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AIMS Public Health

2016, Volume 3, Issue 2: 298-312. doi: 10.3934/publichealth.2016.2.298
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Research article Special Issues

Validation and Comparison of Accelerometers Worn on the Hip, Thigh, and Wrists for Measuring Physical Activity and Sedentary Behavior

  • 1.
    Clinical Exercise Physiology Program, School of Kinesiology, Ball State University, Muncie, IN, USA
  • 2.
    Human Energy Research Laboratory, Department of Kinesiology, Michigan State University, East Lansing, MI, USA
  • 3.
    Networked Embedded & Wireless Systems Laboratory, Department of Electrical and Computer Engineering, Michigan State University, East Lansing, MI, USA
  • Background: Recent evidence suggests that physical activity (PA) and sedentary behavior (SB) exert independent effects on health. Therefore, measurement methods that can accurately assess both constructs are needed. Objective: To compare the accuracy of accelerometers placed on the hip, thigh, and wrists, coupled with machine learning models, for measurement of PA intensity category (SB, light-intensity PA [LPA], and moderate- to vigorous-intensity PA [MVPA]) and breaks in SB. Methods: Forty young adults (21 female; age 22.0 ± 4.2 years) participated in a 90-minute semi-structured protocol, performing 13 activities (three sedentary, 10 non-sedentary) for 3–10 minutes each. Participants chose activity order, duration, and intensity. Direct observation (DO) was used as a criterion measure of PA intensity category, and transitions from SB to a non-sedentary activity were breaks in SB. Participants wore four accelerometers (right hip, right thigh, and both wrists), and a machine learning model was created for each accelerometer to predict PA intensity category. Sensitivity and specificity for PA intensity category classification were calculated and compared across accelerometers using repeated measures analysis of variance, and the number of breaks in SB was compared using repeated measures analysis of variance. Results: Sensitivity and specificity values for the thigh-worn accelerometer were higher than for wrist- or hip-worn accelerometers, > 99% for all PA intensity categories. Sensitivity and specificity for the hip-worn accelerometer were 87–95% and 93–97%. The left wrist-worn accelerometer had sensitivities and specificities of > 97% for SB and LPA and 91–95% for MVPA, whereas the right wrist-worn accelerometer had sensitivities and specificities of 93–99% for SB and LPA but 67–84% for MVPA. The thigh-worn accelerometer had high accuracy for breaks in SB; all other accelerometers overestimated breaks in SB. Conclusion: Coupled with machine learning modeling, the thigh-worn accelerometer should be considered when objectively assessing PA and SB.

    Citation: Alexander H.K. Montoye, James M. Pivarnik, Lanay M. Mudd, Subir Biswas, Karin A. Pfeiffer. Validation and Comparison of Accelerometers Worn on the Hip, Thigh, and Wrists for Measuring Physical Activity and Sedentary Behavior[J]. AIMS Public Health, 2016, 3(2): 298-312. doi: 10.3934/publichealth.2016.2.298

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  • Background: Recent evidence suggests that physical activity (PA) and sedentary behavior (SB) exert independent effects on health. Therefore, measurement methods that can accurately assess both constructs are needed. Objective: To compare the accuracy of accelerometers placed on the hip, thigh, and wrists, coupled with machine learning models, for measurement of PA intensity category (SB, light-intensity PA [LPA], and moderate- to vigorous-intensity PA [MVPA]) and breaks in SB. Methods: Forty young adults (21 female; age 22.0 ± 4.2 years) participated in a 90-minute semi-structured protocol, performing 13 activities (three sedentary, 10 non-sedentary) for 3–10 minutes each. Participants chose activity order, duration, and intensity. Direct observation (DO) was used as a criterion measure of PA intensity category, and transitions from SB to a non-sedentary activity were breaks in SB. Participants wore four accelerometers (right hip, right thigh, and both wrists), and a machine learning model was created for each accelerometer to predict PA intensity category. Sensitivity and specificity for PA intensity category classification were calculated and compared across accelerometers using repeated measures analysis of variance, and the number of breaks in SB was compared using repeated measures analysis of variance. Results: Sensitivity and specificity values for the thigh-worn accelerometer were higher than for wrist- or hip-worn accelerometers, > 99% for all PA intensity categories. Sensitivity and specificity for the hip-worn accelerometer were 87–95% and 93–97%. The left wrist-worn accelerometer had sensitivities and specificities of > 97% for SB and LPA and 91–95% for MVPA, whereas the right wrist-worn accelerometer had sensitivities and specificities of 93–99% for SB and LPA but 67–84% for MVPA. The thigh-worn accelerometer had high accuracy for breaks in SB; all other accelerometers overestimated breaks in SB. Conclusion: Coupled with machine learning modeling, the thigh-worn accelerometer should be considered when objectively assessing PA and SB.


