View clinical trials related to Parkinson's Disease.
Filter by:The purpose of this research study is to measure the safety (side effects) of an Omega 3 Fatty acid called docosahexanoic acid (DHA) and measure the dyskinesia (involuntary movements) in Parkinson 's disease (PD).
Does dual hemispheric stimulation of the subthalamic nucleus (STN) and fornix/hypothalamus potentially improve cognitive function in patients with Parkinsons disease.
The purpose of this study is to better understand why individuals with Progressive Supranuclear Palsy (PSP) fall. Understanding the mechanism of gait and balance dysfunction in individuals with PSP may provide us with important early diagnostic tools, allowing for earlier identification of mobility problems and to better evaluate medical therapies aimed at improving motor disability. The investigators will recruit 10 PSP, 10 PD and 10 healthy controls for the study. All subjects will be asked to come to the OHSU clinic at the Center for Health and Healing for an initial screening visit. They will meet with the primary investigator to conduct a brief interview and physical examination. In addition, they will be asked to answer questions regarding current and past medical illness, how often they fall and what kinds of medications they are on. Subjects who agree to participate will come to the Oregon Clinical and Translational Research Institute (OCTRI) at OHSU for balance testing. Subjects will be asked to stand or sit on a movable platform with eyes open or closed. Prior to standing on the platform, the investigators will place 6 small sensors on body which are held in place by velcro straps (one on each wrist, ankles, chest and lower back). The platform will then be moved (tilt or slide) while subjects try to keep their balance. During all of the balance tests described above, body movements will be recorded from the sensors on the subjects' body. This data is directly recorded by a computer and analyzed to help us gain better understanding of the subjects' posture and their ability to remain up right.
The primary goal of this study is to determine the neuroprotective qualities of long-term, in home, exercise therapy program in human PD patients. It is hypothesized that an exercise intervention might delay the onset of levo-dopa therapy (i.e. evidence for neuroprotection). The first part involves a pilot-study in which the feasibility of the intervention and outcome measures will be tested.
Rasagiline has been developed for the treatment of Parkinson's Disease (PD), as monotherapy in early PD patients not treated with levodopa, and as adjunct therapy to levodopa in levodopa-treated PD patients with motor fluctuations. The rationale for conducting this study is to evaluate the efficacy, tolerability, and safety of rasagiline compared to placebo in Chinese PD patients not treated with levodopa.
The purpose of this study is to determine whether 18F-AV-133 PET scans can be used to differentiate subjects with Parkinson's Disease from other movement disorders.
The purpose of this project is to develop and evaluate Internet-based Cognitive Behavioral Therapy (ICBT) for Parkinson's Disease (PD) patients with concurrent depression or anxiety symptoms. All treatment in this project is given as an adjunct to Standard Medical Treatment (SMT). ICBT will be compared to an Internet-based active control treatment (ICONTROL) and to SMT alone. It is hypothesized that both active treatments will be superior to SMT, and that ICBT will be superior to ICONTROL, in reducing symptoms of depression and anxiety.
Parkinson's disease (PD) is a common neurodegenerative disease affecting movement. Although drug treatments for PD are available they only treat the symptoms of the disease, fail to halt neuronal loss, and are associated with long term side effects and loss of efficacy. There is a chronic need to develop neuroprotective therapies. Increased iron and oxidative stress have been heavily implicated in the neurodegenerative process in PD, hence removal of excess iron by iron chelation represents a potential drug target. Iron chelators are extensively utilised to treat peripheral iron overload disorders (e.g. thalassaemia) and recently the investigators have demonstrated iron chelators such as Deferiprone can enter the brain removing excess iron and are neuroprotective in PD animal models. Although good tolerability and efficacy to remove brain iron has also been shown in a pilot study with the iron chelators Deferiprone in young patients with Friedreich Ataxia, where iron accumulates in the dentate nucleus, no studies have been conducted in aged individuals affected by PD. Hence the aims of this study are 1) to assess whether Deferiprone is well tolerated in PD patients, 2) whether Deferiprone can remove the excess iron levels found in the brain area affected by PD, the substantia nigra, as assessed by Magnetic resonance imaging (MRI) and 3) whether Deferiprone has any direct effect on the clinical symptoms of PD. Three groups of 12 (total 36) early stage drug free PD patients will be treated with 20 or 30mg/kg/d Deferiprone or Placebo for 6 months. Over the 6 months patients will receive serial MRI scans, neurological examinations not only to assess PD symptoms but also psychological state, plus blood test to monitor for potential side effects. Positive results from this pilot will help support larger clinical trials to evaluate whether Deferiprone can slow down/halt PD.
The cause of Parkinson's disease (PD) is unknown and a reliable biomarker to identify PD patients as early as possible is urgently needed. Nerve cells near the nose and in the gut become first affected in PD and patients frequently suffer from loss of smell and constipation. The nose and gut harbor very high amounts of bacteria that influence our body functions in many ways, even in the brain. The investigators are examining a possible role of bacteria of the nose and gut in the pathogenesis of PD. This may lead to a better understanding of what PD causes and may open new possibilities for diagnosis and treatment. The investigators will recruit 100 PD patients and 100 control subjects. The investigators will characterize all subjects carefully with respect to clinical symptoms. The investigators will collect bacterial samples from the nose, mouth and stool of these subjects. Using modern genomic techniques the investigators will read out the genetic code of all bacteria contained in these samples and will be able to identify which species of bacteria are present in the samples. Using complex cluster computing the investigators will compare the pattern of bacterial species between PD patients and controls and look for specific abnormalities in PD patients. If the investigators can detect specific differences of bacterial communities between PD patients and controls this may point to a role of bacteria as a cause of PD. Since there are many ways to influence bacterial communities pharmacologically (antibiotics, probiotics) it will be possible to investigate whether these therapies could alleviate or even reverse PD symptoms. Furthermore, the investigators would be able to use these differences as a biomarker which would enable us to develop a quick screening test for bacterial samples that may reveal whether a person has PD or not. By doing this study the investigators will learn whether bacteria play a role in the development of PD and whether the investigators can use them as a biomarker or therapeutic target. So hopefully the investigators will be able in the future to better understand what causes PD, how the investigators can diagnose it as early as possible and how to cure patients from PD.
The purpose of this study is to collect kinematic motion data from subjects with movement disorders such as Parkinson's disease (PD) and essential tremor (ET) to develop and validate algorithms for quantifying motor symptoms such as tremor, bradykinesia (slowed movements), dyskinesias (sudden, involuntary movements), gait, and balance during standardized tasks and/or activities of daily living.