Between-Day Reliability of Kinematic Variables Using Markerless Motion Capture for Single-Leg Squat and Single-Leg Landing Tasks.

IF 2.1 Q3 SPORT SCIENCES

International Journal of Sports Physical Therapy Pub Date : 2025-08-01 eCollection Date: 2025-01-01 DOI:10.26603/001c.141870

Matias Yoma, Lee Herrington, Chelsea Starbuck, Luis Llurda, Richard Jones

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Abstract

Background: Markerless motion capture has the potential to repeatedly collect biomechanical data during activities associated with injuries. Few studies have assessed the reliability of this technology during single-leg tasks.

Purpose: The primary aim was to examine the between-day reliability of trunk and lower limb kinematics during single-leg squat and single-leg landing tasks using markerless motion capture. The secondary aim was to examine the between-day reliability of the same protocol using marker-based motion capture.

Design: Reliability.

Methods: Nineteen recreational athletes performed all tasks in two sessions, one week apart. Joint angles of trunk, hip, knee, and ankle were processed using Theia3D. A separate study (10 different participants) evaluated the reliability of marker-based motion capture. In both technologies, full curve analysis was examined using root mean square difference (RMSD) and discrete point analysis (initial contact and peak knee flexion) using intraclass correlation coefficient (ICC) and standard error of measurement (SEM). Statistical parametric mapping (SPM) was also used for full curve analysis in markerless motion capture.

Results: For full curve analysis, markerless motion capture demonstrated low mean RMSD for all joints and planes in both SLS (3.6˚±1.3˚) and landing tasks (forward=3.2˚±1.3˚; medial=3.4˚±1.7˚). SPM showed statistical difference for bilateral hip flexion (full curve) and unilateral hip adduction, rotation, and knee flexion during a percentage of landing tasks. For discrete point analysis, ICC mean indicated moderate to good reliability (SLS= 0.77; forward landing= 0.83; medial landing= 0.80) with low mean SEM values (SLS=3.1°±1.3˚; forward landing=2.3˚±0.9°; medial landing=2.3˚±0.8˚). Marker-based motion capture showed slightly higher mean RMSD (SLS=4.2˚±1.8˚; forward landing=3.5˚±1.0˚; medial landing=3.3˚±0.9) and SEM values (SLS=4.1˚±2.2˚; forward landing=2.7˚±1.2°; medial landing=2.8˚±1.2˚). ICC mean showed good relative reliability (SLS=0.90; forward landing=0.88; medial landing=0.88). Hip flexion presented values >5° across tasks and technologies (RMSD and SEM= 5° to 8°).

Conclusions: Markerless motion capture using Theia3D can reliably measure single-leg tasks with measurement errors comparable to marker-based motion capture. The low measurement error provides confidence for the regular monitoring of athletes during single-leg tasks.

Level of evidence: 3.

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基于无标记动作捕捉的单腿深蹲和单腿落地运动变量的日间可靠性研究。

背景：无标记运动捕捉具有在与损伤相关的活动中反复收集生物力学数据的潜力。很少有研究评估这种技术在单腿任务中的可靠性。目的：主要目的是使用无标记动作捕捉技术来检验单腿深蹲和单腿着地任务中躯干和下肢运动学的日间可靠性。第二个目的是使用基于标记的动作捕捉来检查同一协议的日间可靠性。设计:可靠性。方法：19名休闲运动员分两期完成所有任务，间隔一周。使用thei3d对躯干、髋关节、膝关节和踝关节角度进行处理。另一项单独的研究（10名不同的参与者）评估了基于标记的动作捕捉的可靠性。在这两种技术中，全曲线分析采用均方根差（RMSD）和离散点分析（初始接触和膝关节屈曲峰值）采用类内相关系数（ICC）和测量标准误差（SEM）进行检验。统计参数映射（SPM）也被用于无标记运动捕捉的全曲线分析。结果：在全曲线分析中，无标记动作捕捉在SLS（3.6˚±1.3˚）和着陆任务(前向=3.2˚±1.3˚；内侧= 3.4˚±1.7˚)。在着陆任务的百分比中，SPM在双侧髋关节屈曲（全曲线）和单侧髋关节内收、旋转和膝关节屈曲方面显示有统计学差异。对于离散点分析，ICC平均值显示中等至良好的信度(SLS= 0.77；前降= 0.83；内侧着陆= 0.80)，平均SEM值低(SLS=3.1°±1.3˚；向前着陆= 2.3˚±0.9°;内侧着陆= 2.3˚±0.8˚)。基于标记的动作捕捉的平均RMSD略高（SLS=4.2˚±1.8˚）；向前着陆= 3.5˚±1.0˚;内侧着陆=3.3˚±0.9)和SEM值(SLS=4.1˚±2.2˚；向前着陆= 2.7˚±1.2°;内侧着陆= 2.8˚±1.2˚)。ICC平均值具有良好的相对信度(SLS=0.90；向前着陆= 0.88;内侧着陆= 0.88)。不同任务和技术的髋关节屈曲值为bbb50°（RMSD和SEM= 5°至8°）。结论：使用Theia3D无标记动作捕捉可以可靠地测量单腿任务，测量误差与基于标记的动作捕捉相当。较低的测量误差为运动员在单腿任务中的常规监测提供了信心。证据等级：3。

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