    Abbreviations:
    SB: sedentary behavior
    LPA: light-intensity physical activity
    MVPA: moderate- to vigorous-intensity physical activity
    PA: physical activity
    DO: direct observation
    METs: metabolic equivalents
    ANN: artificial neural network

    1. Introduction

    Moderate- to vigorous-intensity physical activity (MVPA; energy expenditure ≥ 3.0 METs), has long been recognized for its beneficial effects on many acute and chronic health indices and is often called “health-enhancing physical activity” [1]. More recently, epidemiologic and laboratory-based studies have uncovered associations between high amounts of sedentary behavior (SB), defined as seated or lying activities requiring low levels of energy expenditure (i.e., ≤ 1.5 METs) [2], and diminished metabolic and cardiovascular health as well as an increased risk of obesity, some cancers, and all-cause mortality [3,4,5]. There is also some evidence that associations of SB and adverse health conditions may be independent of time spent in MVPA [6]. Additionally, the way SB is accrued may influence health, with longer periods of SB being worse than SB broken up periodically by short bouts of non-sedentary activities [6,7]. While many health-based interventions focus on increasing MVPA, there is also evidence that reducing SB by increasing light-intensity physical activity (LPA; energy expenditure 1.6-2.9 METs) is beneficial to health, even if MVPA is unchanged [8,9]. However, despite emerging findings of potential SB health risks, current research is insufficient to allow for creation of evidence-based recommendations for SB or how SB and MVPA interact to affect health; contributing to the lack of evidence-based recommendations is the difficulty in accurately measuring time spent in each physical activity (PA) intensity category (SB, LPA, MVPA).

    Accelerometry-based activity monitors (accelerometers) are currently used to measure PA intensity category. Traditionally, raw accelerometer data were converted to “activity counts” which correspond to frequency and magnitude of acceleration. Cut-point thresholds could then be developed to assess SB, LPA, or MVPA from accelerometer data. A range of cut-points are available to assess PA intensity category; perhaps the most commonly used cut-points for adult populations are < 100 counts/minute for SB, 100-1,951 counts/min for LPA, and ≥ 1,952 counts/min for MVPA for the ActiGraph accelerometer [10,11,12,13]. However, these cut-points were developed in specific populations and during strict, laboratory-based protocols. Other studies validating the ActiGraph have found vastly different cut-points for SB (range 50-250 counts/min) and MVPA (191-2,691 counts/min) in adults, depending on the population and type of validation setting [14,15,16,17,18]. Regardless of which cut-points are chosen to designate SB, LPA, and MVPA, the cut-point method has several limitations. First, the cut-point approach cannot differentiate standing from sitting/lying, but standing is considered LPA because it elicits different physiologic responses and has different long-term health consequences than sitting/lying [19,20]. Furthermore, the MVPA threshold for accelerometer counts/min is considerably different for ambulatory activities compared to non-ambulatory activities, rendering any single cut-point inaccurate for assessing MVPA [21]. An accurate measurement tool for SB needs to differentiate between SB and standing or other LPA; the measurement tool must also be able to classify intensity of both ambulatory and non-ambulatory activities for MVPA.

    Due to limitations of the cut-point approach to measuring PA intensity categories, researchers have utilized machine learning models to improve accuracy of PA measurement. Studies show improved measurement of energy expenditure, accurate classification of activity type, and correct classification of PA intensity category from a hip-mounted accelerometer [22,23,24]. Despite the common use of hip-mounted accelerometers, there are advantages, such as improved comfort and compliance, of wearing accelerometers on other body locations. Research shows that machine learning modeling has dramatically improved measurement accuracy of accelerometers worn on various body locations, such as the wrist and thigh [23,25]. Additionally, accelerometers worn on the wrist and thigh have shown strong ability to detect specific activities and have yielded acceptably accurate assessments of energy expenditure and SB [23,26,27]. However, these accelerometer placements have not yet been tested for assessment of PA intensity category when coupled with machine learning models. Therefore, the purpose of our study was to develop, validate, and compare the accuracy of hip-, thigh-, and wrist-worn accelerometers, coupled with machine learning models, for measuring 1) total time spent in SB, LPA, and MVPA intensity categories, and 2) breaks in SB in a semi-structured setting.

    2. Materials and Method

    2.1. Study participants

    Study participants (n = 44,50% female) were recruited from the surrounding area of East Lansing, MI. Eligible participants were able to perform MVPA safely, did not have orthopedic limitations, were 18-44 years old and could read and speak the English language. Written, voluntary informed consent was obtained from all participants, and this study was approved by the Michigan State University Institutional Review Board.

