View clinical trials related to Gait Disorders, Neurologic.
Filter by:The purpose of this study was to investigate the effects of gait training with the new wearable hip assist robot developed by Samsung Advance Institute of Technology (Samsung Electronics Co, Ltd, Korea) in patients with chronic stroke.
The purpose of this study was to investigate the effects of gait training with the new wearable hip assist robot developed by Samsung Advance Institute of Technology (Samsung Electronics Co, Ltd, Korea) in elderly adults.
This study evaluates the effect of the need to void on parkinsonian gait
This study aims to look at how changes to a person's functional electrical stimulation might change how they walk. Functional electrical stimulation (FES) is commonly used to help people with foot drop from upper motor neurone conditions such as stroke or multiple sclerosis. This group of people have muscle weakness which makes it difficult to lift the foot, which causes trips and falls. FES reduces foot drop by using a portable device to apply short electrical pulses to the nerve which lifts the foot. The FES device stimulates this nerve only during the swing phase, when the foot is off the floor. Typically this is achieved by using a foot-switch, which detects when the heel leaves the floor. Stimulation begins a short interval of time after the heel leaves the floor, ramps up from zero to set stimulation for the individual, and at another period of time after the heel hits the floor, stimulation ramps down from set amount to zero. There are four time intervals described here which can be varied by the clinician on the device:- - Delay (the time between heel lift and the start of stimulation) - Ramp up (the time for stimulation to reach full strength) - Extension (the time between heel strike and the ramp down) - Ramp down (the time for stimulation to reach zero from full strength) These intervals are usually set by experienced clinicians using a qualitative assessment of the patient's walking and trial-and-error. A literature review has found no published studies which compare walking with different timing. This knowledge would be useful for clinicians, who could use this information as a starting point in finding the best timing parameters for each patient.
Hypothesis/Specific Aims: The purpose of this research study is to determine if using an exoskeleton during stair climbing training will result in an improved ability to walk and climb stairs in individuals affected by recent stroke as compared to stair climbing training without an exoskeleton.
The randomized clinical trial will aim to analyze the influence of binary and quaternary rhythm through a protocol on motor symptoms, sleep, fatigue and quality of life in individuals with Parkinson's disease. The study design with a randomized clinical trial, including individuals diagnosed with Parkinson's Disease, will be divided into two groups: 1) Control group 2) Experimental group. Cognition, balance, gait freezing, functional mobility, quality of life, sleep, daytime sleepiness and fatigue will be evaluated. Through the application of binary and quaternary rhythm protocol for a period of 12 weeks. First, the descriptive statistics (mean, standard deviation and percentage) will be used to know the data, then the normality calculation using the Kolmogorov Smirnov test will be used to choose the statistical tests. All information will be collected before and after the intervention period. For statistical analysis, use the SPSS statistical package, version 20.0. (Kolmogorov-Smirnov or Shapiro-Wilk test) for the selection of statistical tests.
This project aims to determine the effects of the HiBalance program on neuroplastic changes in people with mild to moderate Parkinson´s disease. The main hypothesis is that highly challenging exercise will lead to greater gait and balance ability, increased levels of physical activity and an improved health related quality of life. The investigators further hypothesize that neuroplasticity changes will be seen in corresponding areas of the brain, neuropsychological changes on cognitive test measures, and that exercise will inhibit the degeneration of dopaminergic neurons in the brain through the mediation of neurotrophic factors.
Parkinson disease (PD) is a progressive neurological disease that results in characteristic gait dysfunction. Gait problems include decreased velocity, decreased stride length, difficulty with initiation of gait, postural stability problems and alteration in joint kinematics.1 In this typically older patient population, these gait deviations affect their participation in household and community activities. The standard of care is currently focused on therapeutic exercise and cueing of various types (visual, auditory, verbal). Current interventions have not been demonstrated to markedly improve gait kinematics, so there is a need to identify interventions that could improve gait performance in this population. Lower extremity bracing is a common and well-established intervention for gait dysfunction with other populations, including stroke and brain injury. The braces allow for improved stability, sensory feedback, and consistent tactile cues to allow patients to have the best gait mechanics with each step. It is reasonable to hypothesize that appropriate bracing may have the potential to improve gait function and kinematics in PD since these patient often have gastroc-soleus weakness. Data from our early pilot studies indicates that bracing individuals with PD can positively impact their mobility. This includes improvements in velocity, step length, and dynamic balance. Additional data supported an upward trend in quality of life.
A novel body weight support device that uses pressurized pants may provide advantages in delivering gait therapy. The objectives of this study are to test the following hypotheses that 1) the novel device will allow for increased body weight support while improving or maintaining the same level of patient comfort; 2) the novel device will yield greater patient satisfaction with gait therapy relative to current harness systems; 3) therapists will be more satisfied with the use of the novel device relative to current harness systems; 4) the use of the novel device will require less total therapist time than a harness comparator; 5) the use of the novel device will increase therapeutic treatment time when compared with current harness systems.
People with weak balance ability or subjective feeling of dizziness and unsure gait are separated into 3 training-groups. One Group is getting no insoles, the second group is getting modern sensomotoric insoles, and the third group is getting normal standard insoles. All are passing a 6 week proprioceptive training. Main outcome measurements are posturography at baseline, 3 weeks and 6 weeks. Secondary measurements are ABC-Scale, Tinetti Gait and balance test and functional reach test at baseline and after 6 weeks.