View clinical trials related to Movement Disorders.
Filter by:The aim of this study is to investigate whether a smartphone app can increase physical activity in patients with Parkinson's Disease in daily life for a long period of time (12 months).
Ischemic stroke is a major public health issue, likely to cause functional disability. It is well known that sleep has an impact on brain plasticity, and after an ischemic stroke, studies have shown subjective sleep quality alterations and sleep architecture abnormalities. Furthermore, there is no clear guideline showing the usefulness of a systematic sleep investigation following an ischemic stroke. The aim of the study is to identify retrospectively correlation between polysomnographic abnormalities (sleep apnea, periodic limb movements, disturbed sleep architecture…) and functional recovery after an ischemic stroke. The study also assesses the impact of sleep abnormalities on survival, and the risk of new cardiovascular event.
High-frequency deep brain stimulation (DBS) is an effective treatment strategy for a variety of movement disorders including Parkinson's disease, dystonia and tremor1-5, as well as for other neurological and psychiatric disorders e.g. obsessive compulsive disorder, depression, cluster headache, Tourette syndrome, epilepsy and eating disorders6-11. It is currently applied in a continuous fashion, using parameters set by the treating clinician. This approach is non-physiological, as it applies a constant, unchanging therapy to a dysfunctional neuronal system that would normally fluctuate markedly on a moment-by moment basis, depending on external stressors, cognitive load, physical activity and the timing of medication administration. Fluctuations in physical symptoms reflect fluctuations in brain activity. Tracking and responding in real-time to these would allow personalised approaches to DBS through stimulating at appropriate intensities and only when necessary, thereby improving therapeutic efficacy, preserving battery life and potentially limiting side-effects12. Critical to the development of such adaptive/closed-loop DBS technologies is the identification of robust signals on which to base the delivery of variable high-frequency deep brain stimulation. Local field potentials (LFPs), which are recordable through standard DBS electrodes, represent synchronous neuronal discharges within the basal ganglia. Different LFP signatures have been identified in different disorders, as well as in different clinical states within individual disorders. For example, low frequency LFPs in the Alpha/Theta ranges (4-12Hz) are frequently encountered in patients with Dystonia13,14, while both beta (12-30Hz) gamma (60-90Hz) band frequencies may be seen in Parkinson's disease, when the patient is OFF and dyskinetic, respectively15,16. Equally, suppression of these abnormal basal ganglia signals through medication administration or high-frequency DBS correlates with clinical improvement. As such, they represent attractive electrophysiologic biomarkers on which to base adaptive DBS approaches. Until recently, neurophysiological assessments were purely a research tool, as they could only be recorded either intra-operatively or for a short period of time post-operatively using externalised DBS electrodes. However, advances in DBS technology now allow real-time LFP recordings to be simply and seamlessly obtained from fully implanted DBS systems e.g. Medtronic Percept PC. In this study, we will evaluate a cohort of patients with movement disorders and other disorders of basal ganglia circuitry who have implanted DBS systems. Recordings of LFPs and/or non-invasive data such as EEG, limb muscle activation and movement (surface EMG and motion tracking) under various conditions (e.g. voluntary movement, ON/OFF medications, ON/OFF stimulation) will allow us to evaluate their utility as markers of underlying disease phenotype and severity and to assess their potential for use as electrophysiological biomarkers in adaptive DBS approaches. These evaluations in patients with DBS systems with and without LFP-sensing capabilities will take place during a single or multi-day evaluation (depending on patient preference and researcher availability). This study will advance not only the understanding of subcortical physiology in various disorders, but will also provide information about how neurophysiological and behavioural biomarkers can be used to inform personalised, precision closed-loop DBS approaches.
This trial aims to test the feasibility of Magnetic Seizure Therapy (MST) for Depression in patients diagnosed with Parkinson's Disease.
Parkinson's disease and essential tremor are chronic movement disorders for which there is no cure. When medication is no longer effective, deep brain stimulation (DBS) is recommended. Standard DBS is a neuromodulation method that uses a simple monophasic pulse, delivered from an electrode to stimulate neurons in a target brain area. This monophasic pulse spreads out from the electrode creating a broad, electric field that stimulates a large neural population. This can often effectively reduce motor symptoms. However, many DBS patients experience side effects - caused by stimulation of non-target neurons - and suboptimal symptom control - caused by inadequate stimulation of the correct neural target. The ability to carefully manipulate the stimulating electric field to target specific neural subpopulations could solve these problems and improve patient outcomes. The use of complex pulse shapes, specifically biphasic pulses and asymmetric pre-pulses, can control the temporal properties of the stimulation field. Evidence suggests that temporal manipulations of the stimulation field can exploit biophysical differences in neurons to target specific subpopulations. Therefore, our aim is to evaluate the effectiveness of complex pulse shapes to reduce side effects and improve symptom control in DBS movement patients.
