View clinical trials related to Fall.
Filter by:Falls can have a significant impact on the lives of adults with intellectual disabilities. The ACTION FALLS programme is a systematic falls management intervention that has been shown to be of benefit for older people however this programme in its current form needs to be adapted for use with adults with intellectual disabilities who have specific risk factors for falling and specific actions to reduce these risks. An adapted version of the programme to account for the different needs of adults with intellectual disabilities and the different services and support networks they access will be developed. A draft programme has been developed based on the views of adults with learning disabilities, carers and clinicians. This programme will now be tried out to see how easy it is to use and whether it can identify the falls risk factors relevant to adults with learning disabilities. Adults with an intellectual disability, clinicians and carers will t try out the programme and will be observed using it and will be asked to give verbal feedback on their views on how easy it is to complete and what could be improved.
This pilot clinical trial assesses the safety and feasibility of a novel fabric-type orthosis designed to mimic the knee extensor muscles and improve gait in elderly patients with mobility impairments due to conditions like sarcopenia, diabetes, or knee osteoarthritis. The study aims to test this orthosis in a real- world setting to see if it can enhance mobility and stability for elderly individuals, potentially reducing falls and improving quality of life. A total of 30 participants aged 65 and older will be recruited to use this orthosis across multiple sessions, where their gait will be analyzed under various conditions to measure the device's impact on walking speed, stability, and muscle activation.
The study assesses a machine learning model developed to predict fall risk among stroke patients using multi-sensor signals. This prospective, multicenter, open-label, sponsor-initiated confirmatory trial aims to validate the safety and efficacy of the model which utilizes electromyography (EMG) signals to categorize patients into high-risk or low-risk fall categories. The innovative approach hopes to offer a predictive tool that enhances preventative strategies in clinical settings, potentially reducing fall-related injuries in stroke survivors.
The goal of this quasi-experimental study using a pre and post test design is to learn about the effect of participating in an exercise program with hydraulic exercise equipment on fall risk in the older adult population. The main questions it aims to answer are: - Does the use of hydraulic exercise equipment decrease fall risk in older adults? - Does the use of hydraulic exercise equipment improve function in older adults? Participants will be evaluated pre and post intervention for strength, fall risk using Berg Balance Scale, Tinetti Balance and Gait Assessment, Timed Up and Go, and functional ability using the Lower Extremity Functional Scale. Participants will engage in an exercise program using 5 different pieces of hydraulic exercise equipment (Frei FACTUM® novus II line) 2x/week for for 6 weeks for 30-45 minutes each session. The equipment uses concentric movements only and works agonist and antagonist muscles with each machine (IE: push and pull, both concentric).
Objective: The aim of this study is to compare neuromuscular and aquatic Exercise programs on fall risk and physical function in geriatrics. Methods: As a result of the power analysis (G-Power), 36 participants are planned to be included in this study Block randomization will be used to divide participants into 2 groups, each with at least 18 participants: Group 1 (NE Group) and Group 2 (AE Group) (Randomizer.org). NE (Neuromuscular Exercise) group will participate in a 12-week exercise program consisting of sensorimotor system training, postural stability and control, global and local joint stabilization, balance training, muscle strength, breathing, and functional movement patterns.AE (Aqıuatic Exercise) Group will participate in an aquatic exercise program, which includes warm-up, mobility and strength, stretching, and cooling exercises in a 140 cm deep pool with a water temperature of 32 °. Data will be collected using the International Physical Activity Survey Short Form (IPAQ-SF), Montreal Cognitive Assessment Scale (MoCA), Geriatric Pain Measure, Optojump-next (Microgate, Bolzano, Italy), 6-minute Walk Test, 30-second-Sit-to-Stand Test, Four Step Square Test, Berg Balance Scale, Fear of Falling Avoidance Behavior Questionnaire. Practice Implications: This current study will contribute to the understanding of how neuromuscular exercises affect falls and physical function in geriatrics.
Walking is a complex and continuous task that entails repetitive motions of the body. Relatively high gait variability sensitively predicts falls and cognitive decline in older adults. Previous work has identified an unique brain network relationship linked to gait variability and its relevant cognitive function (i.e., sustained attention). This project aims to develop a non-invasive brain stimulation montage designed to modulate the shared brain networks dynamics and to demonstrate its effects on resting state functional connectivity, gait and cognitive performance in older adults at risk for falls.
