Active clinical trials for "Parkinson Disease"

Continuous subcutaneous apomorphine infusion (CSAI) has proven to be effective in advaced Parkinson's disease patients with motor fluctuations not controlled by oral or transdermal medication. After initiation of this therapy, most of the patients need nurse services at home for the entire duration of treatment. Some patients are reluctant about this dependence and thus may refuse or delay the initiation of CSAI. To date, there is no guideline to promote patients' autonomy in managing CSAI treatment. Thus we developed a program focusing on early autonomy during CSAI intitiation, through empowering the patient or their carer, and promoting primary and tertiary care. The hypothesis is that implementing the program will lead patients to autonomy. This will have beneficial effects on clinical and heath-related outcomes and may be cost-effective.

This project will investigate exploratory outcomes related to the effect of intranasal insulin on cognition, mood, apathy and motor performance of subjects with Parkinson's disease over a 3 week period.

Parkinson Disease (PD) patients experience a variety of motor issues such as walking difficulties, loss of balance, and freezing while walking, which impacts their quality of life. Some symptoms, like freezing of gait (FOG), do not respond to medications typically used to treat PD. Current surgical procedures used to alleviate PD symptoms also do not always improve FOG. Since many traditional therapies have failed for the treatment of FOG, researchers have proposed the use of newer treatments. Recent research in animal models and clinical human data using SCS has produced promising results, specifically showing improvement in FOG with the use of SCS in patients with PD. The purpose of this study is to evaluate the effectiveness of spinal cord stimulation (SCS) for the management of freezing of gait (FOG) that does not respond to conventional treatments in subjects with Parkinson's disease (PD). The investigators hypothesize that SCS significantly decreases FOG episodes in patients with PD. Assess the safety, tolerability and preliminary evidence of effectiveness of upper thoracic spinal cord stimulation for freezing of gait in Parkinson's (PD) patients. Explore the effects of two SCS programming paradigms on motor, nonmotor and quality of life measures in PD patients with freezing of gait.

The study was designed to test the acceptability of the Si-Robotics system in a group of 20 subjects with Parkinson's Disease at an early stage, during a rehabilitation treatment based on Irish dancing. Assessments will be performed at the baseline and at the end of the treatment.

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).

Nearly 90% of people with Parkinson's disease have speech and voice disorders that negatively impact their ability to communicate effectively in daily life. This study will test the hypothesis that a combined speech and exercise intervention will improve speech intelligibility in people with Parkinson's disease and speech impairment. This approach would offer an affordable way to continue to both instruct and encourage training by Veterans virtually indefinitely through the remote access technology. These findings may help VA clinicians provide optimal care for the many Veterans with Parkinson's disease and speech impairment.

The aim of this study is to assess the effect of 8-week physiotherapy training using immersive virtual reality (VR-training) compared to a physiotherapy training performed in a real setting (RS-training) on handwriting and touch screen technology-based activities, brain functional activity and cognition in patients with Parkinson's disease (PD). Both groups will perform upper limb exercises focused at improving movement amplitude and speed during several activities such as writing and using touch screen-technology. Participants randomized to VR-training (N=20) will perform exercises under the augmented visual feedback induced by the VR aimed at stimulating movement amplitude and speed. Participants randomized to RS-training (N=20) will perform exercises in a real setting. Before training, after training (8 weeks) and at 3-month follow-up (20 weeks), subjects with PD will undergo clinical evaluations (neurological, physiotherapy and neuropsychological) while taking their regular anti-parkinsonian drugs (on-medication state). MRI scans will be acquired at each time-point to assess brain activity reorganization during off state (MRI scans will be acquired at least 12 hours after the regular evening dopaminergic therapy administration to mitigate the pharmacological effects on neural activity). A sample of matched healthy subjects (N=15) will undergo clinical, physiotherapy, neuropsychological and MRI assessments only at study entry as a benchmark.

People with Parkinson's disease (pwPD) often present difficulty consolidating newly learned skills into long-term memory. Sleep facilitates motor memory consolidation in healthy adults, especially in combination with targeted memory reactivation (TMR). TMR works by adding associated sounds during learning that are replayed during sleep and thus reinforce the recently formed neural connections. Importantly, recent work suggested that consolidation during sleep may be preserved in pwPD, but robust findings are lacking and have not involved TMR. The objective of the present study is to address this imperative question by investigating the effect of napping on motor memory consolidation by experimentally manipulating exposure to sleep and TMR for the first time. Concretely, the investigators will first compare the effect of a 2-hour nap to that of a wake control period in pwPD and healthy age-matched controls. A validated motor sequence learning task will be used to test for behavioral markers of motor learning and polysomnography with electroencephalography (EEG) will be conducted to study the neural correlates of sleep-related motor learning effects. In a second experiment, the investigators will then test the effects of adding TMR during post-learning sleep, by comparing performance on two motor sequences of which only one is reactivated during post-learning napping using auditory TMR.

The use of simulators to retrain driving skills of patients with stroke, Parkinson's disease (PD), or multiple sclerosis (MS) is very limited because of cost, space required, and incidence of simulator sickness in high fidelity simulators. The Principal investigator recently developed a low cost low fidelity portable driving simulator (PDS). In this pilot study, the study team will (1) determine the ease of use and occurrence of simulator sickness while operating the low fidelity PDS in a clinic setting and (2) the efficacy of the low fidelity PDS to reproduce the benefits from retraining impaired driving skills of stroke survivors in a high-fidelity simulator. Participants: 30 participants, separated according to neurological condition including stroke, PD, or MS, will be randomly allocated to either the PDS or fixed-base high-fidelity simulator training. Each participant will undergo a pre-training evaluation, five hours of designated training and a post-training assessment, similar to the pre-training evaluation. Data will be analyzed according to study aims. The investigators hypothesize that the simple set up of the PDS will make it easier to use and better decrease the incidence of simulator sickness that typically leads to stopping therapy than the high-fidelity simulator. The investigators hypothesize that improvements in lane maintenance, adherence to speed limits, reaction to traffic lights, and overall reaction time after training using the PDS will not be significantly different from improvements observed after training using the high-fidelity driving simulator.

This trial aims to understand the mechanism and to test whether transcranial direct current stimulation (tDCS) combined with transcranial ultrasound (TUS) (tDCS+TUS) combined with physical therapy (PT) will induce significant therapeutic effects in postural instability in Parkinson's disease (PT) patients. The investigators designed a double-blinded, placebo controlled, randomized study to investigate the effects of 2 weeks of TDCS+TUS on postural instability in PD patients receiving PT. (Followed by biweekly sessions for 2 more weeks in Phase II)