View clinical trials related to Movement Disorders.
Filter by:When the literature is examined, it has not been found that the use of massage applications in relation to the functional level of individuals who have undergone abdominal surgery. We think that our study will be the first in this field. Therefore, this study will lay the groundwork for future studies on the subject. In the future, it is aimed to establish a standardized evaluation method to determine the functional levels of individuals who have undergone abdominal surgery and to determine the ideal duration and frequency when a decision is made to apply foot massage in the future with the data obtained as a result of this method. In this study, the effectiveness of foot massage on the functional level of individuals with high post-surgical kinesiophobia will be investigated.
The aim of this interventional, cross-sectional study is to evaluate the performance and the safety of the medical device software S360. This clinical investigation is performed in order to demonstrate the conformity of the medical device, when operating under the normal conditions of its intended use, in accordance with the General Safety and Performance Requirements pertaining to clinical evaluation of the device regarding the Medical Device Regulation (MDR) 2017/745 (EU).
There is an urgent need for the development of digital progression biomakers, which are sensitive to detect small, but potentially clinically relevant changes in the disease course. Digital biomarkers are based on (i) continuously collected real-time data, during the patient's day to day activities; and (ii) task-based assessment. In this study the investigators are interested in developing algorithms for the detection of disease progression in PSP patients in key clinical parameters: bradykinesia, gait, rising from a chair and falls, based on (i) sensor data obtained by means of passive monitoring during daily living; and (ii) sensor data collected during the Virtual Motor Exam.
The research was carried out to determine the effects of tactile stimulation, music listening and virtual reality video watched during the non-stress test on maternal anxiety level and fetal parameters.
The purpose of this protocol is to create an active natural history cohort of patients with degenerative movement disorders, tracked in a clinical setting with clinical rating scales and neuroimaging. The overarching rationale is that neurodegenerative diseases may be heterogeneous, complex disorders. A new way of performing clinical trials in these patients may be in order and this protocol aims to build a longitudinally tracked clinical trial-ready cohort of patients. The purpose of this protocol is to establish an active natural history cohort of patients with neurodegenerative movement disorders who are deeply phenotyped and "clinical trial ready" across Mass General Brigham. After a thorough clinical diagnostic evaluation (this may include clinically indicated testing, for example MRI, FDG-PET, MIBG scan, polysomnography, genetic testing, autonomic function tests, inflammatory tests, skin biopsy) the investigators aim to achieve this through: 1. Longitudinal tracking of clinical progression through use of clinical scales including at the present time: UMSARS, BARS, MoCA and UPSIT, PROM, MDS-NMS, UPDRS, and SARA 2. Longitudinal tracking of disease progression through use of neuroimaging including at the present time: TSPO-PET and 3D MRI (see section 1.3) This is a pilot study designed to track patients with neurodegenerative movement disorders across Mass General Brigham through MRI and PET imaging modalities and clinical measures. Figure 5 represents the study design in detail. In short, subjects will be asked to visit Mass General Brigham every 6-9 months over the course of 18 months for imaging and clinical evaluation.
One of the most disabling features of Parkinson's disease (PD) is represented by the gait disturbances. Some systematic reviews and meta-analysis have showed that conventional physical therapy might improve gait as well as balance, mobility and functional reach in subjects affected by PD. In addition, several studies and reviews support the effectiveness of external sensory cueing, by means of rhythmic auditory or visual cues, in improving kinematic parameters of gait (gait cadence, stride length, velocity, and postural stability) and the functional performance in people with PD, at least in the short-term. Specifically, cueing refers to the use of temporal or spatial stimuli to regulate movement and facilitate functional performance for individual with motor dysfunction. Basal ganglia act as internal triggers of neuronal activity in the supplementary motor area for well-learned, automatic movement sequences, such as locomotion. This mechanism is damaged in individuals with PD, and external cues may act as an attention resource to compensate the deficient internal rhythm due to basal ganglia dysfunction. Subjects can be coached in concentrating their attention on gait by specific self-prompting instructions or by cues stimulation or a combination of these. Movements generated by the presence of external sensory cues are prompted to use alternative (cortical, parieto-premotor) neuronal pathways which have not been damaged by neuronal degeneration of PD, bypassing the automatic basal ganglia network. Recent studies have provided preliminary evidence that visual cueing based on laser shoes and laser canes may reduce freezing, an established risk for falls, with improvement that can be observed for a variable period of time after rehabilitative intervention. In light of the evidence of effectiveness of cueing, developing wearable devices able to generate cues that match with step and that are effective, easy to use and low cost, would be challenging but very appropriate. The aim of this study was to investigate the non-inferiority of a wearable device producing visual cues (Q-Walk system, QUICKLYPRO s.r.l., Bergamo, Italy) in order to improve gait and balance PD patients, compared to a conventional training (stripes on the floor).
