Clinical Research Directory

Local Field Potentials in Dystonia

The goal of this clinical trial is to learn whether local field potential (LFP) signals recorded from the globus pallidus interna (GPi) using the Medtronic Percept™ deep brain stimulation (DBS) device can help optimize DBS programming for people with dystonia. The study will also explore whether LFP patterns can serve as a biomarker of disease activity and predict treatment response. The main questions it aims to answer are: Do LFP peaks in the alpha-theta range reliably correlate with dystonia severity and clinical characteristics? Can LFP-based programming achieve similar or better clinical outcomes compared to traditional programming methods? How do LFP profiles change with stimulation and other treatments such as botulinum toxin or oral medications? Researchers will compare two programming approaches: Traditional programming based on clinical assessment and imaging. LFP-guided programming based on the site and characteristics of LFP peaks Participants will: Undergo DBS surgery for dystonia as part of standard clinical care. Attend regular follow-up visits for DBS programming and outcome assessments. Complete clinical rating scales for dystonia severity, quality of life, cognition, and mood. Take part in neurophysiological assessments, including surface EMG, EEG, and reaction time tasks. Have LFP recordings collected using the Medtronic Percept™ device during clinic visits and, where possible, at home using device sensing features. This study will help determine whether LFP analysis can shorten the time to optimal DBS settings and improve outcomes for people with dystonia.

Dystonia Genotype-Phenotype Correlation

The purpose of this study is to (1) investigate the effect of known dystonia-causing mutations on brain structure and function, to (2) identify structural brain changes that differ between clinical phenotypes of dystonia, and to (3) collect DNA, detailed family history, and clinical phenotypes from patients with idiopathic dystonia with the goal of identifying new dystonia-related genes. Investigators will be recruiting both healthy control subjects and subjects with any form of dystonia. For this study there will be a maximum of two study visit involving a clinical assessment, collection of medical and family history, task training session, an MRI using the learned tasks, and finally a blood draw for genetic analysis. In total, these visits will take 3-5 hours. If the dystonia subjects receive botulinum toxin injections for treatment, the participants and their matched controls will be asked to come for a second visit.

Enhancing Sensorimotor Processing in Children With Dystonia

Dystonia is a severely disabling movement disorder with no cure, in which people suffer painful muscle spasms causing twisting movements and abnormal postures. There are many causes, including genetic conditions and brain injury. The most common cause in childhood is dystonic cerebral palsy (CP) which often affects the whole body. The underlying mechanisms are unknown, but there is growing evidence to implicate abnormal brain processing by the brain of incoming "sensory" information (e.g., signals to the brain from our senses of touch and body position): the distorted perception of these signals disrupts the way the brain produces instructions for planning and performing movements. The investigator's previous studies have shown that the way the brain processes sensory information related to movement is abnormal in children with dystonia and dystonic CP, by using methods that record the EEG (electroencephalogram - brain wave signals) and/or EMG (electromyogram - electrical signal from muscles). A specific brain rhythm (called mu) typically shows well-defined changes in response to movement, and reflects processing of sensory information. The investigator's work shows these rhythm changes are abnormal in children with dystonia/dystonic CP. This study will explore if these findings can improve treatment. In particular the study team will investigate whether children and young people with dystonia/dystonic CP can enhance these mu rhythm responses during a movement task by using feedback of their brain rhythms displayed as a cartoon/game on a computer. The investigators will also assess whether enhanced mu activity is associated with improved movement control. This would open future possibilities to use such devices for therapy/rehabilitation. Children and young people with dystonia/dystonic CP aged 5-25 years will be recruited, along with age-matched controls. Studies will last 2-3 hours with time for breaks and will be conducted at Evelina London Children's Hospital and Barts Health Trust, with the option for home visits if preferable for families.