Evaluation of postural stability based on a force plate and inertial sensor during static balance measurements.

IF 3.3 4区 医学 Q1 PHYSIOLOGY
Chia-Hsuan Lee, Tien-Lung Sun
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引用次数: 42

Abstract

Background: Previous research on balance mostly focused on the assessment, training, and improvements of balance through interventions. We investigated tools commonly used to study static balance. Differences in postural stability were analyzed using multiscale entropy (MSE) and feature analysis.

Methods: A force plate and inertial sensor were used to collect acceleration and center-of-pressure (COP) nonlinear signals. MSE was also used to detect fractal correlations and assess the complexity of univariate data complexity. Fifteen healthy subjects participated in the experiments. Each stood on a force plate and wore a sensor while attempting to maintain postural stability for 30 s in four randomized experiments to evaluate their static balance via a copositive experiment with eyes open/closed and with standing on one foot or both feet. A Wilcoxon-signed rank test was used to confirm that the conditions were significant. Considering the effect of the assessment tools, the influence of the visual and lower limb systems on postural stability was assessed and the results from the inertial sensor and force plate experiments were compared.

Results: Force plate usage provided more accurate readings when completing static balance tasks based on the visual system, whereas an inertial sensor was preferred for lower-limb tasks. Further, the eyes-open-standing-on-one-foot case involved the highest complexity at the X, Y, and Z axes for acceleration and at the ML axis for COP compared with other conditions, from which the axial directions can be identified.

Conclusions: The findings suggested investigation of different evaluation tool choices that can be easily adapted to suit different needs. The results for the complexity index and traditional balance indicators were comparable in their implications on different conditions. We used MSE to determine the equipment that measures the postural stability performance. We attempted to generalize the applications of complexity index to tasks and training characteristics and explore different tools to obtain different results.

Trial registration: This study was approved by the Research Ethics Committee of National Taiwan University and classified as expedited on August 24, 2017. The committee is organized under and operates in accordance with Social and Behavioral Research Ethical Principles and Regulations of National Taiwan University and government laws and regulations.

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静态平衡测量中基于力板和惯性传感器的姿态稳定性评估。
背景:以往关于平衡的研究主要集中在评估、训练和通过干预来改善平衡。我们调查了常用的静平衡研究工具。采用多尺度熵(MSE)和特征分析方法分析不同部位的体位稳定性差异。方法:采用测力板和惯性传感器采集加速度和压力中心(COP)非线性信号。MSE还用于检测分形相关性和评估单变量数据复杂性的复杂性。15名健康受试者参加了实验。在四个随机实验中,每个人站在一个测力板上,戴上传感器,同时试图保持30秒的姿势稳定性,通过睁/闭眼睛、单脚站立或双脚站立的合成实验来评估他们的静态平衡。使用wilcoxon符号秩检验来确认条件的显著性。考虑评估工具的作用,评估了视觉系统和下肢系统对姿态稳定性的影响,并比较了惯性传感器和力板实验的结果。结果:在完成基于视觉系统的静态平衡任务时,使用测力板提供了更准确的读数,而在完成下肢任务时,惯性传感器更受欢迎。此外,与其他可以识别轴向的情况相比,睁着眼睛单脚站立的情况在加速的X、Y和Z轴以及COP的ML轴上涉及的复杂性最高。结论:研究结果建议研究不同的评估工具选择,以适应不同的需求。复杂性指数和传统平衡指标的结果在不同条件下具有可比性。我们使用MSE来确定测量姿势稳定性性能的设备。我们尝试将复杂性指数的应用推广到任务和训练特征,并探索不同的工具来获得不同的结果。试验注册:本研究已于2017年8月24日获得国立台湾大学研究伦理委员会批准,并归类为加急。本会依据国立台湾大学社会与行为研究伦理准则及规定及国家法律法规组织运作。
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来源期刊
自引率
6.50%
发文量
39
期刊介绍: Journal of Physiological Anthropology (JPA) is an open access, peer-reviewed journal that publishes research on the physiological functions of modern mankind, with an emphasis on the physical and bio-cultural effects on human adaptability to the current environment. The objective of JPA is to evaluate physiological adaptations to modern living environments, and to publish research from different scientific fields concerned with environmental impact on human life. Topic areas include, but are not limited to: environmental physiology bio-cultural environment living environment epigenetic adaptation development and growth age and sex differences nutrition and morphology physical fitness and health Journal of Physiological Anthropology is the official journal of the Japan Society of Physiological Anthropology.
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