This is a pilot study to collect data with the Ceraxis product and standard movement disorders tests in order to prove and codify potential correlations.
Parkinson's disease (PD) is a progressive neurological disorder characterized by motor and non-motor symptoms such as rigidity, bradykinesia, resting tremor, cognitive and autonomic dysfunctions, gait and balance difficulties. The impairment of gait, balance and cognitive performances is partially responsive to dopaminergic medications. This emphasizes the importance of non-pharmacological interventions for people with PD (pwPD). Intensive multidisciplinary motor and cognitive rehabilitation has been proposed as a complementary and effective treatment for managing pwPD. Several structural and physiological mechanisms have been suggested to underpin exercise-induced neuroplastic changes in PD, such as enhanced synaptic strength and preservation of dopamine neurons. To date, studies on brain changes induced by motor and cognitive exercises in pwPD have been small-scaled and uncontrolled. Identifying accessible and measurable biomarkers for monitoring the events induced by intensive motor and cognitive rehabilitation program would help in testing the treatment effectiveness and would allow personalization of rehabilitation strategies by predicting patients' responsiveness. Based on validated clinical assessments of intensive multidisciplinary rehabilitation treatment, the project will test the ability of a new set of biomarkers to evaluate rehabilitative outcomes in a cohort of people with PD.
Background: A movement disorder is a condition that causes a person s body to move in ways that are not normal. There are different types. Some disorders cause movements people can t control, such as tics or shaking. Some cause reduced or slow movements. Movement disorders can cause disability in people. Sometimes members of the same family will have the same disorder. Researchers want to learn more about how people develop these disorders. This research could lead to better treatments. Objective: This natural history study will collect data on people with different types of movement disorders. It will also collect data on their family members. The data will support further research. Eligibility: Children and adults aged 2 years and older who have a movement disorder. Family members of people with movement disorders are also needed. Design: Participants will undergo screening. They will have a physical exam. Researchers will look at their existing medical images. Any photographs or videos of their movements will also be reviewed. Most participants will come to the NIH clinic for only 1 visit. They will answer questions about their condition. They will have normal tests used to diagnose their condition. They may have blood tests and different types of imaging scans. They may have tests to see how well their nerves function. The tests used will depend on the type of disorder they have. Family members will have some of the same tests as people with disorders. Participants will not receive any new treatments. Some participants may be asked to return for a follow-up visit. Up to 4000 people may participate.
Deep brain stimulation (DBS) has been approved for treatment of dystonia by the FDA under a humanitarian device exemption (HDE) status. DBS has been shown to be very effective in the treatment of a variety of diseases such as Parkinson's disease and essential tremor. It has been widely used for the treatment of primary and secondary dystonia as well. Surgery involves the placement of the DBS electrode in one or two of the deep nuclei constituting the basal ganglia. A subcutaneous thoracic or abdominal implantable pulse generator is placed and connected to the intracranial electrode. Pulsatile stimulation of the deep brain nuclei has been shown to result in significant improvement in many patients, including restoration of the ability to walk or make voluntary arm movements. A major difficulty with DBS is the accurate placement of the electrode. Adult patients are usually awakened during surgery and micro electrode recordings are used to determine the optimal electrode effectiveness and monitor for side effects. This requires the patient to be awake and cooperate, while on the operating table. When DBS is performed in children, such testing is often not possible because the children are scared or not cooperative when awakened during surgery, the procedure is most often done for Dystonia, which does not respond immediately, and dystonia may cause involuntary movements that could be dangerous in the operating room while the child's brain is exposed. As part of the routine clinical evaluation of target location in the operating room or Neuromodulation Unit, stimulation is performed using the deep brain or depth electrodes, typically at frequencies between 60hz and 185hz. For this research study, stimulation will occur at much lower frequencies, between 9hz and 20hz in order to be able to measure how electrical activity from the deep electrodes spreads to other electrodes or the scalp. As part of the research, peripheral nerves will also be stimulated at the wrist and knee at frequencies of 20hz to 150hz in order to measure the transmission of peripheral nerve stimulation to these areas of the brain. The investigators hope these additional studies will allow discovery for mechanisms that lead to movement disorders including dystonia, and that knowledge of these mechanisms will allow the investigators to develop new, safer, and more effective treatments in the future.