Statistical Learning Methods to Identify Nonwear Periods From Accelerometer Data

Sahej D. Randhawa, Manoj Sharma, M. Fiterau, J. Banda, F. Haydel, K. Kapphahn, Donna Matheson, Hyatt Moore, Robyn L. Ball, C. Kushida, S. Delp, Dennis P Wall, Thomas Robinson, M. Desai
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Abstract

Background: Accelerometers are used to objectively measure movement in free-living individuals. Distinguishing nonwear from sleep and sedentary behavior is important to derive accurate measures of physical activity, sedentary behavior, and sleep. We applied statistical learning approaches to examine their promise in detecting nonwear time and compared the results with commonly used wear time (WT) algorithms. Methods: Fifteen children, aged 4–17, wore an ActiGraph wGT3X-BT monitor on their hip during overnight polysomnography. We applied Hidden Markov Models (HMM) and Gaussian Mixture Models (GMM) to classify states of nonwear and wear in triaxial acceleration data. Performance of methods was compared with WT algorithms across two conditions with differing amounts of consecutive nonwear. Clinical scoring of polysomnography served as the gold standard. Results: When the length of nonwear was less than or equal to WT algorithms’ predefined thresholds for consecutive nonwear time, GMM methods yielded improved classification error, specificity, positive predictive value, and negative predictive value over commonly used algorithms. HMM was superior to one algorithm for sensitivity and negative predictive value. When the length of nonwear was longer, results were mixed, with the commonly used algorithms performing better on some parameters but GMM with the greatest specificity. However, all approached the upper limits of performance for almost all metrics. Conclusions: GMM and HMM demonstrated robust, consistently strong performance across multiple conditions, surpassing or remaining competitive with commonly used WT algorithms which had marked inaccuracy when nonwear time periods were shorter. Of the two statistical learning algorithms, GMM was superior to HMM.
从加速度计数据中识别非磨损期的统计学习方法
背景:加速度计用于客观地测量自由生活个体的运动。将非磨损与睡眠和久坐行为区分开来,对于获得身体活动、久坐行为和睡眠的准确测量是很重要的。我们应用统计学习方法来检验它们在检测非磨损时间方面的前景,并将结果与常用的磨损时间(WT)算法进行比较。方法:15名年龄4-17岁的儿童在臀部佩戴ActiGraph wGT3X-BT监护仪进行夜间多导睡眠描记。应用隐马尔可夫模型(HMM)和高斯混合模型(GMM)对三轴加速度数据中的非磨损和磨损状态进行分类。在连续非磨损量不同的两种情况下,将方法的性能与WT算法进行了比较。多导睡眠图临床评分为金标准。结果:当非磨损长度小于或等于WT算法预定义的连续非磨损时间阈值时,GMM方法的分类误差、特异性、阳性预测值和阴性预测值均优于常用算法。HMM在灵敏度和负预测值方面优于一种算法。当非磨损长度较长时,结果好坏参半,常用算法在某些参数上表现较好,但GMM具有最大的特异性。然而,他们都接近了几乎所有指标的性能上限。结论:GMM和HMM在多种条件下表现出稳健、持续的强大性能,超过或保持与常用的WT算法的竞争力,后者在非磨损时间较短时具有明显的不准确性。在两种统计学习算法中,GMM优于HMM。
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CiteScore
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