View clinical trials related to Vestibular Disorder.
Filter by:The goal of this comparative pilot study is to provide evidence that Praxis, a portable testbed with low-cost wearable sensors and a mixed reality environment, can deliver effective multisensory rehabilitation exercises with military face-validity in a military service member (SM) population after mild Traumatic Brain Injury (mTBI). The main questions this comparative pilot study aims to answer are: - Can the Praxis testbed provide feasible/acceptable 4-week multisensory rehabilitation for SMs with post-acute mTBI? - Can Praxis detect and influence measurable changes in readiness performance during mTBI recovery? Fifteen SMs with post-acute mTBI from the Center for the Intrepid's Special Operations Performance and Recovery (SPaR) Program will participate in the multisensory vestibular rehabilitation regimen. These SMs will go through 4 weeks of multisensory vestibular rehabilitation including: - gaze stabilization - dual-task balance training - spatial navigation - agility training Data from another fifteen SMs, who will not go through the multisensory rehabilitation regimen and will receive supervised cardiovascular exercise, will be used as the control group. Researchers will compare the Praxis and Control group to determine if the Praxis group shows improvement over the control group with respect to the military-relevant behavioral performance outcomes and patient-reported symptom scores after the end of the rehabilitation.
Severe-to-profound hearing loss can have a major impact on patients´ lives leading to social isolation and decreased quality of life. Most commonly the hearing loss is caused by damage to the inner ear or cochlear nerve. Since the vestibular system which is central for our balance is located in the inner ear it can be suspected that patients with severe-to-profound hearing loss also might have an impaired vestibular function. This impairment may lead to a feeling of dizziness or vertigo. This study aims to investigate if patients with severe-to-profound hearing loss also have impaired vestibular function. The vestibular function will be measured with caloric irrigation, video head impulse test and vestibular evoked myogenic potential.
This project will investigate the role of noise in the vestibular system, and in particular its effects on the variability (precision) of vestibular-mediated behaviors. The investigators will study vestibular precision in normal subjects and patients with peripheral vestibular damage, and will investigate its potential plasticity. The goals are to develop a better understanding of the role noise plays in the vestibular system in normal and pathologic populations, and to determine if the brain can learn to improve signal recognition within its inherently noisy neural environment, which would result in improved behavioral precision.
Multiple sensory cues are typically generated by discrete events, and while they do not reach the cerebrum simultaneously, the brain can bind them temporally if they are interpreted as corresponding to a single event. The temporal binding of vestibular and non-vestibular sensory cues is poorly understood and has not been studied in detail, despite the fact that the vestibular system operates in an inherently multimodal environment. In this study, the researchers are investigating the physiology and pathophysiology of vestibular temporal binding by studying normal subjects, patients with peripheral and central vestibular dysfunction, and patients with vestibular and cochlear signals provided by prosthetic implants in the inner ear.