Tenan Matthew S, Tweedell Andrew J, Haynes Courtney A
United States Army Research Laboratory, Human Research and Engineering Directorate, Integrated Capability Enhancement Branch, Aberdeen Proving Ground, MD, United States of America.
PLoS One. 2017 May 10;12(5):e0177312. doi: 10.1371/journal.pone.0177312. eCollection 2017.
The timing of muscle activity is a commonly applied analytic method to understand how the nervous system controls movement. This study systematically evaluates six classes of standard and statistical algorithms to determine muscle onset in both experimental surface electromyography (EMG) and simulated EMG with a known onset time. Eighteen participants had EMG collected from the biceps brachii and vastus lateralis while performing a biceps curl or knee extension, respectively. Three established methods and three statistical methods for EMG onset were evaluated. Linear envelope, Teager-Kaiser energy operator + linear envelope and sample entropy were the established methods evaluated while general time series mean/variance, sequential and batch processing of parametric and nonparametric tools, and Bayesian changepoint analysis were the statistical techniques used. Visual EMG onset (experimental data) and objective EMG onset (simulated data) were compared with algorithmic EMG onset via root mean square error and linear regression models for stepwise elimination of inferior algorithms. The top algorithms for both data types were analyzed for their mean agreement with the gold standard onset and evaluation of 95% confidence intervals. The top algorithms were all Bayesian changepoint analysis iterations where the parameter of the prior (p0) was zero. The best performing Bayesian algorithms were p0 = 0 and a posterior probability for onset determination at 60-90%. While existing algorithms performed reasonably, the Bayesian changepoint analysis methodology provides greater reliability and accuracy when determining the singular onset of EMG activity in a time series. Further research is needed to determine if this class of algorithms perform equally well when the time series has multiple bursts of muscle activity.
肌肉活动的时间是一种常用的分析方法,用于了解神经系统如何控制运动。本研究系统地评估了六类标准和统计算法,以确定实验性表面肌电图(EMG)和已知起始时间的模拟EMG中的肌肉起始。18名参与者在分别进行肱二头肌卷曲或膝关节伸展时,从肱二头肌和股外侧肌采集了EMG。评估了三种既定的EMG起始方法和三种统计方法。评估的既定方法包括线性包络、Teager-Kaiser能量算子+线性包络和样本熵,而使用的统计技术包括一般时间序列均值/方差、参数和非参数工具的顺序和批处理,以及贝叶斯变化点分析。通过均方根误差和线性回归模型,将视觉EMG起始(实验数据)和客观EMG起始(模拟数据)与算法EMG起始进行比较,以逐步淘汰较差的算法。分析了两种数据类型的顶级算法与金标准起始的平均一致性以及95%置信区间的评估。顶级算法均为贝叶斯变化点分析迭代,其中先验参数(p0)为零。性能最佳的贝叶斯算法是p0 = 0,起始确定的后验概率为60-90%。虽然现有算法表现合理,但贝叶斯变化点分析方法在确定时间序列中EMG活动的单一起始时提供了更高的可靠性和准确性。需要进一步研究以确定当时间序列有多个肌肉活动爆发时,这类算法是否同样表现良好。
