View clinical trials related to Movement Disorders.
Filter by:''This study aims to determine the relationship between functional movement screen (FMS), core stabilization and Y balance test. The study will include evaluations on 30 handball players and 30 sedentary individuals.'' Functional movement analysis is a biomechanical screening and evaluation system to identify limitations and asymmetries in 7 basic movements. This system reveals the kinetic chain interaction between mobility and stability required for basic performance. Unlike conventional assessment methods, FHA focuses on the efficiency and quality of the movement pattern, not on the number of repetitions or weight lifted. The main aim of the study was to reveal the relationship between functional movement screen and core endurance and Y balance test evaluations in handball players with objective data. Functional movement is the general name of the activities performed by individuals for function and the movements performed by individuals for function are examined with analysis methods. In an effective analysis, if people do not have appropriate stability and mobility, it is determined from which muscle-muscle group or joint the problem originates. Analyses play a role in determining which of the stabilization, mobilization and flexibility factors are problematic at which stage of the function. In addition, these methods are effective in preventing possible injuries while helping to improve balance, strength and power characteristics of individuals. Core stabilization problems cause significant posture and stabilization problems. These problems are reflected in functional movements. Core stabilization problems are thought to have negative effects on functional movement analysis scores. Active athletes with this problem will be more affected. This study also aimed to observe the differences between athletes and sedentary individuals. Studies defined the core as the part of the body in the musculoskeletal system consisting of the proximal lower extremities, abdominal structures, hips, pelvis and spine and stated that the core muscles are composed of the trunk and pelvis muscles. It is argued that trunk and pelvis stabilization is essential for all movements of the extremities. The transversus abdominis and multifidus work in cocontraction and control excessive anterior pelvic tilt, which is known to be associated with femoral internal rotation and adduction. The musculature of the core is referred to as the muscular corset over the trunk and spine that stabilizes the body with or without limb movement. The strength and stabilization of the core affects the fitness and physical fitness of athletes. Core exercises should be included in exercise programs planned to improve athletic performance. Core endurance tests have been defined to reveal the relationship between core stabilization and performance. Lateral bridge test and trunk flexor test are the preferred core endurance tests in this study. The Y balance test is a dynamic test that requires strength, flexibility, core control and proprioception in a single-legged stance. Functional movement analysis, core stabilization tests and Y balance test are assessment scales that provide objective data on stabilization, postural alignment and spinal alignment. It is envisaged that these three assessment parameters will support each other after the study. Functional movements are widely used during both daily and sports activities. Core stabilization and dynamic balance are the factors that determine the quality of functional movements. These movements become more important for athletes as they affect their sporting success. Athletes need a good evaluation to ensure and maintain success. Since handball is defined as a sport that requires a lot of effort, the risks increase and it becomes clear that the evaluation should be done with a holistic approach.Injuries in handball develop due to multifactors.Biomechanical, kinesthetic and functional losses in players should be determined to prevent injuries.Functional movement analysis, core stabilization, Y balance test will give us detailed information about posture, limb alignment and asymmetry, spinal smoothness, dynamic balance and will give us the chance to analyze whether there is a correlation between these tests.
This study is a single blinded prospective randomized monocentric study examining the effectiveness of transcutaneous auricular vagus nerve stimulation paired with rehabilitation and low frequency/antidromic stimulation of the pelvic somatic nerves. The investigator hypothesize that treatment using transcutaneous auricular vagus nerve stimulation will improve gait recovery in spinal cord injured participants already treating by rehabilitation and pelvic nerves neuromodulation.
This research study aims to identify MRI-based brain biomarkers that predict an individual's response to Deep Brain Stimulation (DBS). In particular, this study will focus on changes in cognition associated with DBS. A total of 55 participants with Parkinson's Disease planning to undergo DBS will be recruited from MUSCs Clinical DBS Program. Participants will undergo four visits, including a 1-hour screening visit, a 1.5-hour pre-DBS MRI scanning visit, and a 3.5-hour post-DBS cognitive assessment visit. In addition control participants without Parkinson's Disease will be recruited to undergo MRI scanning and cognitive assessments.
