View clinical trials related to Dystonia.
Filter by:This study is a retrospective chart review to evaluate the doses of botulinum Type A toxins BOTOX® (onabotulinumtoxinA) and Xeomin® (incobotulinumtoxinA) used for the treatment of Cervical Dystonia and Blepharospasm in clinical practice.
Background: - People with dystonia cannot control their muscle contractions. This disorder can affect different body areas. When it affects the face, tongue, and jaw, it is called oromandibular dystonia (OMD) or cranial dystonia (CD). Researchers want to find out if a drug that treats seizures may help people with this kind of dystonia. Objective: - To see if levetiracetam can improve symptoms of jaw or face dystonia. Eligibility: - Adults ages 18 70 with OMD or CD. Design: - Participants will be screened with a medical history and physical exam. Researchers will test how severe their dystonia is. - Participants will have blood drawn through a needle in the arm. - Participants will be assigned to take either levetiracetam or placebo. - Phase 1: - Participants will start with one 500-mg tablet twice daily. The dose will be increased by 500 mg every 3 days. The maximum dose will be 4000 mg a day over 3 weeks. Participants who cannot tolerate that will take the highest dose they can. - Participants will return for study visits at weeks 3 and 6. They will be asked about their health, side effects, and symptoms of depression. They will have a neurological examination and test of their dystonia. - After the week 6 visit, participants will taper and stop the study drug over about 1 week. - Phase 2 begins one week later. Participants will repeat phase 1, but with the other drug. - After phase 2, participants will return to their usual clinics. They will be told how to stop taking the drug. They will have a follow-up phone call 2 weeks later.
Dystonia is a devastating disorder defined by involuntary, sustained muscle contractions or abnormal postures that can affect any part of the body. Cervical dystonia (CD) is the most pervasive form of dystonia affecting 60-90,000 individuals in the United States alone and is characterized by involuntary twisting of the neck. The symptoms of CD are disabling, disfiguring, painful, and have a strongly negative impact on quality of life, including social withdrawal and depression. At present, there is no treatment that has been shown to have long term benefit in CD. Standard of care (SOC) is botulinum toxin, which temporarily paralyzes affected muscles, resulting in reduced muscle spasms. This treatment has many undesirable side effects, variable effectiveness, is expensive, and must be repeated every 3 months throughout the lifespan. Physical therapy based treatments aimed at retraining posture or stretching dystonic muscles are largely ineffective and not typically delivered as a part of standard of care. There is an urgent need for novel and effective therapies. Emerging technologies, specifically non-invasive brain stimulation (NBS), have demonstrated compelling evidence to make a meaningful impact in the lives of people with CD. In this study, individuals with cervical dystonia will be randomly assigned to receive tDCS for 15 minutes daily for 4 days in 1 of 4 stimulation location groups. Hypothesis 1: One location of stimulation will result in clear benefit with at least 1 standard deviation (SD) improvement in the CDQ-24, the primary outcome measure, at 1-week follow-up. Hypothesis 2: The cortical silent period will be the most sensitive measure investigated and will demonstrate significant increase in inhibition as determined by an elongation of silent period in the affected upper trapezius muscle. Hypothesis 3: The stimulation location determined to be most effective in Objective 1 will produce the greatest physiologic change in inhibition increase. Hypothesis 4: The hypothesis for this aim is if certain characteristics can predict response to treatment, a strong association will be seen between baseline measure(s) and the primary outcome measure. A thorough assessment of characteristics including: age, sex, duration of symptoms, genotyping for two specific polymorphisms, botulinum toxin history, baseline measures of outcome variables, measures of brain excitability, and genetic testing will predict response.
This study aims to compare Botox injections without Physical Therapy sessions to Botox injections combined with Physical Therapy sessions for treatment of Cervical Dystonia. It is expected that Botox combined with Physical Therapy will improve Cervical Dystonia symptoms and quality of life more than Botox alone. It is also expected that Botox combined with Physical Therapy will enhance neuroplasticity, or the ability of the brain to make new connections, more than Botox alone at 4-5 weeks, and remain improved at 12 weeks, after Botox injection.
Investigation of the clinical condition in patients with cervical dystonia by Toronto Western Spasmodic Torticollis Scale (TWSTRS)
Investigation of the clinical condition and safety in patients with cervical dystonia
Cervical dystonia (CD) is the most common focal dystonia. Currently there are no effective oral medications for the treatment of CD. While botulinum toxin injections improve symptoms, they require repeated injections by a trained physician and some patients stop responding to injections or never respond at all. Therefore, alternative treatment options for CD are needed. One new agent is a drug that targets glutamate receptors that are thought to be involved dystonia. This drug, perampanel, was originally developed for epilepsy and is licensed for use in the USA and Canada for treating epilepsy. The purpose of this study is to test the effectiveness of perampanel in treating the symptoms of CD.
The investigational drug being studied in this protocol is Incobotulinumtoxin A (Xeomin®). Botulinum toxin (BoNT) prevents the release of the acetylcholine from peripheral nerves, inhibiting muscle contractions. BoNT is effective in relaxing overactive muscles. In musician's dystonia, the ability to reduce abnormally overactive muscles in the hand can be critical for the musical professional to continue his or her career. With the use of EMG/electrical stimulation and/or ultrasound guidance, the injector can precisely localize the individual muscles that are affected in this condition with great accuracy. Prior studies have shown that BoNT injections produce beneficial effects in forearm muscles, and less effect in shoulder or proximal arm muscles. Possible risks in treating patients with BoNT include excessive weakness of the injected muscles. The drug may also affect non-targeted muscles. However these risks will be minimized during the screening period by carefully targeting the affected muscles and by administering low doses of BoNT. Small booster doses may be given at follow up visit (2, 4, 14 and 16-weeks after the primary injection date) if the initial injection was insufficient to produce sufficient efficacy in relief of the focal dystonia and did not produce excess weakness of the targeted muscle.
Background: - Focal hand dystonia (FHD) causes muscles to contract, leading to abnormal movements or postures. Musicians, writers, and athletes often get it. Researchers want to study how patients with this condition learn, a process of the brain that depends on a property called plasticity. Objective: - To study brain plasticity in people with FHD. Eligibility: - Right-handed adults 18 years and older with FHD. - Healthy, right-handed adult volunteers. Design: - Participants will be screened with medical history, physical exam, pregnancy test, and questionnaire about their right-handedness. - Participants will have 2 study visits on 2 different days. - Participants will sit in a chair and have up to 30 Transcranial Magnetic Stimulation (TMS) pulses on the left side of the head. A brief electrical current passes through a wire coil on the scalp. They will hear a click and may feel a pulling on the skin or muscle twitches. They may have to keep their eyes open and remain alert, tense certain muscles, or perform simple finger movements. - Forty more pulses, with 10 seconds between, will be given on the left side of the head. Some will be small, some big. - Researchers will measure muscle response through small electrodes taped to the right hand. - A cloth cap will be put on the participant s head. Researchers will write on tape on the cap. - Participants will have the r-PAS. An electrical stimulator will be placed on the nerve at the right wrist. Repeated magnetic pulses will be delivered in trains or short bursts together with electrical stimulation of nerve. Participants will receive up to 840 pulses. - Participants will be contacted after a few days for a follow-up check.
It is often difficult to quantify and distinguish aspects of abnormal muscle tone due to neurological injury. This makes it difficult to evaluate therapies that aim to reduce the effects of abnormal muscle tone. This research study will evaluate the feasibility of a clinician worn device to capture and quantify features of spasticity and dystonia.