用惯性传感器和机器学习检测腰背部物理治疗练习:算法开发和验证。

Q2 Medicine
Abdalrahman Alfakir, Colin Arrowsmith, David Burns, Helen Razmjou, Michael Hardisty, Cari Whyne
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引用次数: 1

摘要

背景:物理治疗是成功保守治疗腰痛的关键因素。定量测量物理治疗参与的金标准对于理解物理治疗依从性在管理腰痛恢复中的作用至关重要。目的:本研究旨在开发和评估一种可穿戴惯性传感器系统,以客观地检测由多平面运动和坐姿组成的无监督下腰痛训练的性能。方法:在机器学习框架内使用定量分类设计来检测健康参与者队列的运动表现和姿势。在参与者身上放置一组8个惯性传感器,并在他们进行7种McKenzie下背部运动和3种坐姿时获取数据。从数据中提取工程时间序列特征,采用6倍交叉验证方法对9个模型进行训练,从中选择最佳的2个模型进行进一步研究。此外,直接在时间序列数据上训练卷积神经网络。进行特征重要性分析以确定对模型贡献最大的传感器位置和通道。最后,将传感器位置和通道子集包含在超参数网格搜索中,以确定最佳传感器配置和最佳运动和姿势分类算法。最终模型使用F1评分在10倍交叉验证方法中进行评估。结果:总共有19名没有腰痛史的健康成年人完成了至少一个完整的锻炼和姿势。随机森林和XGBoost(极端梯度增强)模型在初始的9个工程特征模型中表现最好。最佳硬件配置被确定为3个传感器设置-下背部,左大腿和右脚踝传感器,具有加速度,陀螺仪和磁力计通道。XGBoost模型获得了最高的运动(F1得分:平均0.94,SD 0.03)和姿势(F1得分:平均0.90,SD 0.11)分类得分。卷积神经网络在传感器位置相同的情况下,仅使用加速度计和陀螺仪通道进行运动分类(F1得分:平均0.94,SD 0.02),仅使用加速度计通道进行姿势分类(F1得分:平均0.88,SD 0.07),得到了类似的结果。结论:本研究展示了3传感器下体可穿戴解决方案(如智能裤子)的潜力,可以识别多平面运动和适当的坐姿,适用于腰痛的治疗。这项技术有可能通过促进定量反馈、早期问题诊断和可能的远程监测来提高LBP康复的有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Detection of Low Back Physiotherapy Exercises With Inertial Sensors and Machine Learning: Algorithm Development and Validation.

Detection of Low Back Physiotherapy Exercises With Inertial Sensors and Machine Learning: Algorithm Development and Validation.

Detection of Low Back Physiotherapy Exercises With Inertial Sensors and Machine Learning: Algorithm Development and Validation.

Detection of Low Back Physiotherapy Exercises With Inertial Sensors and Machine Learning: Algorithm Development and Validation.

Background: Physiotherapy is a critical element in the successful conservative management of low back pain (LBP). A gold standard for quantitatively measuring physiotherapy participation is crucial to understanding physiotherapy adherence in managing recovery from LBP.

Objective: This study aimed to develop and evaluate a system with wearable inertial sensors to objectively detect the performance of unsupervised exercises for LBP comprising movement in multiple planes and sitting postures.

Methods: A quantitative classification design was used within a machine learning framework to detect exercise performance and posture in a cohort of healthy participants. A set of 8 inertial sensors were placed on the participants, and data were acquired as they performed 7 McKenzie low back exercises and 3 sitting posture positions. Engineered time series features were extracted from the data and used to train 9 models by using a 6-fold cross-validation approach, from which the best 2 models were selected for further study. In addition, a convolutional neural network was trained directly on the time series data. A feature importance analysis was performed to identify sensor locations and channels that contributed the most to the models. Finally, a subset of sensor locations and channels was included in a hyperparameter grid search to identify the optimal sensor configuration and best performing algorithms for exercise and posture classification. The final models were evaluated using the F1 score in a 10-fold cross-validation approach.

Results: In total, 19 healthy adults with no history of LBP each completed at least one full session of exercises and postures. Random forest and XGBoost (extreme gradient boosting) models performed the best out of the initial set of 9 engineered feature models. The optimal hardware configuration was identified as a 3-sensor setup-lower back, left thigh, and right ankle sensors with acceleration, gyroscope, and magnetometer channels. The XGBoost model achieved the highest exercise (F1 score: mean 0.94, SD 0.03) and posture (F1 score: mean 0.90, SD 0.11) classification scores. The convolutional neural network achieved similar results with the same sensor locations, using only the accelerometer and gyroscope channels for exercise classification (F1 score: mean 0.94, SD 0.02) and the accelerometer channel alone for posture classification (F1 score: mean 0.88, SD 0.07).

Conclusions: This study demonstrates the potential of a 3-sensor lower body wearable solution (eg, smart pants) that can identify exercises in multiple planes and proper sitting postures, which is suitable for the treatment of LBP. This technology has the potential to improve the effectiveness of LBP rehabilitation by facilitating quantitative feedback, early problem diagnosis, and possible remote monitoring.

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来源期刊
CiteScore
4.20
自引率
0.00%
发文量
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审稿时长
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