View clinical trials related to Parkinson's Disease.
Filter by:Pain is a very common and disabling symptom in Parkinson's disease, yet it is often untreated. This study will assess the impact of home-based physical and cognitive exercise interventions to reduce pain in this disease. This approach would offer an easily implemented and affordable way to encourage and maintain use of these interventions by patients virtually indefinitely through remote access technology. The study findings may help VA clinicians provide optimal care for the many Veterans with Parkinson's disease and chronic pain.
Inability to align and refocus the eyes on the objects at different depths, i.e., vergence impairment, frequently affects the quality of life in patients with Parkinson's disease. Our study aims to understand the location-specific effects of subthalamic region deep brain stimulation on vergence by integrating the patient-specific deep brain stimulation models and high-resolution eye-tracking measures. The knowledge gained will allow us to find the most beneficial stimulation location and parameters for improving binocular coordination and vergence while preserving the ability to treat motor symptoms in Parkinson's disease.
This project will provide preliminary data on the feasibility and effects of exercise and VR on motor behavior and neuroplasticity in PD. Results from this work will provide insight into whether combination interventions utilizing AE and VR have parallel effects on cognition, gait, and neuroplasticity in PD.
This is an open-label, non-randomized, single-arm trial design to actively follow participants for 12 months. Ten participants will be enrolled to receive bilateral delivery of Peripheral Nerve Tissue (PNT) to the Substantia Nigra at the time of Deep Brain Stimulation (DBS) surgery. After 12 months, participants will be followed long term through annual visits for the rest of their lives. Participants will serve as their own donor for the tissue.
This study aims to evaluate the impact of the frequency of assessments on the variability over time, reliability, and compliance for the Parkinson's disease (PD) diary in patients with PD in whom medications do not provide adequate control of symptoms.
This research will develop novel and accessible way to deliver effective and customized rehab to those suffering from common and devastating neurodegenerative condition called Parkinson's disease. The investigators will examine the efficacy of novel rehab technique that can be monitored and modified in real-time but over virtual interface using a remotely located device in a paradigm called dynamic cycling. This technology will benefit thousands of Veterans who need customized and cost-effective rehab but cannot travel to specialized facilities due to inevitable limitations such as pandemics or because of lack of resources, social support, frailty, or home-bound status.
This study is aimed at testing the hypothesis that adaptive stimulation of the Subthalamic Nucleus (STN) drives changes in sleep episode maintenance and improves sleep quality. Investigators will directly test the efficacy of an adaptive stimulation protocol. Study subjects are adults with Parkinson's disease who experience inadequate motor symptom relief, and who have been offered implantation of a deep brain stimulator system targeting STN for the treatment of motor symptoms (standard-of-care). Investigators will implant 20 (n = 10 per clinical site) Parkinson's Disease subjects with the Medtronic RC+S System, enabling the implementation of real-time adaptive stimulation during in-home sleep. Prior to surgery, study subjects will complete clinical sleep questionnaires in an outpatient setting and wear an actigraphy watch for 3 weeks to monitor sleep architecture and sleep fragmentation. Three months after subjects have completed their standard-of-care Deep Brain Stimulation surgery and are optimized in terms of Parkinson's medication and clinical DBS stimulation parameters, we will monitor sleep for an additional 3 weeks, using in-home monitoring. During each week of the in-home monitoring period, subjects will undergo, in a randomized and double-blind fashion, one of three nocturnal stimulation algorithms: Adaptive stimulation, Open-Loop stimulation (standard clinical stimulation therapy) and No stimulation (control). During the 3 weeks of in-home sleep monitoring, we will monitor sleep architecture and sleep fragmentation using an actigraphy watch and subjects will complete a sleep questionnaire. At the end of the 3-week period of sleep-time randomized, blinded stimulation delivery, subjects will return to their standard stimulation therapy.
The aim is to compare the effect of reducing the conventional pulse width or frequency of stimulation for axial symptoms occurring after Subthalamic nucleus Deep Brain Stimulation (STN DBS) treatment. The participants will be assessed with chronic stimulation with conventional stimulation parameters, namely 60 us and 130 Hz, and after random allocation to short pulse width (30 us) or low frequency (80 Hz).
This is an imaging study designed to illuminate the function of the cholinergic system and its association with cognitive skills in people with Parkinson's disease. The hypothesis of this study is that there will be an association between cholinergic terminal density, sex hormones, and cognitive functioning. Participants will receive a PET and MRI scan along with a battery of neurocognitive tests at baseline and again at 18 months follow-up. Hormone levels will be measured at baseline.
Deep brain stimulation (DBS) is recognized as the most safe and effective neurosurgical method for the treatment of advanced Parkinson's disease. However, the mechanism of relieving motor and non-motor symptoms of Parkinson's disease has not been fully clarified, and the prognosis is significantly different. This study is based on multimodal MRI technique to clarify the mechanism of DBS in relieving motor and non-motor symptoms of Parkinson's disease, and to explore imaging indicators that can predict prognosis, so as to guide the individual and accurate treatment of Parkinson's disease (PD).