整合个性化的形状预测、生物力学建模和可穿戴设备，用于跑步者的骨应力预测。

IF 12.4 1区医学 Q1 HEALTH CARE SCIENCES & SERVICES

NPJ Digital Medicine Pub Date : 2025-05-13 DOI:10.1038/s41746-025-01677-0

Liangliang Xiang,Yaodong Gu,Kaili Deng,Zixiang Gao,Vickie Shim,Alan Wang,Justin Fernandez

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引用次数: 0

摘要

跑步生物力学研究在跑步过程中所经历的机械力，以提高表现和防止受伤。这项研究提出了一种预测跑步者骨骼压力的数字双胞胎的发展。数字孪生利用基于领域自适应的长短期记忆（LSTM）算法，根据可穿戴传感器数据，动态模拟运行条件下足部骨骼的结构行为。来自50名参与者（分为后脚和非后脚者）的数据被用于创建个性化的3D足部模型和有限元模拟。两个九轴惯性传感器在运行过程中捕获三轴加速度数据。具有域自适应的LSTM神经网络在预测足部关键骨骼（特别是跖骨、跟骨和距骨）在站立中期和蹬离阶段的骨应力方面表现最佳（RMSE < 8.35 MPa）。这种非侵入性、成本效益高的方法代表了精确健康的重大进步，有助于理解和预防与跑步相关的骨折损伤。

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Integrating personalized shape prediction, biomechanical modeling, and wearables for bone stress prediction in runners.

Running biomechanics studies the mechanical forces experienced during running to improve performance and prevent injuries. This study presents the development of a digital twin for predicting bone stress in runners. The digital twin leverages a domain adaptation-based Long Short-Term Memory (LSTM) algorithm, informed by wearable sensor data, to dynamically simulate the structural behavior of foot bones under running conditions. Data from fifty participants, categorized as rearfoot and non-rearfoot strikers, were used to create personalized 3D foot models and finite element simulations. Two nine-axis inertial sensors captured three-axis acceleration data during running. The LSTM neural network with domain adaptation proved optimal for predicting bone stress in key foot bones-specifically the metatarsals, calcaneus, and talus-during the mid-stance and push-off phases (RMSE < 8.35 MPa). This non-invasive, cost-effective approach represents a significant advancement for precision health, contributing to the understanding and prevention of running-related fracture injuries.

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来源期刊

NPJ Digital Medicine Multiple-

CiteScore

25.10

自引率

3.30%

发文量

170

审稿时长

15 weeks

期刊介绍： npj Digital Medicine is an online open-access journal that focuses on publishing peer-reviewed research in the field of digital medicine. The journal covers various aspects of digital medicine, including the application and implementation of digital and mobile technologies in clinical settings, virtual healthcare, and the use of artificial intelligence and informatics. The primary goal of the journal is to support innovation and the advancement of healthcare through the integration of new digital and mobile technologies. When determining if a manuscript is suitable for publication, the journal considers four important criteria: novelty, clinical relevance, scientific rigor, and digital innovation.