Exploration of Inertial Sensor-Derived Kinematic Predictors for Dynamic Balance Assessment in the Active Adult.

IF 1.6 Q3 SPORT SCIENCES

Open Access Journal of Sports Medicine Pub Date : 2025-07-11 eCollection Date: 2025-01-01 DOI:10.2147/OAJSM.S523553

Chairat Phuaklikhit, Vaibhav R Shah, Satoshi Muraki, Philippe C Dixon, Ping Yeap Loh

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Abstract

Purpose: The modified Star Excursion Balance Test (mSEBT) is a clinical tool for dynamic balance assessment. While researchers have examined individual joint kinematic predictors of dynamic balance performance, limited data exist on body and joint sway during the test execution. Further investigation of kinematic predictors' influence on dynamic balance is needed to improve assessment methodologies. This study aimed to examine the relationship between the center of mass and lower limb kinematics as predictors of mSEBT performance.

Patients and methods: Twenty-seven participants with no history of lower limb joint instability were recruited for this study. The inertial sensors were positioned on the non-dominant leg: trunk, thigh, shank, and foot. The participants completed the mSEBT barefoot following standardized practice trials with three test trials per direction. The reach distance and lower limb kinematic data were recorded. Spearman rank's correlation and stepwise multiple regression analyses identified key predictors of dynamic balance performance.

Results: Ankle dorsiflexion was a strong predictor of normalized reach distance in the anterior direction (r² = 0.34, p < 0.001). Body center of mass displacement was the strongest predictor of posteromedial and posterolateral reach (r² = 0.55, p < 0.001; r² = 0.57, p = < 0.001, respectively). The combined influence of the body center of mass and hip flexion accounted for 65% of the variance in the posterior reach assessments.

Conclusion: This study highlights the key biomechanical factors that influence dynamic balance, focusing on the interaction between joint mobility and segmental control. Ankle dorsiflexion is critical for anterior balance, whereas hip flexion and body center of mass displacement are essential for posterior balance.

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用于运动成人动平衡评估的惯性传感器衍生运动学预测器的探索。

目的：改良星偏移平衡试验（mSEBT）是一种临床动态平衡评估工具。虽然研究人员已经检查了动态平衡性能的单个关节运动学预测因子，但在测试执行过程中，关于身体和关节摆动的数据有限。需要进一步研究运动预测器对动平衡的影响，以改进评估方法。本研究旨在研究质量中心和下肢运动学之间的关系，作为mSEBT表现的预测指标。患者和方法：本研究招募了27名无下肢关节不稳定史的参与者。惯性传感器被放置在非优势腿上：躯干、大腿、小腿和脚。参与者赤脚完成mSEBT，遵循标准化练习试验，每个方向有三个测试试验。记录到达距离和下肢运动数据。Spearman秩相关和逐步多元回归分析确定了动态平衡性能的关键预测因子。结果：踝关节背屈是前方向归一化到达距离的有力预测因子（r²= 0.34,p < 0.001）。身体质量中心位移是后内侧和后外侧到达的最强预测因子(r²= 0.55,p < 0.001；R2 = 0.57, p = < 0.001)。身体重心和髋关节屈曲的综合影响占后伸评估方差的65%。结论：本研究强调了影响动态平衡的关键生物力学因素，重点关注关节活动和节段控制之间的相互作用。踝关节背屈对于前平衡至关重要，而髋部屈曲和身体重心位移对于后平衡至关重要。

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