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The purpose of this research study is to determine if intermittent visual perturbations can improve balance training. The investigators will quantify differences in body movement, muscle activity, and beam walking performance during and after practice walking on a balance beam that is 1" high. The investigators will ask the participants to come to the laboratory twice (2 sessions). The first session will not last more than 3 hours. The second session will not last more than 1 hour and will be two weeks after the first session. In total, the maximum amount of time the participant would be asked to participate is 4 hours.
The goal of this study is to learn if manipulating the brain using magnets works to treat balance impairment, a major cause of falls, in older adults with balance problems. The technique to manipulate the brain using magnets is known as transcranial magnetic stimulation or TMS. The main questions this study aims to answer are: * How does TMS change communication between brain areas? * Does TMS improve balance ability in older adults with balance problems? Researchers will compare the TMS group to a placebo group to see if manipulating the brain using magnets works to treat balance impairment. Participants will: * Receive TMS or placebo stimulation for 4 weeks. * Visit the laboratory for checkups and tests 3 times.
In this study the effects of diabetic peripheral neuropathy will be assessed on balance control, balance recovery, and muscle electrical activity in adults over 50 years. Aim 1: Determine muscle activity and balance control during a sit-to-stand in adults age above 50 with and without diabetic peripheral neuropathy. Aim 2: Assess local balance recovery and latency responses to lateral surface perturbation during quiet standing.
Age-related balance and walking issues increase fall risks, leading to injuries, higher healthcare costs, reduced quality of life, and increased morbidity/mortality rates. Preserving functional ability is a crucial public health priority, with the potential to reduce healthcare costs and enhance older adults' quality of life. Declines in balance and walking ability threaten independence. These declines are attributed to spinal network impairments and may be mitigated by targeted interventions aimed at addressing age-related spinal cord impairment to enhance functional outcomes. However, there is a lack of research into how the aging spinal cord affects balance/walking. In older adults, the spinal cord is less excitable, conducts signals more slowly, and is subject to neural noise. Intervening on age-related impairment of the spinal cord to improve balance/walking ability is a very promising but untapped area of research. A therapeutic approach that combines dynamic balance training with non-invasive electrical spinal stimulation may be effective in preserving functional abilities. This study tests whether electrical stimulation of the spinal lumbar regions is more beneficial than sham stimulation.
This study is being done to understand how reducing blood flow (BRT) during balance-challenging strengthening exercises (instability resistance training, or IRT) can help improve symptoms of Parkinson's disease.
Problems with walking and balance are common after traumatic brain injury (TBI). Walking and balance problems limit independence and increase risk for injuries due to falls. The purpose of this research study is to test the effectiveness of training that combines moving and thinking tasks, referred to as Personalized cognitive integrated sensorimotor virtual reality (VR)/augmented reality (AR) training on walking and balance ability. The study will also help to understand the changes in thinking ability and brain activity as a result of this training after a brain injury. The study will evaluate the differences between three intervention groups (n=45 each): 1) personalized cognitive integrated sensorimotor VR/AR training (CMT), 2) traditional dual-task training (CTRL), and 3) standard of care (SOC) on gait, balance, community ambulation, and cognitive functions, as well as underlying biomechanical and neurophysiological mechanisms to understand the changes due to CMT.
Stroke is a leading cause of disability in the United States, affecting approximately 795,000 people annually. The Veteran's Health Administration provides over 60,000 outpatient visits for stroke-related care annually at a cost of over $250 million. Among ambulatory people with chronic stroke (PwCS), impaired balance is a common health concern that substantially limits mobility (those with the worst balance walk the least). This project will explore adaptive strategies employed by PwCS in balance challenging environments and if a novel gait training intervention using a robotic device to amplify a person's self-generated movements can improve walking balance. The development of effective interventions to increase walking balance among PwCS will positively impact Veterans' health, quality of life, and ability to participate in walking activities.
The intervention being studied is a minimal risk perceptual learning protocol delivered in an academic laboratory setting; the goal of the intervention is to improve the perception of passive whole-body tilts and/or translations, as well as balance, by providing feedback following passive tilts or translations of the body. The protocol lasts a total of \~45 days: Day 1 includes a pre-test assessment of perception and balance, as well as 100 repetitions of training, Days 2-7 each include 400 repetitions of training, and Day 6 includes only post-test assessments of perception and balance.
A moderate traumatic brain injury (TBI) occurring in early or middle adulthood might have long-lasting effects on the brain that can accelerate the decline of physical and cognitive function in older age. The proposed study seeks to better understand the implications of aging with a TBI, in order to help Veterans maintain their health and independence. The overarching hypothesis of this new line of research is that participants who experienced a moderate TBI in early or middle adulthood (at least 15 years prior to study enrollment) will have poorer performance on balance and cognitive tests, despite self-reporting no persistent motor or cognitive impairment from the TBI. The investigators also seek to evaluate the potential for practice-based learning and improvement of complex balance tasks in this population, to gain experience for conducting future rehabilitation studies. The long term goal of this line of research is to design rehabilitative and lifestyle interventions to preserve brain health and function in Veterans who have previously experienced a TBI.
This project will determine the feasibility and efficacy of remote assessment and treatment of balance disorders in people with Parkinson's disease.