IEEE Trans Biomed Eng. 2019 Nov;66(11):3136-3145. doi: 10.1109/TBME.2019.2900863. Epub 2019 Feb 21.
This paper describes how non-invasive wearable sensors can be used in combination with deep learning to classify artificially induced gait alterations without the requirement for a medical professional or gait analyst to be present. This approach is motivated by the goal of diagnosing gait abnormalities on a symptom-by-symptom basis, irrespective of other neuromuscular movement disorders the patients may be affected by. This could lead to improvements in treatment and offer a greater insight into movement disorders.
In-shoe pressure was measured for 12 able-bodied participants, each subject to eight artificially induced gait alterations, achieved by modifying the underside of the shoe. The data were recorded at 100 Hz over 2520 data channels and were analyzed using the deep learning architecture and the long term short term memory networks. Additionally, the rationale for the decision-making process of these networks was investigated.
Long term short term memory networks are applicable to the classification of the gait function. The classifications can be made using only 2 s of sparse data (82.0% accuracy over 96 000 instances of test data) from participants who were not a part of the training set.
This paper provides potential for the gait function to be accurately classified using non-invasive techniques, and at more regular intervals, outside of a clinical setting, without the need for healthcare professionals to be present.
本文描述了如何将非侵入性可穿戴传感器与深度学习相结合,在无需医学专业人员或步态分析师在场的情况下对人为诱导的步态改变进行分类。这种方法的目的是根据症状对步态异常进行诊断,而不考虑患者可能受到的其他神经肌肉运动障碍的影响。这可能会改善治疗效果,并更深入地了解运动障碍。
对 12 名健康参与者进行了鞋内压力测量,每位参与者都进行了 8 种人为诱导的步态改变,这些改变是通过改变鞋底来实现的。数据以 100Hz 的频率记录了 2520 个数据通道,并使用深度学习架构和长短期记忆网络进行了分析。此外,还研究了这些网络决策过程的基本原理。
长短期记忆网络适用于步态功能的分类。仅使用训练集之外的参与者的 2s 稀疏数据(96000 个测试数据实例的准确率为 82.0%)即可进行分类。
本文为使用非侵入性技术在临床环境之外更频繁地准确分类步态功能提供了潜力,且无需医疗保健专业人员在场。
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