Active clinical trials for "Parkinson Disease"

Several animal and human epidemiologic studies have provided evidence that exercise may be neuroprotective in Parkinson's disease (PD). Exercise may forestall diagnosis and, in the case of those who have already been diagnosed with PD, it may slow the observed neurodegeneration. Unfortunately, because this line of research is in early stages, there is little evidence to indicate what biological mechanisms underlie the neuroprotection that is conferred with exercise. Toward this end, it is possible that an interaction between endogenous antioxidant enzymes, inflammatory processes, and reactive oxygen species may be associated with exercise improvements in PD. One of the most common reasons for premature death in PD is falls. Several meta-analyses have concluded that exercise training programs focused on balance and/or strength training are effective at improving aspects of balance. Taken together, the current body of evidence suggests that exercise may be neuroprotective and balance/strength training may decrease the likelihood of a fall. The combination of these efficacious treatment modalities (exercise and balance/strength training) in a comprehensive treatment approach to improve PD symptoms and balance has been previously reported at relatively mild or moderate exercise intensities. Because recent research has suggested that patients with PD may benefit more from more physically intense programs, we are proposing a more aggressive approach with regard to exercise intensity and frequency in the present trial. The primary purpose of this study is to determine the feasibility and safety of a high intensity exercise approach to PD. A secondary purpose is to determine the trajectory of change in outcomes over the duration of the trial from a high intensity fall prevention program. It is hoped that a signal of efficacy will allow this trial to progress to a comparative effectiveness trial. An important innovative design element is collecting biological assays to better understand the mechanism underlying the anticipated clinical improvements. Aim 1 is to test the feasibility of a high-intensity exercise and fall prevention boot camp (HIBC) in patients with PD by analyzing adherence and whether they achieve minimum Centers for Disease Control exercise standards (150 min/wk moderate level aerobic exercise; strengthening at least two times per week) for the duration of the trial. Aim 2 is to determine if participation in an 8-week HIBC under the direction of a physical therapist is safe for individuals with PD. Secondary Aim 3 is to determine if participation in an 8-week HIBC will produce a signal of efficacy for several physical outcomes: falls per physical activity ratio, balance efficacy, motor activity, fatigue, muscle strength, bone health, cognition/mood, and quality of life. Secondary Aim 4 is to determine if participation in an 8-week HIBC will produce a signal of efficacy for biological outcomes, anti-inflammatory cytokines and anti-oxidant enzymes. An additional exploratory aim will be an analysis of BDNF val66val, val66met, met66met polymorphisms to determine if there is a differential response to exercise. This trial is innovative because it utilizes a high intensity comprehensive exercise treatment approach (aerobic exercise, strengthening, and balance training). To our knowledge, there have been no trials of individuals with PD who have participated in a trial of this intensity in a group "boot camp" setting. Another innovative design element is the use of three novel assessments: biological assays of pro- and anti-inflammatory cytokines, endogenous anti-oxidant enzymes and a novel assessment of falls (falls per physical activity ratio). Participants will be randomly assigned into either an 8-week HIBC group or an 8-week usual care control group (standard, low intensity group therapy class) under the direction of physical therapists. Each group will have 15 participants with a 1:5 patient-to-therapist ratio. The HIBC will be 1.5 hours daily, Monday through Friday. Participants will be required to attend 3 out of the 5 days. The protocol of the HIBC will include the following exercise components: A. 30 minutes of moderate-high intensity aerobic exercise; B. 15 minutes of strengthening the major muscle groups; C. 15 minutes of balance training; and, D. 15 minutes of interspersed rest and stretching. Participants will rotate through these four exercise components. Participants will have one baseline test and assessments at the 2-week, 4 week, 8-week, and 6-month points. Outcomes of the primary aims (Aim 1 and Aim 2) will be frequency counts of participation, adverse events, and compliance with exercise. The outcomes for the secondary aims will include measures of balance and falls, physical capacity, fatigue, exercise/physical activity behavior, and biological assays.

This is a single-center, unblinded trial without placebo control to evaluate the acute effects of caloric vestibular stimulation on UPDRS motor scores in Parkinson's Disease patients.

'Off periods' where people with Parkinson's disease are slow, stiff and unable to function are disabling, and a treatment which can converts people to a "on", good, able to function state would be extremely useful. We assessed safety, tolerability and efficacy of inhaled dry powder apomorphine (VR040) in a clinic-based study in this setting.

The goal of the second phase of the study is to determine if simultaneous bilateral subthalamic nucleus stimulation or simultaneous bilateral globus pallidus stimulation is more effective in reducing symptoms of Parkinson's Disease.

The purpose of this study is to determine if repetitive transcranial magnetic stimulation (rTMS), a method of noninvasive brain stimulation) is effective in the treatment of the motor (movement) and mood symptoms due to Parkinson's disease (PD).

