sedation induced by Dexmedetomidine at levels appropriate for awake, DBS surgery has no significant effect on electrophysiological parameters of DBS micro-electrode recordings
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.
The purpose of this study is to allow patients to undergo deep brain stimulation (DBS) surgery for the treatment of dystonia. This is NOT a research study, but rather, a requirement by the FDA for humanitarian use of the deep brain stimulator device in the treatment of this rare disorder. Use of DBS for dystonia is approved for humanitarian use by the FDA in the treatment of chronic, intractable (drug refractory) dystonia, including generalized and segmental dystonia, hemidystonia, and cervical dystonia (torticollis) in patients 7 years or older. Thus, this proposal request authorization by the IRB to allow patients at VUMC to access this HUD therapy.
Patients 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.
The NIH grant has funded the development of a physiological brain atlas registry that will allow us to significantly improve the data collectioin and use of physiological data into a normalized brain volume. This initially was used to improve DBS implants for Parkinson's Disease, Dystonia, Essential Tremor, and OCD, but now includes data acquired during all stereotactic brain procedures.