A cross-sectional study (part 1) aims to investigate the influence of fatigue on the MI ability in PD compared to healthy controls. A randomized controlled trial (part 2) aims to compare the effect of fNIRS-based NFB-MI on balance and gait performance versus MI only in people with PD.
Mild cognitive impairment associated with movement disorders occurs in up to one third of patients in early stages of the disease, and confers an increased risk of developing dementia. Non-pharmacological interventions to improve cognition have so far been based on computer-based cognitive stimulation and rehabilitation programs. These interventions base their mechanism of action on neuroplasticity and how improvements in cognitive function will generalize to functional improvement. Despite having shown certain indicators of efficacy in previous exploratory studies and clinical trials, cognitive rehabilitation continues to show insufficient evidence and requires further study. To date, there are no previous studies using immersive virtual reality (IVR) to improve cognition. Both IVR and cognitive stimulation are based on the premise that they allow the simulation of ecological environments for rehabilitation than conventional rehabilitation, as well as being more efficient by allowing control of extraneous variables and providing safe spaces for patients. The only PD rehabilitation studies that have been conducted using IVR aimed to improve gait and balance disturbances compared to conventional physiotherapy treatment or non-immersive virtual reality (NIVR). We hypothesize that a cognitive rehabilitation program using IVR or computer-mediated cognitive stimulation could have a greater beneficial effect on the cognitive status of patients with cognitive impairment associated with movement disorders compared to other modalities such as music therapy, delaying the worsening of cognitive functions.
The purpose of this study is to validate previously developed physical function-clustered specific machine-learned accelerometer algorithms to estimate total daily energy expenditure (TDEE) in individuals with general movement and functional limitations.
The purpose of this research is to evaluate how people move about in different settings with different assistive devices or components, and to understand how people interact with different assistive technologies. Individuals that have limb weakness, limb paralysis, limb loss, and movement disorders are often provided assistive devices such as prostheses and orthoses to assist with mobility or use assistive technologies for purposes such as to regain muscle strength or retrain movements. It is important to understand the impact of these different assistive technologies on human movement for technology improvement and in preparation for commercialization. Because this research focuses on evaluating how different people move about in different settings with different assistive devices/components, there are different activities that may take place. These activities have been classified as (1) Movement Analysis in the Laboratory, (2) Movement Analysis Outside the Laboratory, (3) Usability Testing, and (4) Focus Groups. Each participant may or may not complete the same activities as the other participants. Each participant may or may not complete all of the activities. Participants may complete the activities more than once.
Background: People with cerebral palsy, spina bifida, muscular dystrophy, or spinal cord injury often have muscle weakness and problems controlling how their legs move. This can affect how they walk. The NIH has designed a robotic device (exoskeleton) that can be worn on the legs while walking. The wearable robot offers a new form of gait training. Objective: To learn whether a robotic device worn on the legs can improve walking ability in those with a gait disorder. Eligibility: People aged 3 to 17 years with a gait disorder involving the knee joint. Design: Participants will be screened. They will have a physical exam. Their walking ability will be tested. Participants will have markers taped on their body; they will walk while cameras record their movements. They will undergo other tests of their motor function and muscle strength. The study will be split into three 12-week phases. During 1 phase, participants will continue with their standard therapy. During another phase, participants will work with the exoskeleton in a lab setting. Their legs will be scanned to create an exoskeleton with a customized fit. The exoskeleton operates in different modes: in exercise mode, it applies force that makes it difficult to take steps; in assistance mode, it applies force meant to aid walking; in combination mode, it alternates between these two approaches. During the third phase, participants may take the exoskeleton home. They will walk in the device at least 1 hour per day, 5 days per week, for 12 weeks. Participants walking ability will be retested after each phase....
The purpose of this study is to evaluate whether New Touch Digital (NTD) NeuroRPM software installed on wearable devices can objectively measure and track symptoms in patients with Parkinson's disease.
The importance of physical activity for individuals with movement disorders, including Parkinson disease and Essential tremor, has been established. Barriers including patient engagement continue to limit effectiveness. Golf requires skills found challenging to individuals with movement disorders. This study seeks to assess the feasibility and effectiveness of an outpatient-based rehabilitation program incorporating golf skills and activities on functional measures and quality of life.