There are many epidemiological data on the relationship between the number or nature of psychoactive medications used and the risk of falling in elderly, but very little on the relationship between the amount of psychoactive medication actually present in the blood and the severity of the fall. However, the inevitable drug-drug interactions related to polypharmacy and the pharmacokinetic modifications related to old age may lead plasma overdose situations which can potentiate the risk of falls but also aggravate these consequences. The investigators therefore propose a study with the objective of verifying whether the proportion of falls with serious traumatic consequences is more frequent in patients over 75 years old, presenting plasma overdoses of psychoactive drugs (plasma concentrations higher than the usual therapeutic concentrations) in regard to those between therapeutic ranges. The aim of this work is to verify if the falls present more severe characters when the psychoactive drug concentrations are beyond the usual therapeutic ranges.
Many people with partial damages in their spinal cord (iSCI) have physical impairments such as muscle paralysis in legs which make standing balance difficult. Poor balance control often leads to falls, injuries, and hospitalization. Therefore, improvement of standing balance is an important therapeutic goal for these individuals. Our team has shown that a therapy called visual feedback training (VFT) can improve standing balance by allowing individuals with iSCI to actively participate and follow visual feedback of their body sway on a screen like a computer game. We have also found that the application of low-energy electrical pulses to weak muscles called functional electrical stimulation (FES) during VFT can enhance the training effects. Recently, transcutaneous spinal cord stimulation (TSCS) has been discussed as a promising technique to further promote the rehabilitation effects after SCI by enhancing the connectivity between the brain and spinal cord and within the spinal pathways. However, to date, the potential of combining the two techniques (TSCS+FES) to improve the standing balance remains unknown. In this study, through the completion of a clinical trial, we will investigate the effects of an intervention that combines lumbar TSCS with FES of ankle muscles during VFT on the functional and neurophysiological outcomes in individuals living with iSCI. Participants will be randomly allocated to receive combined TSCS with FES or FES alone during VFT for 12 training sessions over 4 weeks. We expect that the new therapy would further improve balance and strengthen the neural connections between the brain and muscles. The expected changes in the neural connections will be measured by recording electrical signals from the lower limb muscles following stimulation of the motor region of the brain. Results of this study will be used for a larger-scale study in people with iSCI to improve balance and reduce falls during their daily life activities.
Background Impaired gait adaptability is one of the major causes of falls among older adults by producing inappropriate gait adjustments in cluttered environments. Training programs designed to improve gait adaptability behavior in a systemic approach may prevent falls in older adults. Recently, the technology of virtual reality has appeared as a relevant gait training tool based on its training implementation potential. The present study was designed to compare the effectiveness of a virtual reality gait training program (VR group) for improving gait adaptability behavior and thus, reducing the risk of falls relative to a conventional training program of Nordic walkway (NW group). We hypothesize that the virtual reality gait training program will lead to greater gait adaptability improvements. Methods The protocol describes a randomized controlled trial with pre-tests, post-tests, retention tests and follow-up. Forty healthy independent living community dweller participants (65-80 years) will be allocated, after a general medical examination, to the VR or the NW group for a training program of six weeks. Primary outcome related to gait adaptability capacities and acceptance of the virtual reality device will be assessed in pre- and post-intervention and one month after the completion of the training program (retention). A follow-up will be done during the 12 months after the completion of the gait training program. Discussion This study will demonstrate the relative relevance of a gait training program in virtual reality versus a conventional one for improving gait adaptability behavior in healthy older adults and thus preventing falls.
Falls are the primary cause of traumatic injury in older adults, and tripping is the leading cause of falls. A robust method for improving aging-related proprioceptive deficits is lacking, while strong evidence shows that proprioception deficits are highly associated with poor balance recovery from tripping. Previous research suggested that stochastic vibratory stimulation (SVS) can influence proprioception (i.e., muscle spindle function) among healthy controls; however, it is not clear how older adults with deficits in muscle spindle function would react to SVS. In previous work the investigators showed promising findings of standing balance and timed-up-and-go (TUG) improvements using SVS among high fall risk older adults with history of fall 15-18. They will implement SVS in the current project to improve aging-related proprioceptive deficits. The hypothesis is that SVS improves muscle spindle function and balance recovery from tripping in older adults with proprioceptive deficits.