Along with cognitive and psychobehavioural disorders, gait disorders represent a major problem in the treatment of advanced Parkinson's disease (PD). PD can be considered to be a hyperglutamatergic disease because dopaminergic depletion induces hyperactivity of the subthalamic nucleus (STN) and the internal pallidum (GPi), with glutamatergic hyperactivity of the STN's efferent pathway, i.e., the subthalamopallidal, subthalamonigral and subthalamo-entopeduncular pathways (projecting to the pedunculopontine nucleus (PPN)). Excess glutamate in the PPN has also been observed in the 6-OHDA rat model of PD. Reduction of this glutamatergic hyperactivity within the PPN via the systemic or intra-peduncular administration of glutamate antagonists improves akinesia in drug-induced murine and primate models of PD, via the NMDA and AMPA receptors. High doses of memantine (10 mg/kg) improve locomotion in reserpine- and alpha-methyl-p-tyrosine-treated rats. In humans, the PPN may play a key role in gait, posture control, axial rigidity and attention. It is also involved in the gating of sensory information involved in the startle reflex, which can be studied via prepulse inhibition (PPI) of the blink reflex. At present, two uncompetitive NMDA receptor antagonists are approved for use in humans: amantadine and memantine. Reviews of the recent literature on these drugs have identified no published studies specifically on severe gait and attention disorders in PD. Memantine is a partial blocker of open NMDA channels. The value of memantine relates to the fact that it decreases excessive glutamatergic transmission by lowering the synaptic noise due to excessive activation of NMDA receptors. In this double-blind study, the investigators shall seek to demonstrate the presence or absence of an effect of memantine on gait and attention disorders. In order to study the interaction between glutamatergic hyperactivity and the dopaminergic system, the investigators shall study the phenomena both in the absence of L-dopa and following acute administration of the latter. Twenty eight volunteer, non-demented, late-stage PD patients displaying severe gait disorders will receive memantine (20 mg/day) or placebo for 3 months. The investigators expect to see a reduction in gait and attention disorders, together with an improvement in the blink reflex with PPI under memantine. This pilot study could subsequently be turned into a double-blind, placebo-controlled multicenter study.

This is a study to compare the efficacy of IPX066 and CLE in subjects with advanced Parkinson's disease.

This Phase IIb exploratory study is designed to determine whether AFQ056 is safe and effective and whether it can increase the therapeutic window of L-dopa in patients whose control of their Parkinson's Disease symptoms is limited by the development of dyskinesia induced by use of L-dopa.

Background: In transcranial magnetic stimulation (TMS), a device creates a short-lasting magnetic field which induces an electric current in the brain leading to a change in the activity of brain cells. There are different effects on the brain with different rates of stimulation. In a previous study in people with Parkinson's disease, repetitive TMS (rTMS) given at a particular rate temporarily improved their ability to walk. A faster rate of rTMS may be more effective in treating symptoms than the rate originally used. This study will compare active rTMS to inactive (sham or Placebo) rTMS. Half of the people in this study will have active rTMS; the other half will have no brain stimulation with rTMS. Objectives: - To see if a faster rate of transcranial magnetic stimulation is a more effective treatment for the symptoms of Parkinson's disease than the slower rates that have been studied. Eligibility: Individuals between 40 and 80 years of age who have been diagnosed with mild or moderate Parkinson's disease. Participants must currently be taking Sinemet or dopamine agonists drugs (e.g., bromocriptine, cabergoline, pergolide, pramipexole, ropinirole, apomorophine, and rotigotine), and are willing to continue their same treatments for the duration of the study. Design: This study requires 11 outpatient visits to the NIH Clinical Center over 6 weeks. Participants can also be admitted and stay as an inpatient in the NIH Clinical Center for the entire study period (for the 10 visits during the first weeks and the follow-up visit a month later). Initial visit will consist of a physical examination; a test of participants' time to walk 10 meters; and questions about memory, mood, and quality of life. Participants should not take Parkinson's disease medications for 12 hours before this visit; once the examinations and tests are complete, participants will be able to take the medications. Researchers will repeat the tests 1 hour after participants take the medication. TMS sessions: 8 TMS sessions (4 sessions per week) over 2 weeks. Each stimulation session will last half an hour. Half of the participants will receive active TMS; the other half will receive sham TMS. The first 10 participants will have additional tests to study the safety of rapid TMS in patients with Parkinson's disease. A day after completing the last TMS session, participants will repeat the same tests as the first visit before and after taking their medication as in the first assessment and respond to questions about mood, memory, and quality of life. One month after completing the last TMS session, participants will repeat the same tests as the first visit before and after taking their medication.

This is a placebo-controlled double-blind crossover comparative study of KW-6500 in Parkinson's disease patients with motor response complications on levodopa therapy. The efficacy of KW-6500 is evaluated using the change of UPDRS part III score at double blind period after 12 weeks subcutaneous self-injections.