View clinical trials related to Parkinson Disease.
Filter by:This study will investigate the impact of three common exercise modalities, cardiovascular, resistance, and multimodal (i.e., a combination of the previous two) training, on sleep quality and architecture in persons with Parkinson's disease (PD). Furthermore, the project will investigate whether the potential positive exercise-induced changes in sleep are associated with improvements in different quality of life (QoL)-related aspects. Participants will perform either cardiovascular training (CT), resistance training (RT), multimodal training (MT), or will be allocated to a control condition (i.e., waiting list - CON) for 12 weeks. Training will be performed three times/week. The assessments will be conducted at baseline, post-intervention, and follow-up (i.e. 8 weeks after the intervention) by assessors blinded to the participants' group allocation.
This is a 17-week double-blind, placebo-controlled, randomized, flexible-dosing, parallel-group, multicenter study designed to evaluate the efficacy and safety of suvecaltamide for the treatment of moderate to severe residual tremor in adult participants with Parkinson's disease (PD). The target population represents participants who have tremor that is not adequately controlled by PD medications and that interferes with their activities of daily living (ADL) and/or with their performance of tasks.
Study Rationale: No accurate tests currently exist to diagnose Parkinson's disease (PD) and the conditions which mimic it (atypical parkinsonism) at a very early stage. Similarly there are no accurate ways to track how these diseases progress in a very precise manner. Recording eye movements and pupils may be a very sensitive way of doing this and may contain important information about a patient's diagnosis and their cognitive and motor function. Hypothesis: We hypothesize that measuring eye movements and pupil changes while people watch short video clips will differentiate PD and atypical parkinsonism at an early stage. We hypothesize that eye movements and pupil changes will be able to track how a person's disease changes over time and could even predict their disease course from the start. Before we can do this, we need to be able to accurately differentiate between PD and atypical parkinsonism and see how eye movements vary among people with the same disease. Study Design: We will ask a large number of people with PD and atypical parkinsonism to watch very brief video clips while we record eye movements and pupil responses. This is like changing the television channel every few seconds and observing what happens to a person's eyes as they search the new clip. We will compare these results between different disease groups and correlate them with clinical features of PD and atypical parkinsonism. Impact on Diagnosis/Treatment of Parkinson's disease: This may have enormous impact in the assessment of people with PD. It may become an important diagnostic tool, a prognostic marker at the early stage of disease, as well as providing the ability to track disease progression in clinical trials. Next Steps for Development: Once we can demonstrate that eye tracking can differentiate these conditions, we will follow a large number of patients to see how their eye movements and pupils change over time with their disease. If this is a reliable way to track disease it could be used to measure disease progression in these conditions and response to treatment.
Previous studies showed that a dose of 8 millicuries of Altropane was appropriate for imaging patients with suspected Parkinson's disease. This study will determine if a lower dose (5 millicuries) would suffice.
Parkinson's disease (PD) occurs when an area of the brain begins to lose nerve cells that produce a chemical called dopamine. Dopamine is an important chemical, and one of its functions is that it helps to regulate body movement. The loss of these nerve cells leads to a reduction of dopamine in the brain. Medications used to treat PD temporarily replace this lost dopamine, but they do not repair the underlying disease. One of the most promising PD therapies to date has been the transplantation of dopamine producing cells into the brain. Unlike current treatments, these therapies may be able to repair the damage caused in PD. In this trial, the investigators will transplant a new stem cell therapy, called the STEM-PD product, into the area of the brain affected in people with PD. These stem cells can develop into many different cell types, including dopamine-producing nerve cells. The investigators will transplant the stem cells using a device that has been previously used for similar transplants in Lund. This is the first time that the STEM-PD product will be given to humans. The trial aims to assess whether the STEM-PD product is safe to use in people with PD. The investigators will also be looking for preliminary signs of efficacy. The trial will recruit participants with PD from the UK and Sweden. Eight participants will undergo the STEM-PD product transplant. Participants will receive a single dose of the STEM-PD product. Participants will attend for 25 visits primarily at their local recruiting hospital. For participants from the UK, some of the imaging will be performed at Invicro (London), and the surgery (including some visits before and after) and some imaging will be performed in Lund. All participants will be followed up for 36 months following surgery
To collect, preserve, and/or distribute annotated biospecimens and associated medical data to institutionally approved, investigator-directed biomedical research to discover and develop new treatments, diagnostics, and preventative methods for specific and complex conditions.
This is a Phase 1b study to determine the safety, tolerability, and immunogenicity of UB-312 in participants with multiple system atrophy (MSA), and in participants with Parkinson's disease (PD). UB-312 is a UBITh®-enhanced synthetic peptide-based vaccine and may provide an active immunotherapy option for treating synucleinopathies including the most prevalent form, PD; and the most rapidly progressive form, MSA.
Prospective observational study to qualify NM-MRI as progression marker in early Parkinson's.
Many patients have benefited from the implantation of brain stimulation electrodes for the treatment of various motor signs of Parkinson's disease in the phase of motor fluctuations. This technique has significantly improved the motor symptomatology of Parkinson's disease and the dyskinesias induced by pharmacological treatment. Technological advances in the field of deep brain stimulation (DBS) could improve the benefit of this therapeutic tool. therapeutic tool. While using directional electrodes, it remains possible to program the stimulation in conventional ring mode.
The purpose of this study is to understand the treatment approach (i.e., targeting gait or targeting the postural adjustment prior to gait) that is most effective at improving gait initiation dynamics in people with Parkinson disease. Ten adults with idiopathic Parkinson disease who self-report difficulty initiating gait will complete the study. The investigators will be using a randomized crossover design, where the participants will participate in two series of training (i.e., postural training and steady-state gait training) with a one-week washout between trainings. Investigators will evaluate the changes induced in gait initiation postural adjustment size, first step length, and first step speed from each intervention. Due to the anticipated limitation of steady-state walking to directly address postural adjustment amplitude, it is hypothesized that training for larger amplitude weight shift during gait initiation will yield improved gait initiation dynamics compared to training with large amplitude movements during steady-state walking.