Enhancing Self-Efficacy Through Robotic Safety Support in Balance-Challenging Reach Tasks: Feasibility Study in Young Adults.

Q2 Medicine

JMIR Rehabilitation and Assistive Technologies Pub Date : 2025-09-30 DOI:10.2196/81263

Daiki Shimotori, Soshi Fujisawa, Masahiro Nishimura, Tatsuya Yoshimi, Kenji Kato

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Abstract

Background: Falls and fear of falling adversely affect the quality of life and independence of older adults. Although various robotic systems have been developed for fall prevention, their psychological effects, particularly on self-efficacy, remain underexplored. A ceiling-mounted fall impact mitigation robot offers continuous protection with almost no limitations on the range of movement; however, its impact on users' psychological state and functional performance is unclear.

Objective: This study aimed to evaluate the effect of a fall impact mitigation robot on psychological reassurance and task performance during dynamic balance tasks in healthy young adults, with a focus on self-efficacy and functional reach capacity.

Methods: Twenty-four healthy adults (age: mean 28.9, SD 7.9 years) were randomly assigned to experimental (n=12) or control (n=12) groups. All participants performed a baseline functional reach test, followed by a series of progressively challenging reach tasks (starting at 98% of maximum reach and increasing by 2% until failure). The experimental group performed tasks while wearing the fall impact mitigation robot; the control group performed without it. Self-efficacy ratings (-5 to +5 scale) were recorded before each trial. Center of pressure (COP) data were continuously collected. Statistical analyses included Mann-Whitney U tests for self-efficacy, Kaplan-Meier survival analysis for task performance, and t tests for functional reach test and COP changes.

Results: During reach trials ≥102% of baseline, the experimental group (median 1.0, IQR 0.0 to 3.0) reported significantly higher self-efficacy ratings than did the control group (median 0.0, IQR -1.0 to 2.0; U=1292.5; P=.047). However, no significant differences were observed in changes in functional reach capacity (experimental: mean 104.2%, SD 3.8%; control: mean 103.6%, SD 2.5%; P=.62) or COP displacement (experimental: mean 108.9%, SD 10.4%; control: mean 114.1%, SD 9.8%; P=.23). Survival analysis revealed a nonsignificant trend toward greater task persistence in the experimental group (χ²₁=0.36, P=.55).

Conclusions: The fall impact mitigation robot significantly improved self-efficacy during challenging balance tasks, despite providing no active physical support. These findings underscore the role of psychological reassurance in modulating balance-related behavior and suggest that robotic safety systems may influence motor performance through psychological mechanisms. Integrating psychological support into robotic fall prevention strategies may enhance their effectiveness.

Trial registration: UMIN Clinical Trials Registry UMIN000049284; https://center6.umin.ac.jp/cgi-open-bin/ctr_e/ctr_view.cgi?recptno=R000056126.

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通过机器人安全支持在挑战平衡的伸手任务中提高自我效能感：在年轻人中的可行性研究。

背景：跌倒和对跌倒的恐惧会对老年人的生活质量和独立性产生不利影响。尽管各种各样的机器人系统已经被开发出来用于预防跌倒，但它们的心理影响，特别是对自我效能的影响，仍然没有得到充分的研究。一个安装在天花板上的跌落冲击缓解机器人提供持续的保护，几乎没有限制的运动范围；然而，其对用户心理状态和功能表现的影响尚不清楚。目的：本研究旨在评估跌倒缓解机器人对健康年轻人动态平衡任务中心理安慰和任务表现的影响，重点关注自我效能感和功能到达能力。方法：24名健康成人（平均28.9岁，SD 7.9岁）随机分为实验组（n=12）和对照组（n=12）。所有参与者都进行了基线功能到达测试，随后是一系列逐步具有挑战性的到达任务（从最大到达的98%开始，增加2%，直到失败）。实验组佩戴防摔机器人执行任务；对照组则不服用。每次试验前记录自我效能评分（-5至+5量表）。连续采集压力中心（COP）数据。统计分析包括自我效能的Mann-Whitney U检验，任务绩效的Kaplan-Meier生存分析，功能延伸测试和COP变化的t检验。结果：在达到基线≥102%的试验中，实验组（中位数1.0,IQR 0.0至3.0）报告的自我效能评分显著高于对照组（中位数0.0,IQR -1.0至2.0；U=1292.5； P= 0.047）。然而，两组功能伸展能力（实验：平均104.2%,SD 3.8%；对照组：平均103.6%,SD 2.5%；P= 0.62）或COP位移（实验：平均108.9%,SD 10.4%；对照组：平均114.1%,SD 9.8%；P= 0.23）的变化无显著差异。生存分析显示实验组的任务持久性有不显著的趋势（χ 2 1=0.36， P= 0.55）。结论：尽管不提供主动的身体支持，但减少跌倒冲击的机器人在挑战性平衡任务中显著提高了自我效能感。这些发现强调了心理保证在调节平衡相关行为中的作用，并表明机器人安全系统可能通过心理机制影响运动表现。将心理支持整合到机器人跌倒预防策略中可以提高其有效性。试验注册：UMIN临床试验注册中心UMIN000049284；https://center6.umin.ac.jp/cgi-open-bin/ctr_e/ctr_view.cgi?recptno=R000056126。

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