View clinical trials related to Dystonia.
Filter by:Cervical dystonia (CD) is the most common isolated dystonia in adults. Cervical dystonia symptoms can in most patients be managed well by botulinum toxin (BTX) injections, and supporting treatment measures. However, one-fifth to one-third of patients do not obtain sufficient relief from long-term BTX therapy, resulting in reduced quality of life. Deep brain stimulation (DBS) is a treatment method in which electrodes are surgically implanted permanently in the brain to modulate brain networks and function. In cervical dystonia, DBS of the postero-ventral part of the internal globus pallidus (GPi-DBS) has been established as an effective treatment for severe cases. However, the outcome of GPi-DBS in cervical dystonia has been reported mostly in some smaller series with up to 3 years follow-up. Thus, there is a lack of documentation of outcome of GPi-DBS in CD beyond 3 years of treatment and in larger patient materials. In this study the investigators will perform a long-term follow-up study of patients who were operated with a DBS-device targeting the GPi bilaterally, and who have been treated with chronic GPi-DBS for a minimum of 3 years. The investigators will measure the severity of symptom burden and quality of life with validated rating scales. The investigators will compare this DBS-treated cohort with an age- and gender matched group of CD patients who are receiving the standard treatment with botulinum neurotoxin (BoNT) injections and have been treated for at least 3 years as well. The investigators hypothesize that the DBS-treated group will have a significantly lower burden of symptoms at long-term follow-up than the BoNT treated group.
The diagnosis and management of movement disorders, such as Parkinson's disease (PD), parkinson-plus syndromes (PPS), dystonia, essential tremor (ET), normal pressure hydrocephalus (NPH) and others is challenging given the lack of objective diagnostic and monitoring tools with high sensitivity and specificity. A cornerstone in research of neurological disorders manifesting as MDi is the investigation of neurophysiological changes as potential biomarkers that could help in diagnosis, monitoring disease progression and response to therapies. Such a neuro-marker that would overcome the major disadvantages of clinical questionnaires and rating scales (such as the Unified Parkinson's disease rating scale -UPDRS, for PD, The Essential Tremor Rating Assessment Scale -TETRAS, for ET and others), including low test-retest repeatability and subjective judgment of different raters, would have real impact on disease diagnosis and choice of interventions and monitoring of effects of novel therapeutics, including disease modifying therapies. To address this, ElMindA has developed over the last decade a non-invasive, low-cost technology named Brain Network Activation (BNA), which is a new imaging approach that can detect changes in brain activity and functional connectivity. Results from proof-of concept studies on PD patients have demonstrated that: 1) PD patients exhibited a significant decrease in BNA scores relatively to healthy controls; 2) notable changes in functional network activity in correlation with different dopamine-agonist doses; 3) significant correlation between BNA score and the UPDRS). 4) BNA could also differentiate early PD from healthy controls
The purpose of this study is to measure the effects of non-regular temporal patterns of deep brain stimulation (DBS) on motor symptoms and neural activity in persons with Parkinson's disease (PD), essential tremor (ET), dystonia or multiple sclerosis (MS). These data will guide the design of novel stimulation patterns that may lead to more effective and reliable treatment with DBS. These data will also enable evaluation of current hypotheses on the mechanisms of action of DBS. Improving our understanding of the mechanisms of action of DBS may lead to full development of DBS as a treatment for Parkinson's disease and may lead to future applications of DBS.
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), Dystonia and Obsessive Compulsive disorder (OCD). Over 100,000 patients worldwide have now been implanted with DBS devices. Current approved methods to locate the DBS target regions in the brain use a combination of stereotactic imaging techniques and measurements of the electrical activity of brain cells. As part of the standard clinical technique, electrical data are collected from individual nerve cells. The target brain region emits unique electrical signals. At certain brain locations, during DBS surgery, additional electrical data that are generated in response to sound will be collected. Regions of the brain that have a decreased response to repeated sound (auditory gating) may be important DBS targets for improving thinking. The aims are (i) during DBS surgery, in addition to EEG, use microelectrodes in the brain to find brain regions, along the normal path to the DBS target, where auditory gating occurs and then (ii) determine if stimulation of the identified region(s) alters auditory gating measured by EEG. Also an additional aim (iii) is to measure electrical activity at the scalp with EEG to characterize auditory gating in patients before and after DBS surgery and also a healthy control population.
The purpose of this study is to detect possible changes in the electrical activity of the Basal Ganglia related to sedation during deep brain stimulation surgery.