SLC13A5 deficiency (Citrate Transporter Disorder, EIEE 25) is a rare genetic disorder with neurodevelopmental delays and seizure onset in the first few days of life. This natural history study is designed to address the lack of understanding of disease progression and genotype-phenotype correlation. Additionally it will help in identifying clinical endpoints for use in future clinical trials.
Parkinson's disease and essential tremor are chronic movement disorders for which there is no cure. When medication is no longer effective, deep brain stimulation (DBS) is recommended. Standard DBS is a neuromodulation method that uses a simple monophasic pulse, delivered from an electrode to stimulate neurons in a target brain area. This monophasic pulse spreads out from the electrode creating a broad, electric field that stimulates a large neural population. This can often effectively reduce motor symptoms. However, many DBS patients experience side effects - caused by stimulation of non-target neurons - and suboptimal symptom control - caused by inadequate stimulation of the correct neural target. The ability to carefully manipulate the stimulating electric field to target specific neural subpopulations could solve these problems and improve patient outcomes. The use of complex pulse shapes, specifically biphasic pulses and asymmetric pre-pulses, can control the temporal properties of the stimulation field. Evidence suggests that temporal manipulations of the stimulation field can exploit biophysical differences in neurons to target specific subpopulations. Therefore, our aim is to evaluate the direct neurophysiological effects of complex pulse shapes in DBS movement disorder patients. This will be achieved using a two-stage investigation: stage one will study the neural response to different pulse shapes using electroencephalography (EEG) recordings. Stage two will study the neural responses to different pulse shapes using intra-operative local field potential (LFP) recordings. This study only relates only to the collection of EEG and LFP recordings in DBS patients. The protocol does not cover any surgical procedures, which already take place as part of the patient's normal clinical care.
Periodic Limb Movements during Sleep (PLMs) are episodes of repetitive, stereotypical, hallux or foot movements. They could induce sleep disturbance, fatigue, daytime sleepiness and impaired quality of life but also increased cardiovascular risk by rising heart rate and blood pressure at night. Gold standard for PLMs diagnosis is based on electromyographic recording of tibialis anterior muscle during full night polysomnography (PSG). PLMs prevalence is higher in patients with spinal cord injury (SCI) possibly due to a loss of encephalic inhibition on a spinal motion generator. In these patients, PLMs can also be wrongly considered as spasms sometimes leading to the unjustified implantation of an intrathecal Lioresal pump. In the general population, drug treatments for PLMs, particularly dopamine agonists, limit the impact of these abnormal movements on sleep fragmentation, daytime alertness and quality of life. Underdiagnosed PLMs in SCI patients can lead to exacerbate cognitive, mood and painful disorders due to the close interaction between sleep disorders and neurocognitive, psychological and painful manifestations. PLMs appropriate diagnosis appeared mandatory in those patients but accessibility and delayed availability remain challenging. In addition, sleep laboratories are often unable to accommodate with SCI patients. In this context, actigraphy, an easy-to-use, cheaper and easily renewable diagnostic tool would be interesting. In the general population, sensitivity to diagnose PLMs was between 0.79 and 1 and specificity between 0.6 and 0.83. Due to lower limbs impairment, increased specificity is expected SCI patients (decrease voluntary activity). The new generation of actigraph (MotionWatchR) could have better characteristics thanks to the development of a specific software which integrate both lower limbs in the same analysis. As primary objective, this prospective monocentric study aims to evaluate the performances of lower limbs actigraphy for PLMs diagnosis versus gold standard.
The purpose of this research study is to see if the level of serum ferritin differs based on how often oral iron (in the form of ferrous sulfate) is given to children with restless leg syndrome/periodic limb movement disorder.
Objectives: To generate pilot data to investigate the feasibility and the potential use in clinical practice of technology based objective measures of motor performances in patients affected by different movement disorders. To correlate kinematics findings with demographic and clinical details. Trial design and methods: Participants enrolled in prof. Bhatia's movement disorders clinic, will be classifies according to the main movement disorder, specifically, tremor, parkinsonism, dystonia, chorea, ataxia. In the study visit (one day only), they will undergo a clinical evaluation using the appropriate clinical scales (respectively, Fahn-Tolosa-Marin tremor rating scale, MDS-UPDRS Part III, Toronto Western Spasmodic Torticollis Rating Scale 2, Unified Hungtington Disease Rating scale and Scale for the Assessment and Rating of Ataxia) and a kinematic evaluation, using wearables and an infra-red and LED markers system. Then the protocol is concluded and they will continue the routine clinical follow-up