    2.2. Equipment

    Each participant wore four accelerometers in this study. Two ActiGraph GT3X+ accelerometers (ActiGraph LLC, Pensacola, FL) were worn, one on the midline of the right thigh (adhered with hypoallergenic tape), and one above the right hip at the anterior axillary line (secured on elastic hip belt). Participants also wore two GENEActiv accelerometers (Activinsights Ltd, Kimbolton, Cambridgeshire, UK), one on the dorsal side of each wrist using a manufacturer-supplied watch strap. A sampling frequency of 20 Hz was chosen for the GENEA accelerometers for comparison to another accelerometer tested (not used in this analysis). ActiGraph accelerometers have a minimum sampling frequency of 30 Hz; therefore, 40 Hz was chosen for sampling frequency, which was reintegrated to 20 Hz after downloading data. A portable metabolic analyzer (Oxycon Mobile; CareFusion, San Diego, CA) was worn by participants during the study, but these data were not utilized for the current analysis.

    2.3. Procedure

    Upon arrival at the Human Energy Research Laboratory, each participant's weight and height were then measured (to the nearest 0.1 kg and 0.1 cm, respectively) according to standardized methods [28]. Handedness was determined by asking participants which hand they prefer to use for the majority of everyday activities, and participant age was determined from self-reported date of birth.

    After being fitted with the four accelerometers, participants performed 13 activities of different types and intensities that encompassed types of activities that individuals may perform in a free-living environment (Table 1). Participants performed the activities for a total of 90 minutes. They performed each of the activities for between 3-10 minutes each, in the order and exact duration of their choosing. Ambulatory activities (walking and jogging) are common in accelerometer validation literature; we included these but added sedentary, exercise, and lifestyle activities to determine the potential for the four accelerometer placements to measure different PA intensity categories accurately in a semi-structured, simulated free-living setting. The 13 activities were described to each participant prior to the start of the protocol, and some of the less familiar activities (e.g., squats) were demonstrated to ensure understanding. Additionally, the research assistant performing direct observation (DO) updated participants periodically on which activities they still needed to complete.

    Table 1.Activities performed during the semi-structured protocol.
    ActivityPA intensity category
    Lying downSB
    ReadingSB
    Computer useSB
    StandingLPA
    LaundryLPA
    SweepingLPA
    Biceps curls (1.3 kg resistance in each hand)LPA
    Walking slow (self-paced)LPA
    Walking fast (self-paced)MVPA
    Jogging (self-paced)MVPA
    Cycling (self-paced)MVPA
    Stair climbing and descending (self-paced)MVPA
    Squats (body weight as resistance)MVPA
     | Show Table
    DownLoad: CSV

    2.4. Creation of models to predict PA intensity category

    From the raw accelerometer data, percentiles (10th, 25th, 50th, 75th, and 90th) were extracted for each accelerometer axis for each 30-second window of data, and the extracted features were used as inputs for machine learning model development. No filtering of the raw accelerometer data was conducted prior to feature extraction. The 30-second window length was chosen partially to time-match with portable metabolic analyzer data; additionally, 30-second windows were chosen rather than 60-second windows due to non-steady-state nature of the protocol. Artificial neural networks (ANNs), a popularly tested modeling technique for predicting activity type and energy expenditure from accelerometer data, were developed for this study [24,29,30]. The ANNs were created to categorically classify all activity into one of three intensity categories: SB, LPA, or MVPA. The decision not to further differentiate MVPA into moderate- or vigorous-intensity PA was made to maximize accuracy of the ANN models, which have lower classification accuracy as more classification categories are added [31,32,33]; additionally, for researchers and practitioners interested in assessing health-enhancing PA rather than specific intensities, further differentiation of higher-intensity activities may not always be necessary. A graphical depiction of the ANNs created in the current study is shown in Figure 1. The ANN function outputs a probability between 0-1 of each PA intensity category. Values closer to one represented a higher likelihood of that intensity category, and the intensity category with the value closest to one was chosen as the predicted output by the ANN. Breaks in SB from the accelerometers were determined as a 30-second window of LPA or MVPA which followed time classified as SB. The ANNs created in this study contained 1 hidden layer and 5 hidden units. Skip-layer connections were not allowed in the ANN.

    Figure 1.ANN for predicting PA intensity category.
    *The number of input features was 15 (5 features*3 measurement axes).
    Abbreviations:
    10th % ile: 10th percentile of acceleration signal. 25th % ile: 25th percentile of acceleration signal.
    50th % ile: 50th percentile of acceleration signal. 75th % ile: 75th percentile of acceleration signal.
    90th % ile: 90th percentile of acceleration signal.
    S: summation functions of the input layer in the hidden units.
    U: activation function for the hidden layer.
    W1: the weight vectors for each of the inputs.
    W2: the weight vectors for each of the summations.
    DownLoad: Full-Size ImgPowerPoint

    The ANNs were created and tested using a leave-one-out cross-validation. In this approach, data from all but one participant were used to estimate the weights for each input feature for predicting PA intensity category. Then, the ANN was tested on the data from the participant left out of the training phase by supplying the input features and comparing the predicted PA intensity category from the ANNs to the recorded PA intensity category from DO. The leave-one-out cross-validation is an iterative approach and was repeated with each participant's data used as the testing data once. This process was conducted separately for each accelerometer, resulting in four distinct ANNs. The ANNs developed can be found at the following link: https://drive.google.com/open?id=0B-BgdTzyd2OxazA1UE1zcTFEY1k.

