View clinical trials related to Parkinson Disease.
Filter by:The investigators intend to compare the effects on the resolution of visual and auditory sensory cues on the resolution of freezing of gait in patients with idiopathic Parkinson's disease.
The RESTART/RICOMINCIARE study is a pilot single-center, not controlled prospective, pre-post intervention study aimed at verifying feasibility and safety of a device-supported home rehabilitation for people suffering from mild to moderate disabilities due to respiratory or neurological conditions, related to Covid-19 or frailty condition (i.e. Parkinson Disease).
The aim of the project is to develop the first alpha-synuclein (a-syn)-specific PET tracer. The research phase will exploit ACI's proprietary MorphomerTM library and extensively optimized screening workflow. Promising PET-tracer candidates will be tested for their ability in detecting a-syn pathology in patients with a range of Parkinsonian conditions with different a-syn levels and distributions, comprising hereditary forms of PD and other synucleinopathies.
Introduction: Parkinson's disease (PD) is responsible for several changes in the body, such as balance, gastrointestinal and autonomic disorders and are associated with impairments in the clinical prognosis of these individuals. In this sense, therapies capable of minimizing this impact are extremely important. Osteopathy has become an alternative treatment for individuals with neurological disorders and has been shown to be effective in treating various conditions, including PD. Objective: a) to evaluate the acute effect of visceral manipulation directed to the intestines and visceral plexuses in the autonomic nervous system of PD patients; b) identify the effect of this approach, after four visits, on balance, plantar pressure, gastrointestinal disorders and autonomic nervous system in this population. Materials and Methods: For this randomized clinical trial, 28 adults diagnosed with PD will be recruited. Subjects will be randomized to protocols in two groups: intervention protocol and placebo protocol, where both will consist of 4 visits twice a week. The intervention protocol will consist of osteopathic manipulative techniques and the sham protocol will consist of simulation of therapy, where the therapist will place his hands in the same regions of the intervention protocol, with superficial contact and without therapeutic intention in each region. The outcome measures of the study will consist of Berg balance assessment and plantar pressure, Rome survey on gastrointestinal disorders, and assessment of autonomic modulation by means of heart rate variability analysis. Volunteers and evaluators will be blind to the protocol and not informed of their order. Only the person responsible for the intervention will not be blind to the protocol. Data will be analyzed according to normality (Shapiro-Wilk test), and comparisons of outcomes between the moments (pre and post) will be performed using the T-student test for paired data or Wilcoxon, as normal and for comparisons between protocols. placebo and intervention, Student's T-test for unpaired data or Mann-Whitney test according to normality will be applied. The adopted statistical significance will be fixed at 5%.
To compare the effects of exer-gaming with conventional physiotherapy on balance and gait in Parkinson's patients
The AETIONOMY project will generate a refined taxonomy and testable mechanisms underlying the derived stratification of patients.
The purpose of this study is to test the feasibility of a novel motor-cognitive home training intervention using eHealth technology among people with Parkinson's Disease
The aim of this pilot/feasibility study is to test if delivering rhythmic vibration cues to the lower legs, specifically in response to gait defects (rather than continuously), can improve walking quality and overcome gait freezing in Parkinson's disease. During the study, people with Parkinson's disease that suffer from regular (daily) gait freezing will undertake a series of walking/activity circuits, receiving continuous cueing, responsive cueing (delivered in response to gait freezing), no cueing and no device. Vibration cueing is provided by a non-invasive wearable device prototyped at the University of Oxford, worn on the lower legs during 3 circuits. A series of walking metrics will be analysed.
Demonstrate safety and efficacy of TAPS delivered by a Cala device as a treatment for action tremor in subjects with Parkinson's disease hand tremor
Treatment of sleep disturbances is mainly attempted through drug administration. However, certain drugs are associated with unwanted side effects or residual effects upon awakening (e.g. sleepiness, ataxia) which can increase the risks of falls and fractures. In addition, there can be systemic consequences of long-term use. An alternative method of manipulating sleep is by stimulating the brain to influence the electroencephalogram (EEG). To date, there have been mixed results from stimulating superficial areas of the brain and, as far as we know, there has been no systematic attempt to influence deep brain activity. Many patients suffering from movement disorders, such as Parkinson's Disease (PD) and Multiple Systems Atrophy (MSA), also have disrupted sleep. Currently, at stages where drug treatment no longer offers adequate control of their motor symptoms, these patients are implanted with a deep brain stimulation system. This involves depth electrodes which deliver constant pulse stimulation to the targeted area. A similar system is used in patients with severe epilepsy, as well as some patients with chronic pain. The aim of this feasibility study is to investigate whether we can improve sleep quality in patients with deep brain stimulators by delivering targeted stimulation patterns during specific stages of sleep. We will only use stimulation frequencies that have been proven to be safe for patients and frequently used for clinical treatment of their disorder. We will examine the structure and quality of sleep as well as how alert patients are when they wake up, while also monitoring physiological markers such as heart rate and blood pressure. Upon awakening, we will ask the patients to provide their subjective opinion of their sleep and complete some simple tests to see how alert they are compared to baseline condition which would be either stimulation at the standard clinical setting or no stimulation. We hope that our study will open new ways of optimising sleep without the use of drugs, in patients who are implanted with depth electrodes. We also believe that our findings will broaden the understanding of how the activity of deep brain areas influences sleep and alertness.