View clinical trials related to Dystonic Disorders.
Filter by:This research involves retrospective and prospective studies for clinical validation of a DystoniaNet deep learning platform for the diagnosis of isolated dystonia.
The researchers will examine functional neural correlates that differentiate between laryngeal dystonia and voice tremor and contribute to disorder-specific pathophysiology using a cross-disciplinary approach of multimodal brain imaging.
The researchers will systematically evaluate current and novel clinical voice assessment tools and measures to elucidate distinct clinical phenotypes of those with laryngeal dystonia and voice tremor.
The goals of this project are 1) to determine the incidence of neurological voice disorders in patients with dystonia and essential tremor undergoing deep brain stimulation (DBS), 2) investigate the neuroimaging and intracranial neurophysiology correlates of voice dysfunction in these subjects, and subsequently 3) determine the effects of DBS on voice function.
The primary objective of this exploratory study is to prospectively evaluate the feasibility of image-guided programming of pallidal deep brain stimulation (DBS) for dystonia. The dystonias are a heterogeneous group of movement disorders that share the core clinical feature of abnormal involuntary muscle contractions in common. Pallidal DBS is an established therapy for severe cases with an average improvement in dystonia severity of 50-60%. However, outcomes are variable and difficult to predict, and clinical trials report up to 25% of Nonresponders. Variability in electrode placement and inappropriate stimulation settings may account for much of this variability in outcome. In addition, improvement in dystonia is delayed, often days to weeks after a change in DBS therapy, complicating programming. Our group recently developed a computer model to predict optimal individualized stimulation settings in patients based on the outcome of a large cohort of of chronically treated patients. In-silico testing showed a 16.3% better mean group improvement with computer-assisted programming compared with physician-assisted programming and a dramatic reduction in non-responders (from 25% to 5%). In this prospective study, the computer model will be compared in a randomized, controlled, and double blinded setting against best clinical DBS programming. The primary outcome will be a responder analysis in which dystonia severity will be compared between conventional clinical and model-based programming will be compared.
Laryngeal dystonia (LD) causes excessive vocal fold abduction (opening) or adduction (closing) leading to decreased voice quality, job prospects, self-worth and quality of life. Individuals with LD often experience episodic breathy voice, decreased ability to sustain vocal fold vibration, frequent pitch breaks and in some cases, vocal tremor. While neuroimaging investigations have uncovered both cortical organization and regional connectivity differences in structures in parietal, primary somatosensory and premotor cortices of those with LD, there remains a lack of understanding regarding how the brains of those with LD function to produce phonation and how these might differ from those without LD. Intervention options for people with LD are limited to general voice therapy techniques and Botulinum Toxin (Botox) injections to the posterior cricoarytenoid (PCA) and/or TA (thyroarytenoid) often bilaterally, to alleviate muscle spasms in the vocal folds. However, the effects of injections are short-lived, uncomfortable, and variable. To address this gap, the aim of this study is to investigate the effectiveness of repetitive transcranial magnetic stimulation (rTMS), a non-invasive neuromodulation technique, in assessing cortical excitability and inhibition of laryngeal musculature. Previous work conducted by the investigator has demonstrated decreased intracortical inhibition in those with adductor laryngeal dystonia (AdLD) compared to healthy controls. The investigators anticipate similar findings in individuals with with other forms of LD, where decreased cortical inhibition will likely be noted in the laryngeal motor cortex. Further, following low frequency (inhibitory) rTMS to the laryngeal motor brain area, it is anticipated that there will be a decrease in overactivation of the TA muscle. To test this hypothesis, a proof-of-concept, randomized study to down-regulate cortical motor signal to laryngeal muscles will be compared to those receiving an equal dose of sham rTMS. Previous research conducted by the investigator found that a single session of the proposed therapy produced positive phonatory changes in individuals with AdLD and justifies exploration in LD.
This study is designed to assess the safety and tolerability of dipraglurant in patients with blepharospasm (BSP) (randomized 1:1:1 to receive dipraglurant 50 mg, 100 mg or placebo) and explore the efficacy of 50 mg and 100 mg immediate release tablets (versus placebo) on the severity and frequency of BSP signs and symptoms using objective measures, clinical ratings and patient reported outcomes.
To study whether Heart Rate Variability (HRV) biofeedback training can improve abnormal head posture and painful symptomatology in patients with "cervical dystonia" not selected for DBS after extensive screening in a specialized unit but diagnosed " dysfunctional ". Patients of the respiratory coherence group will receive HRV biofeedback training for 12 sessions during a 6 months-period. The hypothesis is that this kind of physiological noninvasive therapy increasing coherence respiratory, will reduce pain and patient's complain about their psychogenic abnormal head posture. Improvement of anxiety, depression and quality of life are expected.
In this scheme, TMS treatment of Primary dystonia is planned by precise magnetic resonance positioning.
Dystonia is a group of movement disorders characterized by twisting, repetitive movements, or abnormal postures caused by involuntary muscle contractions and is characterized by a young age of onset and a high disability rate. Early intervention can reduce disability incidence, improve the patient's quality of life, and reduce the burden on families and society. Multiple international guidelines on dystonia have found deep brain stimulation (DBS) to be a safe and effective treatment for refractory dystonia. The globus pallidal internus (GPi) is the mostly widely used target for dystonia. However, there are limitations on the GPi DBS treatment, including slow onset of beneficial effects, poor improvement of axis symptoms, and potential stimulation-related side effects. Previous studies have described the highly successful use of subthalamic nucleus deep brain stimulation (STN DBS) in patients with refractory dystonia, suggesting that STN DBS is an effective and persisting alternative to pallidal deep brain stimulation. However, all STN DBS treated cases have been analyzed in open-label uncontrolled cohort studies, leading to limited data with a high level of evidence on the STN DBS in dystonia. Further, the investigators hypothesized STN has potentially more effectiveness when compared with GPi, and may be more power-saving and quick-acting. In this study, the investigators will organize a prospective randomized, double-blind, parallel-group, multicenter study comparing active versus sham stimulation in isolated segmental or generalized dystonia to evaluate the effectiveness and safety of STN DBS by measuring the impact on motor status, mental status, quality of life, the rate of response of the patients (the number of patients with ≥30% improvement in the movement score on the Burke-Fahn-Marsden Dystonia Rating Scale) and the rate of adverse events during the trial.