    2.5. Direct observation

    DO served as the criterion measure for time spent in SB, LPA, MVPA, and the number of breaks in SB for the current study. Activities performed were recorded continuously and in real time on a handheld personal digital assistant using the BEST (Observerware, Hobe Sound, FL) observation software. Using this software, activities performed during the visit were coded as 1 of the 13 activity types listed in Table 1. Research assistants were trained to record an activity change as closely as possible to the moment it occurred. After collection, DO data were synchronized with the accelerometer data so that each 30-second window of accelerometer data was matched to the actual activity performed during that window. In most cases, only one activity occurred during a given 30-second window. However, when transitioning between activities, two activities could occur in the same window. If this occurred, the window was automatically recoded as a transition. Additionally, the transition category was used to define all time between activities, such as resting or making an equipment adjustment between activities. Thus, transitions did not represent a specific activity type but instead involved walking, standing, etc. that occurred at the end of one activity and before the next started. All data coded as a transition were included when determining breaks in SB but removed from the DO and accelerometer datasets prior to creation and testing of the ANNs for the determination of time spent in each PA intensity category. From the DO data, activities were classified into one of three intensity categories (SB, LPA, or MVPA) based on MET values published in the Compendium of Physical Activities [34]. For DO, transitions from SB to a non-sedentary activity were summed to obtain total breaks in SB during the protocol. Five research assistants collected DO data during the study. Pilot testing demonstrated inter-researcher reliability of r > 0.92 across all research assistants for assessment of total time in each activity type.

    2.6. Statistical analyses

    Sensitivity and specificity were calculated for SB, LPA, and MVPA for each accelerometer and each participant. Sensitivity was calculated by assessing the proportion of instances of a certain intensity category correctly classified as that category by the accelerometer (e.g., the proportion of instances where the participant was performing SB that the thigh-worn accelerometer correctly classified the activity as SB). Specificity was calculated as the proportion of instances where an intensity category was not performed and was correctly classified as not performing that intensity category (e.g., the proportion of time an individual was not performing SB [i.e., was performing LPA or MVPA] that the thigh-worn accelerometer correctly classified the activity as not SB). Repeated measures analysis of variance tests were used to compare sensitivity and specificity among accelerometers. Confusion matrices were created to assess misclassification of PA intensity category, and weighted Kappa statistics (with quadratic weights and equal weighting for relative distance) were calculated and compared among accelerometer placements. Additionally, repeated measures analysis of variance was conducted to compare total time spent in SB, LPA, and MVPA predicted from each accelerometer to time measured by DO. For breaks in SB, criterion-measured breaks were also obtained for each participant using DO. Differences among DO and the four accelerometers were evaluated with repeated measures analysis of variance. If significant differences were revealed in any of the repeated measures analysis of variance tests, post hoc dependent t-tests were conducted with a least significant difference correction. An alpha level of p < 0.05 was used to determine statistical significance. We desired 90% power to be able to detect significant differences for an effect size of 0.5 among accelerometers for sensitivity and specificity and for predicted and measured time spent in each PA intensity category and breaks in SB. At an alpha level of p = 0.05, 36 subjects were required. Therefore, our sample size of 44 provided sufficient power to address our research questions.

    3. Results

    Of the 44 participants who participated in study, accelerometer malfunction occurred during one participant's visit, resulting in exclusion from the data analysis. Additionally, the portable metabolic analyzer (used to address an aim not part of the current study) malfunctioned in three participants, resulting in premature termination of the protocol and exclusion of their data from the analysis. Demographic characteristics of the 40 participants included in data analysis are displayed in Table 2. Approximately 25% of the sample was classified as overweight (≥ 25.0 kg/m2 body mass index), and 90% of the sample reported being right-hand dominant.

    Table 2.Demographic characteristics of participants in study.
    All (n = 40)Males (n = 19)Females (n = 21)
    Age (years)22.0 (4.2)23.7 (5.0)20.5 (2.7)
    Weight (kg)71.9 (16.3)84.5 (13.1)60.4 (8.8)
    Height (cm)171.0 (10.3)179.1 (7.7)163.7 (5.9)
    BMI (kg/m2)24.3 (3.5)26.3 (3.4)22.5 (2.6)
    Left-hand dominantn = 4 (10.0%)n = 4 (21.1%)n = 0 (0.0%)
    Data for age, weight, height, and body mass index (BMI) are displayed as mean (standard deviation).
    Data for hand dominance are displayed as total number (% of sample).
     | Show Table
    DownLoad: CSV

