View clinical trials related to Dystonia.
Filter by:Dystonias represent hyperkinetic movement disorders characterized by protracted muscle contractions, such as to cause torsional movements and anomalous postures in different parts of the body. Although they occur more often in a focal form (blepharospasm, oromandibular dystonia, cervical dystonia, laryngeal dystonia, attitudinal cramps of the limbs) than segmental (involvement of several contiguous muscle groups, e.g. facial muscles and neck muscles), they are nevertheless capable of significantly influencing the quality of life, with consequent social and health costs. Although described as a predominantly motor disorder, the presence of non-motor symptoms in dystonias associated with alteration of the fronto-striatal circuits is increasingly recognized. Neuroimaging studies have highlighted that the striatum and, more specifically, striatal dopamine, is involved in high cognitive processes such as attention, reward-based learning and decision making. Clinical conditions associated with cortico-striatal circuit dysfunction and abnormal meso-striatal or meso-cortical dopamine transmission also appear to influence temporal estimation, delay discounting, showing an impulsive preference for immediate rewards over delayed gratification. Based on these premises, the present project aims to evaluate the cognitive and affective aspects of dystonias, in line with neuroimaging research documenting structural and functional dysfunctions in the respective brain regions.
Transcranial Ultrasound Stimulation (TUS) is an emerging non-invasive brain stimulation technique capable of targeting both superficial and deep brain areas with high spatial resolution, down to a few cubic millimeters. In this study, the investigators aim to use TUS to non-invasively modulate the globus pallidus internus (GPi) in patients with Parkinson's disease (PD) and dystonia. These patients have previously been implanted with deep brain stimulation (DBS) leads. The investigators plan to simultaneously record local field potentials (LFPs) from the DBS leads using the Percept PC device (Medtronic Inc.) while the DBS is turned off. The study's goal is to investigate the mechanism of action of TUS and its neuromodulatory effects on LFPs recorded from the GPi. This will enable us to compare the effects of TUS with those of DBS.
People with Parkinson's disease (PD) commonly experience a range of both motor (e.g., bradykinesia, rigidity, tremor, and postural instability) and non-motor (e.g., fatigue, psychiatric and behavioural disturbances, autonomic dysfunction, cognitive impairment, sleep dysfunction and olfactory loss) features. Currently, it is challenging to alleviate these symptoms with first-line treatment, the medications such as levodopa. The CUE1 is a non-invasive device, which is approved for sale in the UK market as a Class I low risk device. It is worn on the sternum or other part of the body such as the forearm and attaches to the skin via an adhesive patch which has been dermatologically tested and approved. The CUE1 delivers pulsing cueing and vibrotactile stimulation to help improve symptoms in people with PD and it has shown to be effective in doing so in previous small case studies. This 9-week feasibility study aims to investigate the feasibility, safety, tolerability and effect of using the CUE1 as an intervention to improve motor and non-motor symptoms in people with PD and related movement disorders. People with clinical diagnosis of idiopathic PD and related disorders including those with progressive supranuclear palsy, multiple system atrophy, corticobasal degeneration, and vascular Parkinsonism as well as atypical dystonias and tremor disorders aged over 18 years old who have the capacity to provide a written consent form to take part in the study, will receive as intervention to wear the CUE1 device at home, on daily basis while carrying out their activities of daily living. Participants will also have to attend four face-to-face appointments of approximately half a day, at weeks -0, -3, -6 and -9 of the study to discuss how they are getting on with using the CUE1 and complete questionnaires on their symptoms, walking, balance, and movement tests as well as a participant's clinical diary.
To assess the safety and tolerability of single and multiple doses of MTR-601 in normal healthy volunteers under fed and fasted conditions. To evaluate the plasma and urine pharmacokinetics (PK) of MTR-601. To evaluate the pharmacodynamic (PD) effects of MTR-601 on muscle strength and muscle accumulation of MTR-601 by muscle biopsy and other potential mechanistic, predictive and PD markers of MTR-601.
The general aim of the study is to provide evidence for usability and feasibility of applying vibro-tactile stimulation (VTS) at home as a non-invasive form of neuromodulation to improve speech in people with spasmodic dysphonia (SD). This work addresses a clinical need to develop alternative or auxiliary treatments for a rare voice disorder with very limited treatment options. Successful completion of the proposed work will be an important step in advancing laryngeal VTS as a therapeutic intervention for improving voice symptoms in SD.
Generalized dystonia is treated with pallidotomy. This is based on observational data which is significantly limited by publication bias and there are no RCTs. The case reports focus on successful outcomes and case series have an inherent selection bias. Bilateral pallidotomy has been used in our institute in a series of patients with generalized and segmental dystonia and have been seen to show good efficacy. However, the existing literature suggests that it is also associated with dysphagia and dysarthria in some cases and thus simultaneous bilateral pallidotomy is not preferred in several centres. However, our center routinely performs simultaneous bilateral pallidotomy. The response rates and compliations of the procedure have not been systematically studied in RCT and we need to generate data on the efficacy and safety of Pallidotomy on generalized and segmental dystonia. This randomized controlled trial will fill the void in knowledge in this field.
The primary objective of the proposed study is to evaluate the safety of ExAblate Transcranial MRgFUS as a tool for creating bilateral or unilateral lesions in the globus pallidus (GPi) in patients with treatment-refractory secondary dystonia due to dyskinetic cerebral palsy
This study aims to investigate the impact of accelerated transcranial magnetic stimulation (TMS) on brain function and behavior in patients with focal hand dystonia. Previous research demonstrated that individualized TMS improved dystonic behavior after one session. Building on this, the current study administers four TMS sessions in a day, with assessments conducted on the same day, two weeks, and twelve weeks after each session. The research involves 10 in-person visits and focuses on functional MRI brain scans and writing behavior analysis. The potential risk of seizures from TMS is mitigated through careful screening, adhering to safety guidelines. The study's main benefit is enhancing dystonic behavior and deepening the understanding of brain changes caused by TMS in focal hand dystonia, paving the way for further advancements in clinical therapy for this condition.
Transcranial Ultrasound Stimulation (TUS) is an emerging non-invasive brain stimulation(NIBS) technique that can be used on both superficial and deep brain targets with a high spatial resolution as small as a few cubic millimeters. Neural correlates of TUS have yet been elucidated. To date, no intracranial recordings (i.e., local field potential [LFP]) have been captured during or after TUS in patients with movement disorders. In this study, we are aiming to profile basal ganglia LFP activity during and after TUS by using a DBS system that is capable of recording LFP. This can shed light on mechanisms of TUS, as well as allow identification of a neurophysiological biomarker that can be used to tune the TUS sonication parameters for future clinical trials.
Sleep-wake disturbances are a major factor associated with reduced quality of life of individuals with Parkinson's disease (PD), a progressive neurological disorder affecting millions of people in the U.S and worldwide. The brain mechanisms underlying these sleep disorders, and the effects of therapeutic interventions such as deep brain stimulation on sleep-related neuronal activity and sleep behavior, are not well understood. Results from this study will provide a better understanding of the brain circuitry involved in disordered sleep in PD and inform the development of targeted therapeutic interventions to treat sleep disorders in people with neurodegenerative disease.