Machine Learning Approach for Frailty Detection in Long-Term Care Using Accelerometer-Measured Gait and Daily Physical Activity: Model Development and Validation Study.

IF 4.8 Q1 GERIATRICS & GERONTOLOGY

JMIR Aging Pub Date : 2025-09-15 DOI:10.2196/77140

Xiaoping Zheng, Ziwei Zeng, Kimberley S van Schooten, Yijian Yang

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引用次数: 0

Abstract

Background: Frailty affects over 50% of older adults in long-term care (LTC), and early detection is critical due to its potential reversibility. Wearable sensors enable continuous monitoring of gait and physical activity, and machine learning has shown promise in detecting frailty among community-dwelling older adults. However, its applicability in LTC remains underexplored. Furthermore, dynamic gait outcomes (eg, gait stability and symmetry) may offer more sensitive frailty indicators than traditional measures like gait speed, yet their potential remains largely untapped.

Objective: This study aimed to evaluate whether frailty in LTC facilities could be effectively identified using machine learning models trained on gait and daily physical activity data derived from a single accelerometer.

Methods: This study is a cross-sectional secondary analysis of baseline data from a 2-arm cluster randomized controlled trial. Of the 164 individuals initially enrolled, 51 participants (age: mean 85.0, SD 9.0 years; female: n=24, 47.1%) met the inclusion criteria of completing all assessments required for this study and were included in the final analysis. Frailty status was assessed using the fatigue, resistance, ambulation, incontinence, loss of weight, nutritional approach, and help with dressing (FRAIL-NH) scale. Participants completed a 5-meter walking task while wearing a 3D accelerometer. Following this task, the accelerometer was used to record daily physical activity over approximately 1 week. A total of 34 dynamic and spatial-temporal gait outcomes, 3 physical activity variables, and 6 demographic characteristics were extracted. Five conventional machine learning models were trained to classify frailty status using a leave-one-out cross-validation approach. Model performance was evaluated based on accuracy and the area under the receiver operating characteristic curve. To enhance model interpretability, explainable artificial intelligence techniques were used to identify the most influential predictive outcomes.

Results: The extreme gradient boosting model demonstrated the optimal performance with an accuracy of 86.3% and an area under the curve of 0.92. Explainable artificial intelligence analysis revealed that older adults with frailty exhibited more variable, complex, and asymmetric gait patterns, which were characterized by higher stride length variability, increased sample entropy, and a higher gait symmetry score.

Conclusions: Our findings suggest that dynamic gait outcomes may serve as more sensitive indicators of frailty than spatial-temporal gait outcomes (eg, gait speed) in LTC settings, offering valuable insights for enhancing frailty detection and management.

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使用加速度计测量的步态和日常身体活动进行长期护理虚弱检测的机器学习方法：模型开发和验证研究。

背景：长期护理（LTC）中超过50%的老年人虚弱，由于其潜在的可逆性，早期发现至关重要。可穿戴传感器可以持续监测步态和身体活动，机器学习在检测社区老年人的虚弱方面显示出了希望。然而，它在LTC中的适用性仍未得到充分探索。此外，动态步态结果（例如，步态稳定性和对称性）可能比步态速度等传统测量方法提供更敏感的虚弱指标，但它们的潜力在很大程度上尚未开发。目的：本研究旨在评估是否可以使用机器学习模型有效识别LTC设施中的脆弱性，该模型训练了来自单个加速度计的步态和日常身体活动数据。方法：本研究是对一项两组随机对照试验的基线数据进行横断面二次分析。在最初纳入的164名个体中，51名参与者（年龄：平均85.0岁，SD 9.0岁；女性：n=24, 47.1%）符合完成本研究所需的所有评估的纳入标准，并被纳入最终分析。虚弱状态的评估采用疲劳、阻力、行走、大小便失禁、体重减轻、营养方法和帮助敷料（rail - nh）量表。参与者在佩戴3D加速计的情况下完成了一项5米的步行任务。在这项任务之后，加速度计被用来记录大约一周的日常身体活动。总共提取了34个动态和时空步态结果，3个身体活动变量和6个人口统计学特征。使用留一交叉验证方法训练五个传统机器学习模型对虚弱状态进行分类。根据准确度和接收机工作特性曲线下面积对模型性能进行评价。为了提高模型的可解释性，使用可解释的人工智能技术来确定最具影响力的预测结果。结果：极值梯度增强模型的准确率为86.3%，曲线下面积为0.92。可解释的人工智能分析显示，虚弱的老年人表现出更多的可变、复杂和不对称的步态模式，其特征是步幅长度变异性较大，样本熵增加，步态对称性评分较高。结论：我们的研究结果表明，在LTC环境下，动态步态结果可能比时空步态结果（如步态速度）更敏感，为加强虚弱的检测和管理提供了有价值的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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