View clinical trials related to Gait Disorders, Neurologic.
Filter by:Stroke,one of the leading cause of death, is caused by ischemia or hemorrhage. It results in neurological deficits such as hemiplegia. Hemiplegia show disability characterized loss of motor, sensory and cognitive function. Reduced postural control and balance stability results gait disturbances such as asymmetric weight bearing, risk of falling and imbalances. It also shows increased energy expenditure, decreased independence on quality of life and limited mobility. Physical therapy can be effective method for solving these problems. Hippotherapy, also known as horseback riding therapy, is a form of physical therapy strategy that uses equine movement. The concept of hippotherapy is to use a horse as a therapeutic tool, and it is based on similarities in gait between the human and horse. The horse's gait provides patients having motor disabilities with rhythmic and repetitive movements similar to human walking, thereby giving them training opportunities to improve posture, balance, and strength. Even though it has many effect on solving these problems, hippotherapy centers are not enough. Due to climate and environmental situations, hippotherapy devices were improved and had similar effects on patients with stroke. In literature, these device mostly used on cerebral palsy, but investigator wants to use hippotherapy device on patient with Hemiplegia. For these reasons, the effects of exercises by mechanical hippotherapy device on postural control and balance will be investigated.
The study is designed to evaluate the use of electromagnetic tracking in transversal plane femoral derotation osteotomies. The goal is to raise the precision of the surgical procedure in order to improve the outcome in short- and long term. All patients are examined with an instrumented 3D gait analysis pre- and one year postoperatively. The electromagnetic tracking system is evaluated against a base line CT or MRI scan serving as reference standard pre- and postoperatively.
Every year 1.7 million people sustain a traumatic brain injury (TBI) in the United States and of these, 84 % are considered mild TBI (mTBI). mTBI is common both in civilian and military populations and can be debilitating if symptoms do not resolve after injury. Balance problems are one of the most common complaints after sustaining a mTBI and often prevent individuals from returning to their previous quality of life. However, the investigators currently lack clear guidelines on when to initiate physical therapy rehabilitation and it is unclear if early physical therapy is beneficial. The investigators believe that the underlying problem of imbalance results from damage to parts of the brain responsible for interpreting sensory information for balance control. The investigators hypothesize that retraining the brain early, as opposed to months after injury, to correctly interpret sensory information will improve recovery. The investigators also believe this retraining is limited when rehabilitation exercises are performed incorrectly, and that performance feedback from wearable sensors, can improve balance rehabilitation. There are three objectives of this study: 1) to determine how the timing of rehabilitation affects outcomes after mTBI; 2) to determine if home monitoring of balance exercises using wearable sensors improves outcomes; and 3) to develop a novel feedback system using wearable sensors to provide the physical therapist information, in real-time during training, about quality of head and trunk movements during prescribed exercises. The findings from this research could be very readily adopted into military protocols for post-mTBI care and have the potential to produce better balance rehabilitation and quality of life for mTBI patients and their families.
The study was aimed to investigate the role of cognition n in FoG.
Cerebellar vermis anomalies are present in schizophrenic individuals. This condition leads to postural balance problems. Foot and ankle complex have a special role for maintaining balance. However, there is no study about this topic in schizophrenic individuals.
The long-term study goal is to develop a more engaging, motivating gait biofeedback methodologies specifically designed for post-stroke gait training. The current project aims to address fundamental questions regarding the optimal methodology to deliver AGRF biofeedback during gait, and the feasibility and preliminary efficacy of AGRF progression protocols for improved gait patterns and gait function. The study objectives are to (1) evaluate the immediate effects of biofeedback training methodology on gait biomechanics; and (2) evaluate the feasibility and short-term effects on gait performance of a real-time biofeedback protocol incorporating progression criteria (similar to those employed during clinical rehabilitative training).
The aim of this study is to investigate the most effective stimulation site in transcranial direct current stimulation for gait recovery after stroke. All subjects will go through four conditions of transcranial direct current stimulation with for 30 minutes. Four conditions are 1) bihemispheric stimulation - anodal stimulation on both ipsilesional and contralesional leg area of primary motor cortex and supplementary motor area. 2) ipsilesional stimulation - anodal stimulation on ipsilesional leg area of primary motor cortex and supplementary motor area. 3) contralesional stimulation - anodal stimulation on contralesional leg area of primary motor cortex and supplementary motor area. 4) sham stimulation. Subjects will walk on treadmill for 10 minutes during transcranial direct current stimulation. Motor evoked potential and functional evaluations will be done before and after stimulation to measure the changes.
The cerebellum is known to be strongly implicated in the functional reorganization of motor networks in stroke patients, especially for gait an balance functions. Repetitive transcranial magnetic stimulation of the cerebellum can be used to enhance these adaptive processes in stroke recovery. In this randomized, double blind, sham-controlled trial we aim to investigate the efficacy and safety of cerebellar intermittent theta burst stimulation coupled with intensive physical therapy in promoting gait recovery in hemiparetic patients due to recent stroke in the territory of the contralateral middle cerebral artery
The aim of this study is to investigate the effects of the implantable drop foot stimulator "ActiGait" (Ottobock Health Care, Duderstadt, Germany) on gait in hemiparetic patients. While several studies investigated the effects of implanted systems on walking speed and gait endurance, only a few studies have focused on the system's impact on kinematics and long-term outcomes. Therefore, our aim was to further investigate the effects of the implanted system ActiGait on gait kinematics and spatiotemporal parameters with a 1-year follow-up period.
Gait and mobility are among the functions frequently affected in Multiple Sclerosis (MS) and have a negative impact on quality of life. Strength losses in lower limb muscles, ataxia, sensory problems and fatigue are the most important reasons of walking problems in patients with MS. In addition to loss of strength and tonus problems, especially biomechanical disorders can be seen on foot and this problem affects gatin and balance negatively. The stabilizing muscles, defined as the "core" region and enveloping the body like a corset, are active in the context of postural preparation prior to lower extremity movements and stabilize for the limb movements to be performed. The aim of this study was to investigate the effects of spinal stabilization exercises on walking performance, fatigue, plantar pressure distribution, balance, muscle strength and quality of life in patients with Multiple Sclerosis.