Active clinical trials for "Parkinson Disease"

The main objective of this study is to evaluate the effect of Azilect® on sleep disturbances in Parkinson's Disease patients, after 2 months of treatment.

Patients with Parkinson's disease (PD) frequently experience upper gastrointestinal disorders. During the disease, weight loss is often noticed. Recently, many studies have demonstrated that STN-DBS improved extrapyramidal symptoms. Interestingly, PD patients gain weight after STN-DBS, at least in part due to a decrease in resting energy expenditure. Purpose: To evaluate benefits of STN-DBS on upper gastrointestinal symptoms and motility. Patients et method: PD patients waiting for STN-DBS, will be assessed in a preoperative time (2 times at, at least, 3 month intervals, to evaluate the natural history of the disease on upper gastrointestinal symptoms and motility) and in a postoperative time, after 6 months of chronic STN-DBS. Each assessment will include : 1/ questionnaires about frequency and severity of upper gastrointestinal symptoms; 2/ a nutritional assessment (body mass index, dietary assessment); 3/ the gastric emptying measurement with the 13C-octanoic acid breath test; 4/ the colorectal transit time measurement with radio-opaque markers 5/ an indirect calorimetry to estimate resting energy expenditure; 6/ and plasmatic leptin and ghrelin concentrations, hormones involved in the homeostatic regulation of appetite. Perspectives: This physiopathological study should allow us to understand the mechanisms of the effects of STN-DBS on upper gastrointestinal symptoms and weight regulation in PD patients.

This research study will evaluate functions of memory, thinking, behavior, and daily life activities and how these relate to the measurement of certain chemicals (acetylcholine and dopamine) in the brain using an imaging procedure called positron emission tomography (PET). You may know that in Alzheimer's dementia (dementia is a disease where persons become forgetful and confused), a reduction in the amount of acetylcholine, a "neurotransmitter" substance (a chemical messenger that nerve cells need to communicate with each other), may be responsible for some of the memory and behavioral changes. At the present time, the investigators have no clear information on the levels of acetylcholine in the brain of patients with Parkinson's disease who also have memory or behavioral changes.

We will evaluate the effect of deep brain stimulation on the depression and quality of life in Parkinson's disease. We aim to compare depression pre-operatively and post-operatively in Parkinson's patients with deep brain stimulation to Parkinson's patients evaluated and approved for deep brain stimulation but who did not complete surgery. We will also compare quality of life measures between patients with and without deep brain stimulation.

The purpose of this study is to assess the effects of unilateral deep brain stimulation on upper and lower extremity motor function in advanced Parkinson's disease patients. It is hypothesized the unilateral stimulation will lead to improvements in bilateral motor functioning.

Imaging studies of the brain have revealed the different areas involved in the processes of learning and reasoning. However, the specific role these regions play in these processes, or if stimulating these areas can improve these processes is unknown. Researchers would like to use repetitive transcranial stimulation (rTMS) to better understand the roles of individual brain regions on the processes of learning and reasoning. Repetitive transcranial magnetic stimulation (rTMS) involves the placement of a cooled electromagnet with a figure-eight coil on the patient's scalp, and rapidly turning on and off the magnetic flux. This permits non-invasive, relatively localized stimulation of the surface of the brain (cerebral cortex). The effect of magnetic stimulation varies, depending upon the location, intensity and frequency of the magnetic pulses. The purpose of this study is to use rTMS to help determine the roles of different brain regions in the development of implicit learning of motor sequences and analogic reasoning. In addition, researchers hope to evaluate if stimulation of these regions speeds up the process of learning or analogic reasoning.

This study has two purposes: 1) to understand the effect of a decline of dopamine in the brain during normal aging and in patients with Parkinson's disease, and 2) to investigate how medicines used to treat Parkinson's disease improve movement performance in patients. Patients with Parkinson's disease have difficulty performing precise finger movements, mainly because of a dramatic decrease of a substance called dopamine in parts of the brain. Medicines such as levodopa, which help restore dopamine levels, can greatly improve function; however, little is known about how these drugs work. In normal aging, dopamine decreases slightly in certain parts of the brain, but the importance of this decline is poorly understood. This study may provide new information about Parkinson's disease and normal aging that might lead to better treatment strategies. Patients with mild to moderate Parkinson's disease and healthy volunteers 21 years of age and older may be eligible for this study. All participants must be right-handed. All candidates will be screened with a medical history and physical and neurological examinations, including memory tests and mood examination. Brain function will be studied using functional magnetic resonance imaging (fMRI) study and positron emission tomography (PET). Participants may be asked to stop using medications that can affect the central nervous system, such as sleeping pills or drugs for depression or anxiety, for 1 week before each study visit. Patients with Parkinson's disease may also be asked to stop using antiparkinsonian medications at least 12 hours before each visit. In addition, all participants will be asked to abstain from alcoholic beverages at least 24 hours before the fMRI and PET scans, and from nicotine and caffeine for at least 12 hours before the scans. Participants will have fMRI, which uses a strong magnetic field and radio waves to create images of the brain. The subject lies on a table in a tunnel-like cylinder (the scanner) for 1 to 2 hours, lying still for 5 to 15 minutes at a time. He or she can communicate with the technician or researcher at all times during the test through an intercom system. Scans will be done while the subject is at rest and while he or she is performing finger movements. The movements involve pushing five buttons on a box-each button every 3 seconds on average in a specific order. Patients with Parkinson's disease will be studied off- and then on- medications that restore the levels of levodopa in the brain. Some participants may be asked to undergo a PET scan on a separate visit. A PET scanner is a doughnut-shaped machine similar in appearance to a CT (computed tomography) scanner. PET scans detect radioactivity used to provide information on brain activity. Before the test begins, subjects are given a dose of carbidopa-a medicine that increases the amount of levodopa in the brain. A catheter (thin, plastic tube) is then inserted into an arm or wrist vein, and a radioactive form of levodopa called 18Fluorodopa is injected through the catheter. A moldable plastic mask with large openings for eyes, nose, and mouth is placed on the face to help keep the head still during scanning. The total scan time is 2 hours or less.

Body motion evaluation (BME) by markerless systems is increasingly being considered as an alternative to traditional marker-based technology because they are faster, simpler, and less expensive. They are increasingly used in clinical settings in patients with movement disorders, however, the wide variety of systems available make results conflicting. The objective of this study was to determine if a markerless 3D motion capture system is a useful instrument to objectively differentiate between Parkinons's Disease (PD) patients with Deep Brain Stimulation (DBS) in On and Off state and controls; and its correlation with the evaluation by means of Unified Parkinson's Disease Rating Scale (UPDRS). Six PD patients who underwent DBS bilaterally in the subthalamic nucleus were evaluated using BME and UPDRS-III with DBS turned On and Off. BME of 16 different movements in six controls paired by age and sex was compared with PD patients with DBS in On and Off states. Kinematic data obtained with this markerless system could contribute to the discrimination between PD patients and healthy controls. This emerging technology may help to clinically evaluate PD patients more objectively.

This is a study of subjects with the St. Jude Medical Infinity deep brain stimulation (DBS) system who undergo an MRI imaging procedure. Enrollment may occur before DBS implant, or when an MRI scan is planned in a subject with an existing implant. There will be a follow-up visit one month after the MRI procedure to document any adverse events and verify device functionality.

This is a Phase IV, prospective, observational, post-marketing study designed to obtain additional data on the effect of XADAGO on motor and non-motor symptoms in Parkinson's Disease patients newly prescribed XADAGO.