    Sensitivity and specificity for classification of each PA intensity category are displayed in Table 3. For SB, the thigh-worn accelerometer had significantly higher sensitivity and specificity than the rest of the accelerometers, and the left wrist-worn accelerometer showed higher sensitivity and specificity than the hip- and right wrist-worn accelerometers. For LPA, the thigh-worn accelerometer had significantly higher sensitivity and specificity than the hip- and right-wrist-worn accelerometers, and the left wrist-worn accelerometer had significantly higher sensitivity and specificity than the hip-worn accelerometer. For MVPA, the thigh-worn accelerometer had significantly higher sensitivity and specificity than all other accelerometers, and the left wrist-worn accelerometer had higher sensitivity and specificity than the hip- and right wrist-worn accelerometers; conversely, the right wrist-worn accelerometer had a lower sensitivity and specificity than all other accelerometers.

    Table 3.Sensitivity and specificity for predictions of SB, LPA and MVPA.
    AccelerometerSBLPAMVPA
    Sensitivity (%)Specificity (%)Sensitivity (%)Specificity (%)Sensitivity (%)Specificity (%)
    Hip88.3 (13.6)2396.3 (4.2)2394.9 (7.1)23496.9 (3.9)23486.5 (10.5)23492.9 (5.4)234
    Thigh99.5 (1.9)13499.9 (0.4)13499.6 (1.8)1499.7 (1.3)1499.2 (3.3)13499.5 (1.8)134
    Left wrist97.5 (4.8)12499.2 (1.4)12499.0 (2.7)199.3 (1.8)1490.8 (10.3)12495.4 (4.6)124
    Right wrist93.1 (7.4)2397.6 (2.6)2397.8 (3.6)1298.7 (1.8)1265.7 (19.1)12384.1 (6.5)123
    Data are displayed as mean (standard deviation).
    1Indicates significant difference from hip-worn accelerometer. 2Indicates significant difference from thigh-worn accelerometer. 3Indicates significant difference from left wrist-worn accelerometer. 4Indicates significant difference right wrist-worn accelerometer.
     | Show Table
    DownLoad: CSV

    To further examine PA intensity category prediction, confusion matrices were created for PA intensity classification by each accelerometer, as shown in Figure 2. For the hip-worn accelerometer, most misclassifications were by a single intensity category, with only 6 instances (0.4%) of SB misclassified as MVPA and 44 instances (1.9%) of MVPA misclassified as SB. A similar scenario was present for the thigh-worn accelerometer (1 instance [< 0.1%] of SB misclassified as MVPA and 0 instances of MVPA misclassified as SB) and the left wrist-worn accelerometer (26 instances [1.6%] of SB misclassified as MVPA and 8 instances [0.3%] of MVPA misclassified as SB). For the right wrist-worn accelerometer, there were more instances of misclassification of SB as MVPA (48 instances [3.0%]) and MVPA as SB (185 instances [7.9%]). Additionally, weighted Kappa (K) statistics are shown in Table 4. Significant differences in Kappa statistics were seen among all four accelerometers, with almost perfect PA intensity category classification from the thigh-worn accelerometer (K = 0.99), very good classification accuracy from the left wrist-worn (K = 0.95) and hip-worn (K = 0.90) accelerometers, and good classification accuracy of the right wrist-worn accelerometer (K = 0.78) [35].

    Figure 2.Confusion matrices for prediction of SB, LPA, and MVPA.
    For a-d, rows are actual PA intensities and columns are predicted PA intensities.
    Grey boxes represent number of instances where the PA intensity category was correctly predicted.
    DownLoad: Full-Size ImgPowerPoint
    Table 4.Weighted Kappa statistics for PA intensity category classification by accelerometer placement.
    Accelerometer placementWeighted Kappa
    Hip0.90 (0.89 – 0.91)
    Thigh0.99 (0.99 – 1.00)
    Left wrist0.95 (0.94 – 0.96)
    Right wrist0.78 (0.76 – 0.80)
    Data are shown as weighted Kappa (95% confidence interval).
     | Show Table
    DownLoad: CSV

    Predictions of total time spent in SB, LPA, and MVPA among accelerometers and the criterion measure (DO) are shown in Figure 3. SB estimated by thigh-worn accelerometer was the same as DO-measured SB for 37 of the 40 study participants, resulting in a mean SB predicted for the entire sample that was not significantly different from DO-measured SB. Additionally, predicted time spent in LPA and MVPA by the thigh-worn accelerometer was not significantly different from DO. Prediction of SB by the left wrist-worn accelerometer was not significantly different than DO, although it overestimated time spent in LPA (2.2 min [~ 7%], p < 0.01) and underestimated time spent in MVPA (1.9 min [7%], p < 0.01). Both the hip- and right wrist-worn accelerometers estimates were significantly different from DO for all intensity categories, with the hip-worn accelerometer underestimating SB (1.1 min [6%], p = 0.024) and MVPA (3.0 min [10%], p < 0.01) but overestimating LPA (4.1 min [15%], p < 0.01) and the right wrist-worn accelerometer overestimating SB (1.2 min [6%], p < 0.01) and LPA (7.4 min [25%], p < 0.01) but underestimating MVPA (8.6 min [30%], p < 0.01), compared to DO.

