View clinical trials related to Dystonia.
Filter by:In this study we are looking at primary focal dystonias, including dystonias of the limbs, eyes, jaw or face, neck, and vocal chords. This study will use magnet resonance imaging (MRI) to see how the brain reacts while resting and doing a finger-tapping task. The investigators will test the hypothesis that disturbances in functional connectivity within the motor, affective and cognitive basal ganglia networks in primary focal dystonia (PFD) underlie the motor and non-motor symptoms in this disorder.
The purpose of the study is to document long-term response in real-life practice after injection cycles with BoNT-A in subjects suffering from idiopathic cervical dystonia (Long-term clinical and pharmaco-economic data).
The purpose of the protocol is to assess the long term safety of repeat treatment cycles of Dysport® 500 U using 2 mL dilution scheme for the treatment of Cervical Dystonia. This is an extension study to study A-TL-52120-169 (hereafter referred to as Study 169).
The purpose of the protocol is to evaluate the efficacy and safety of Dysport® using 2 mL dilution compared with placebo for the treatment of Cervical Dystonia.
Background: - Blepharospasm is caused by excessive contraction of the muscles that close the eye. One treatment is botulinum neurotoxin (BoNT), which works by weakening those muscles. Like BoNT, acetyl hexapeptide-8 (AH-8) works to weaken the muscles, but is available as a skin cream. AH-8 is the active ingredient in a number of cosmetic creams used to treat wrinkles. Researchers thought that AH-8 cream could be used to treat blepharospasm, but the original dose studied was not very effective. They want to try a higher dose of AH-8 in a cream to see if it can be a more effective treatment. Objectives: - To see if AH-8 cream can improve the symptoms of blepharospasm. Eligibility: - Individuals at least 18 years of age who have blepharospasm that is severe enough to require treatment. Design: - This study will involve up to eight study visits. - Participants will be screened with a physical exam and medical history. They will answer questions about their symptoms. They will also have a blink test to see how severe the blepharospasm is. At this visit, participants will receive one of three types of cream. One cream will have a low dose of AH-8, one will have a higher dose of AH-8, and the other will be a placebo (no AH-8). - One month later, participants will have a followup visit, with tests similar to the first visit. They will also receive more of the cream. - One month later, participants will have another visit with the same tests. They will be videotaped at this visit to study their facial movements. Those who have responded to the treatment will continue to use the cream. Those who have not responded will be offered the chance to have BoNT injections, and will stop taking the cream. - One month later, participants who had BoNT injections will have a final visit to check for possible side effects. Those who continued to take the cream will continue on the study. - The fifth and sixth visits will involve the same tests as before. At the seventh visit, remaining participants will be offered the chance to have BoNT injections, and will stop taking the cream. - The final visit will check for any side effects from the cream or the injections.
This study is exploring a new experimental procedure in dystonia called repetitive transcranial magnetic brain stimulation (TMS) combined with rehabilitation. The purpose of the study is to determine whether repetitive TMS is effective as a treatment to reduce symptoms in dystonia as demonstrated by improved motor performance.
In this study, the investigators will monitor extracellular neurotransmitter levels using a probe that is able to perform real time electrochemical detection during deep brain stimulation surgery. The overall question this study is designed to answer is: Are there neurotransmitters released during deep brain stimulation?
The aim of this study is to asses the efficacy and the clinical safety of the transcranial magnetic resonance guided high intensity focused ultrasound system ExAblate 4000, InSightec Ltd. for functional neurosurgery in the treatment of movement disorders. The treatments to be conducted in this study are non-invasive, i.e. without opening the skull, and will create microthalamotomies in specific target areas such as thalamus, subthalamus and pallidum. The data obtained in this study will be used to evaluate the basic safety aspects of this new treatment technology and will serve as a basis for the clinical introduction of MR-guided ultrasound neurosurgery.
Movement disorders such as dystonia, hypertonia, and spasticity interfere with or prevent voluntary movement. Studies have suggested that using biofeedback to increase awareness of muscle activation can improve motor function in patients with motor deficits. The investigators hypothesize that the daily use of a surface electromyographic (SEMG) biofeedback device for one month will improve motor function in children and young adults with dystonia, hypertonia, and/or spasticity. The SEMG biofeedback device is worn over the muscle(s) the subject has difficulty in controlling and provides vibratory feedback about muscle activation. Groups of children and young adults (ages 3-21), with dystonia, hypertonia, and/or spasticity will be asked to wear a small (approx 1 square inch) sensory feedback device on their affected muscle(s) for 5 hours a day for one month. The device will vibrate and emit a blue light when the muscle is activated. At the start of the experiment, subjects will be tested on the Goal Attainment Scale (GAS), the Pediatric/Adolescent Outcomes Data Collections Instruments (PODCI), and the Barry Albright Dystonia Scale (BAD). For one month, subjects will practice goals without device. After a month, subject will be assessed again and be given device to practice goals for a month. After one month, the subjects will be tested on the outcome measures again and return device.
The purpose of this research study is to determine the physical brain changes in people with cervical dystonia after deep brain stimulation (DBS) surgery and as compared to healthy controls. We will do this by measuring your body's response to transcranial magnetic stimulation (TMS) before and/or after DBS surgery. TMS is a non-invasive procedure during which you sit in a chair that looks like one you would find at the dentist's office. A nerve stimulator is placed on the wrist of the right hand to stimulate the median nerve; the intensity of the nerve stimulator is gradually increased until the right thumb begins to twitch. A magnetic coil is placed on the scalp on one side of the head, overlying the brain's motor cortex, to stimulate the brain's output to the muscles in the opposite hand. If you are a control subject, and therefore will not/have not have DBS surgery, we will measure the body's response to TMS for comparison purposes. We expect that the electrical differences in the brain may be related to the physical benefits some patients with primary cervical dystonia receive from DBS surgery.