Dooley Erin E, Winkles J F, Colvin Alicia, Kline Christopher E, Badon Sylvia E, Diaz Keith M, Karvonen-Gutierrez Carrie A, Kravitz Howard M, Sternfeld Barbara, Thomas S Justin, Hall Martica H, Gabriel Kelley Pettee
Department of Epidemiology, The University of Alabama at Birmingham, Birmingham, AL, USA.
Epidemiology Data Center, The University of Pittsburgh, Pittsburgh, PA, USA.
J Act Sedentary Sleep Behav. 2023;2. doi: 10.1186/s44167-023-00017-5. Epub 2023 Apr 5.
Daily 24-h sleep-wake cycles have important implications for health, however researcher preferences in choice and location of wearable devices for behavior measurement can make 24-h cycles difficult to estimate. Further, missing data due to device malfunction, improper initialization, and/or the participant forgetting to wear one or both devices can complicate construction of daily behavioral compositions. The Method for Activity Sleep Harmonization (MASH) is a process that harmonizes data from two different devices using data from women who concurrently wore hip (waking) and wrist (sleep) devices for ≥ 4 days.
MASH was developed using data from 1285 older community-dwelling women (ages: 60-72 years) who concurrently wore a hip-worn ActiGraph GT3X + accelerometer (waking activity) and a wrist-worn Actiwatch 2 device (sleep) for ≥ 4 days (N = 10,123 days) at the same time. MASH is a two-tiered process using (1) scored sleep data (from Actiwatch) or (2) one-dimensional convolutional neural networks (1D CNN) to create predicted wake intervals, reconcile sleep and activity data disagreement, and create day-level night-day-night pairings. MASH chooses between two different 1D CNN models based on data availability (ActiGraph + Actiwatch or ActiGraph-only). MASH was evaluated using Receiver Operating Characteristic (ROC) and Precision-Recall curves and sleep-wake intervals are compared before (pre-harmonization) and after MASH application.
MASH 1D CNNs had excellent performance (ActiGraph + Actiwatch ROC-AUC = 0.991 and ActiGraph-only ROC-AUC = 0.983). After exclusions (partial wear [n = 1285], missing sleep data proceeding activity data [n = 269], and < 60 min sleep [n = 9]), 8560 days were used to show the utility of MASH. Of the 8560 days, 46.0% had ≥ 1-min disagreement between the devices or used the 1D CNN for sleep estimates. The MASH waking intervals were corrected (median minutes [IQR]: -27.0 [-115.0, 8.0]) relative to their pre-harmonization estimates. Most correction (-18.0 [-93.0, 2.0] minutes) was due to reducing sedentary behavior. The other waking behaviors were reduced a median (IQR) of -1.0 (-4.0, 1.0) minutes.
Implementing MASH to harmonize concurrently worn hip and wrist devices can minimizes data loss and correct for disagreement between devices, ultimately improving accuracy of 24-h compositions necessary for time-use epidemiology.
每日24小时的睡眠 - 清醒周期对健康有重要影响,然而研究人员在选择用于行为测量的可穿戴设备及其佩戴位置上的偏好可能会使24小时周期难以估计。此外,由于设备故障、初始化不当和/或参与者忘记佩戴一个或两个设备而导致的数据缺失,可能会使日常行为构成的构建变得复杂。活动睡眠协调方法(MASH)是一种使用来自同时佩戴髋部(清醒时)和手腕(睡眠时)设备≥4天的女性数据来协调来自两种不同设备数据的过程。
MASH是利用1285名年龄在60 - 72岁之间的社区老年女性的数据开发的,这些女性同时佩戴髋部佩戴的ActiGraph GT3X +加速度计(清醒活动)和手腕佩戴的Actiwatch 2设备(睡眠)≥4天(N = 10,123天)。MASH是一个两层过程,使用(1)评分睡眠数据(来自Actiwatch)或(2)一维卷积神经网络(1D CNN)来创建预测的清醒间隔,协调睡眠和活动数据的不一致,并创建日级的夜 - 日 - 夜配对。MASH根据数据可用性(ActiGraph + Actiwatch或仅ActiGraph)在两种不同的1D CNN模型之间进行选择。使用受试者工作特征(ROC)和精确召回曲线对MASH进行评估,并比较MASH应用前后(预协调)的睡眠 - 清醒间隔。
MASH的1D CNN具有出色的性能(ActiGraph + Actiwatch的ROC - AUC = 0.991,仅ActiGraph的ROC - AUC = 0.983)。排除部分佩戴情况(n = 1285)、活动数据之前缺少睡眠数据(n = 269)以及睡眠<60分钟的情况(n = 9)后,使用8560天的数据来展示MASH的效用。在这8560天中,46.0%的天数在设备之间存在≥1分钟的不一致情况,或者使用1D CNN进行睡眠估计。相对于预协调估计,MASH的清醒间隔得到了校正(中位数分钟数[四分位间距]:-27.0 [-115.0, 8.0])。大多数校正(-18.0 [-93.0,