    Figure 3.Predicted vs. measured time in each PA intensity category.
    Error bars represent standard deviation.
    * Indicates significant differences from the criterion measure (direct observation).
    DownLoad: Full-Size ImgPowerPoint

    Breaks in SB as predicted by the accelerometers and measured by DO are shown in Figure 4. Breaks in SB predicted by the thigh-worn accelerometer were the same as DO-measured breaks in SB for each of the 40 participants in the study, resulting in the same mean and standard deviation of the data as DO (i.e., was not significantly different from DO). Conversely, breaks in SB were overestimated by the hip-worn accelerometer (mean difference 1.4 breaks [70%], p < 0.01), left wrist-worn accelerometer (mean difference 0.4 breaks [20%], p < 0.01), and right wrist-worn accelerometer (mean difference 2.7 breaks [135%], p < 0.01).

    Figure 4.Predicted vs. measured breaks in SB.
    Error bars represent standard deviation.
    * Indicates significant differences from the criterion measure (direct observation).
    DownLoad: Full-Size ImgPowerPoint

    4. Discussion

    This study's purpose was to test accelerometers worn on the hip, thigh, and wrists (coupled with ANN models) for prediction of time spent in PA intensity categories (SB, LPA, and MVPA) in 30-second windows as well as breaks in SB. While previous research has shown strong utility of ANNs and other machine learning models for assessment of energy expenditure and/or recognizing specific activity types, to our knowledge our study is the first to use machine learning models for several accelerometers specifically to assess time spent in PA intensity categories. The assessment of energy expenditure in terms of Calories or METs has proven difficult, with most current research in this area showing prediction errors (i.e., root mean square error) of > 1.0 MET, which represents a large error when the average daily MET level for adults is < 1.5 METs [23,36,37]. While the assessment of PA into three distinct intensity categories (SB, LPA, and MVPA) is more crude than predicting Calories or METs, assessment of time into PA intensity categories is simpler to model and still allows for valuable information regarding individuals' PA levels, adherence to PA guidelines, and associated health implications.

    Our study found high accuracy of the thigh-worn accelerometer for predicting time spent in each PA intensity category, as seen by sensitivities and specificities > 99% for correctly classifying each PA intensity category and no differences from the DO in predictions of total time spent in any category; additionally, the thigh-worn accelerometer correctly predicted the number of breaks in SB for all 40 participants in the study, providing evidence that the thigh-worn accelerometer has high utility for detecting temporal changes in PA and SB. Previous research also shows high accuracy of thigh-worn accelerometers for assessing time spent in SB and breaks in SB [14,15,27], and our study extends these findings by showing that thigh-worn accelerometers are also capable of accurately assessing time spent in LPA and MVPA, thereby demonstrating the thigh-worn accelerometer's utility to assess time spent in SB and health-enhancing PA (i.e., MVPA). The superior accuracy of the thigh-worn accelerometer supports previous research showing high accuracy of a thigh-worn accelerometer for measurement of energy expenditure and activity type classification [23,29,31]. Due to their consistently high accuracy for measuring several different PA constructs and sleep [38], continuous wear (primarily using adhesive tape) for high compliance, and the miniaturization of accelerometer devices, thigh-worn accelerometers have strong potential for assessment of a number of health-related constructs.

    Our study also indicated high PA intensity category classification accuracy and prediction of SB for the left wrist-worn accelerometer, achieving sensitivities above 90% and specificities above 95% for all PA intensity categories and no difference from DO for total SB. The left wrist-worn accelerometer did especially well at lower intensity categories, achieving sensitivities and specificities above 97% for SB and LPA. The right wrist-worn accelerometer also had high sensitivities and specificities for SB and LPA (> 93%), but both sensitivity and specificity were significantly lower for MVPA, which was commonly misclassified as LPA. Additionally, the right wrist-worn accelerometer underestimated MVPA but overestimated time spent in SB and LPA and had a more pronounced overestimation of breaks in SB than the left wrist-worn accelerometer. Our findings are supported by those of Esliger et al., who performed the initial validation of the GENEA accelerometer in 2011 and also found higher classification accuracy of PA intensity category using cut-points for a left-wrist accelerometer compared to a right-wrist accelerometer [39]. Given that 90% of our sample reported the left hand being their non-dominant hand, our findings provide evidence that an accelerometer worn on the non-dominant wrist may have better utility for assessing PA intensity category and SB than a dominant wrist-worn accelerometer. One reason for lower accuracy when an accelerometer is worn on the right wrist may be lack of familiarity, since most wristwatches are designed to be worn on the left hand, which could influence movement patterns when performing an activity. Another reason may be the greater variability of movement of the dominant hand during everyday activities. Regardless, these studies provide evidence that studies assessing PA intensity may prefer to use the non-dominant wrist for accelerometer wear. Pavey et al. and Rowlands et al. provide further rationale for using an accelerometer worn on the non-dominant wrist for assessing time spent in SB [26,40,41]. These findings also support the choice for wearing accelerometers on the non-dominant wrist in the 2011-2014 NHANES data collection cycle [42].

