View clinical trials related to Dystonia.
Filter by: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.
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.
Dystonia, a disabling disease with uncontrolled movement disorders was considered to be a manifestation of basal ganglia dysfunction, yet there is accumulating evidence from animal and human experiments that the cerebellum plays a prominent role in the pathophysiology of dystonia. Our recent results suggest a deficient cerebellar sensory encoding in dystonia, resulting in a decoupling of the motor component from the afferent information flow resulting from changes in the environment. An overall loss of gabaergic-mediated inhibition is at the forefront in dynamic changes in neural circuitry described in dystonia. In the mature brain gabaergic control the generation of temporal synchronies and oscillations in the glutamatergic neurons. Taken these all together with the results of a pilot experiment, the investigators hypothesize that deficient synchronies in the fast gamma range are one of the key mechanisms leading to abnormal communication inside the cerebello-cortical network in dystonia. The investigators aim first to demonstrate it by means of MEG (Magneto encepholography) recordings allowing to reconstruct the spatio-temporal dynamics of gamma oscillations in the nodes of the cerebello-cortical network. The investigators then aim to re-establish (if lost) or boost (if decreased) the defective synchronies by applying to the cerebellum at high gamma frequency a non invasive transcranial alternative current stimulation.
Deep Brain Stimulation (DBS) is an FDA approved, and widely used method for treating the motor symptoms of Parkinson's Disease (PD), Essential Tremor (ET) and Dystonia. Over 100,000 patients worldwide have now been implanted with DBS devices. The DBS target regions in the brain are the Subthalamic nucleus (STN), the Internal Segment of Globus Pallidus (GPi), or the Ventral Intermediate Nucleus of the Thalamus (VIM). In order to place the DBS electrode in the target location, a combination of two 3D imaging techniques; 3D MRI and CT, are used. Data are also collected from individual nerve cells to help find the best location for the DBS electrode in each patient. This electrode recording takes place during the standard surgical implantation of the DBS electrode, and is part of the standard clinical technique. The investigators plan to collect additional data from populations of neurons during the DBS surgery in an effort to further improve the placement of the DBS electrode. These "Local Field Potentials", LFPs, represent the activity of the collection of neurons surrounding the tip of the electrode, and will be measured during surgery along the path used for the placement of the DBS electrode. The goal of this project is to determine whether this additional data from surrounding neurons will help with optimal placement of the DBS electrode.
This study addresses postures and range of motion in cervical dystonia (Spasmodic Torticollis). It uses 3D miniature and wireless motion captures sensors, and aims to increase the understanding of the biomechanics of the movement disorders of the cervical column in this pathology. In addition, the clinical state of cervical dystonia of the patients will be assessed, using the Toronto Western Spasmodic Torticollis Rating Scale (TWSTRS). The investigators will compare the results between control and study groups.
The main purpose of this study is to investigate primary cervical dystonia as compared to healthy control subjects and DYT 1 dystonia as compared to healthy control subjects by examining cognitive measures, physical measures, and structural and functional magnetic resonance imaging (MRI). The secondary aim of this study is to investigate a specific drug therapy for primary cervical dystonia to develop a functional MRI (fMRI) research paradigm. The drug, trihexyphenidyl, is FDA approved to treat Parkinson's Disease and is commonly prescribed by physicians as a treatment for symptoms of primary cervical dystonia.
Objective: Writer s cramp (WC) is a form of focal hand dystonia (FHD). Focal injections of botulinum toxin (BoNT) are the current best therapy. Past studies showed that some types of rehabilitative therapy can be useful. The hypothesis of this study is that BoNT together with a specific type of occupational therapy will be better than BoNT alone for treating these patients. Additionally, studies on WC were hampered by the lack of objective, validated rating scales. In this pilot study, we will assess the value of a new scale compared with older scales. Study population: The study population will consist of 12 WC patients (accrual ceiling of 16). Design: Patients will be randomized so that 6 patients will receive just BoNT therapy and 6 patients will receive BoNT therapy plus occupational therapy. The physical therapy will involve specific exercises of finger movements in the direction opposite to the patient s own dystonic movements, during the writing task. The movements will be isometric against splints made to suit the individual patient. The final outcome will be assessed after 20 weeks of treatment. Patients will be evaluated on several scales, including the writer s cramp rating scale (WCRS) and writer s cramp impairment scale (WCIS), and will also be videotaped. The primary outcome will be based on patient reported subjective scale and the secondary outcomes will be assessed by four blinded raters of the videotapes, done both before and after treatment. Outcome measures: The primary outcome is to show additional improvement from baseline with BoNT therapy plus occupational therapy compared to BoNT alone at 20 weeks using a patient-rated subjective scale. The secondary outcomes are to show improvement in scores of WCRS, WCIS, WCDS, and writing parameters with a new handwriting analysis program. Additionally, the scores obtained from WCRS and WCIS will be compared.
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.