    The hip-worn accelerometer, while providing high specificity across all PA intensity categories, had lower sensitivity for correctly classifying PA intensity category and frequently misclassified SB and MVPA as LPA, resulting in underestimations of time spent in SB and MVPA but an overestimation of time spent in LPA and in breaks in SB. Previous studies by Lyden et al. and Kozey-Keadle et al. demonstrate difficulties in assessing time spent in SB and breaks in SB with hip-worn accelerometers using traditional cut-point methods, and our study adds to these findings by illustrating misclassification of SB as a non-sedentary activity (and vice versa) with machine learning models [14,15]. Given the similar hip angle and minimal movement present in most types of SB and for non-sedentary activities such as standing, hip-worn monitors appear limited in their capacity for assessing SB. It should be noted that sensitivities and specificities were above 86% and predicted time in each intensity category was within 15% of criterion measure with the hip-worn accelerometer, indicating reasonable accuracy for the hip-worn accelerometer. However, with the high performance of the thigh- and left wrist-worn accelerometers for assessing SB as well as higher-intensity PA, these alternative accelerometer locations, when coupled with machine learning modeling, may be preferable to hip-worn accelerometers for assessment of PA intensity.

    There are a number of factors to consider when employing the developed ANNs from our study. First, these ANNs were developed in a semi-structured setting and require cross-validation in a free-living environment. Additionally, most studies use hip-worn accelerometers and cut-points for data analysis, and use of alternate placements and machine learning may affect comparability of PA estimates across studies. Additionally we chose to use 30-second windows due to the non-steady-state nature of the protocol. A 30-second window is shorter than the 60-second window typically used for applying cut-points to accelerometer data in studies assessing PA in adults, and studies evaluating window (or epoch) length show that use of different epoch lengths affects estimations of time spent in different PA intensities [43,44]. Therefore, the use of alternate accelerometer placements vs. hip-worn accelerometers, machine learning vs. cut-points, and 30-second vs. 60-second windows should be considered when comparing estimates of PA from the developed ANNs to estimates derived from cut-point approaches with hip-worn accelerometers.

    This study had several strengths. First, the semi-structured setting allowed for considerable freedom in the manner in which participants performed their activities, thereby improving the generalizability of the ANN models created. The most common accelerometer placement sites (hip, thigh, and wrist) were included in this study, allowing for direct comparison of their utility for assessment of PA intensity category. Moreover, comparison of left and right wrists provided insight into which wrist may be preferable for accelerometer wear. Finally, classification into PA intensity categories, as was performed in this study, allows for reasonably accurate assessment of PA patterns while avoiding the difficulties associated with predicting energy expenditure or activity type using accelerometers.

    This study also had several limitations worth considering. The study sample consisted mainly of younger adults, and the ANN models developed in this study need further validation before use in an older or more diverse population. Additionally, while we consider the semi-structured setting a study strength, the study included a limited set of activities, and the ANN models developed in this study may not correctly classify intensity of other activities, such as sports, which were not evaluated in this study.

    DO was used as a criterion measure of PA intensity category, which does not directly measure the energy cost of an activity but, rather, classifies it based on the Compendium of Physical Activities [34]. Our choice for using DO instead of directly-measured energy expenditure (e.g., via a metabolic analyzer)to characterize PA intensity category was predicated on the non-steady-state nature of the study protocol. Periods of SB following higher-intensity PA may have a falsely elevated energy cost (and vice versa for higher-intensity PA following SB) as the body's metabolic processes lag behind the current energy cost of the activity, and this would be problematic for assessing PA intensity category using a metabolic analyzer. To illustrate this point, a previous study by our research group using the same participants and activity protocol found that 29.5% of the time participants spent lying, reading, and using the computer (sedentary activities) elicited an energy expenditure > 1.5 METs and 3.3% of the time elicited an energy expenditure ≥ 3.0 METs (measured with a metabolic analyzer), which would incorrectly characterize the activity intensity as LPA and moderate-intensity PA, respectively. Similarly, 2.6% and 3.2% of the time participants spent jogging and using the stairs (MVPA) elicited an energy expenditure < 3.0 METs, which would incorrectly characterize the activity intensity as LPA [23]. Therefore, we feel that the use of DO was preferable over measured energy expenditure for characterizing PA intensity in the current study.

    Another study limitation is that our ANN models were not designed to differentiate between moderate-intensity PA (3.0-5.9 METs) and vigorous-intensity PA (≥ 6.0 METs), instead grouping these into a single MVPA category. While our main goal was to develop models capable of differentiating SB, LPA, and health-enhancing PA (MVPA), further differentiation into moderate and vigorous intensity categories would allow for more specific assessment of meeting PA recommendations. Finally, two different brands of accelerometers were used in the current analysis, making it possible that differences seen between the wrists (GENEA accelerometers) and hip and thigh (ActiGraph accelerometers) were due to accelerometer brand. A study by John et al. found that time domain features (similar to those used in the current study) were not interchangeable between monitor brands, providing evidence that ANNs from the wrist-worn GENEA accelerometer would have lower accuracy if used with wrist-worn ActiGraph accelerometers. However, John et al. also found similar PA measurement accuracy when using ANNs developed specifically for each two accelerometer brand [45]. Therefore, it is unlikely that accelerometer brand affected measurement accuracy.

    5. Conclusion

    An accelerometer worn on the right thigh, coupled with an ANN model, achieved high accuracy for classification of three distinct PA intensity categories (SB, LPA, and MVPA) as well as breaks in SB in a semi-structured setting. An accelerometer worn on the left wrist also had high accuracy for assessment of SB but had some misclassification of LPA and MVPA, whereas accelerometers worn on the right wrist and hip had the lowest accuracy for assessment of all PA intensity categories and for measuring breaks in SB. These findings support the use of a thigh-worn accelerometer for assessment of time spent in different PA intensity categories. Alternately, for researchers using wrist-worn accelerometers to assess PA, wear on the non-dominant wrist is likely to allow for higher measurement accuracy than wear on the dominant wrist. Further research should cross-validate these ANN models in a free-living setting to confirm findings from this study.

    Acknowledgments

    Todd Buckingham, Ryan Hulteen, Brandon Krinock, Elizabeth Lenz, and Stefan Rowland assisted with data collection and participant recruitment for this study. Additionally, this research was supported by the Michigan State University College of Education and by a Student Award Program grant (1997. SAP) from the Blue Cross Blue Shield of Michigan Foundation.

    Conflict of Interest

    The authors attest that they have no conflicts of interest to report.

    [1] U.S. Department of Health and Human Services. Physical Activity Guidelines Advisory Committee: 2008. Physical Activity Guidelines for Americans.
    [2] Sedentary Behavior Research Network. (2012) Letter to the Editor: Standardized use of the terms "sedentary" and "sedentary behaviours". Appl Physiol Nutr Metab 37: 540-542. doi: 10.1139/h2012-024
    [3] Hamilton MT, Hamilton DG, Zderic TW. (2007) Role of low energy expenditure and sitting in obesity, metabolic syndrome, type 2 diabetes, and cardiovascular disease. Diabetes 56: 2655-2667. doi: 10.2337/db07-0882
    [4] Hu FB, Li TY, Colditz GA, et al. (2003) Television watching and other sedentary behaviors in relation to risk of obesity and type 2 diabetes mellitus in women. JAMA 289: 1785-1791.
    [5] Katzmarzyk PT, Church TS, Craig CL, et al. (2009) Sitting time and mortality from all causes, cardiovascular disease, and cancer. Med Sci Sports Exerc 41: 998-1005. doi: 10.1249/MSS.0b013e3181930355
    [6] Owen N, Healy GN, Matthews CE, et al. (2010) Too much sitting: the population health science of sedentary behavior. Ex Sport Sci Rev 38: 105-113. doi: 10.1097/JES.0b013e3181e373a2
    [7] Healy GN, Dunstan DW, Salmon J, et al. (2008) Breaks in sedentary time: beneficial associations with metabolic risk. Diabetes Care 31: 661-666. doi: 10.2337/dc07-2046
    [8] Matthews CE, Moore SC, Sampson J, et al. (2015) Mortality Benefits for Replacing Sitting Time with Different Physical Activities. Med Sci Sports Exerc 47: 1833-1840. doi: 10.1249/MSS.0000000000000621
    [9] Stamatakis E, Rogers K, Ding D, et al. (2015) All-cause mortality effects of replacing sedentary time with physical activity and sleeping using an isotemporal substitution model: a prospective study of 201,129 mid-aged and older adults. Int J Behav Nutr Phys Act 12: 121. doi: 10.1186/s12966-015-0280-7
    [10] Treuth MS, Schmitz K, Catellier DJ, et al. (2004) Defining accelerometer thresholds for activity intensities in adolescent girls. Med Sci Sports Exerc 36: 1259-1266.
    [11] Freedson PS, Melanson E, Sirard J. (1998) Calibration of the Computer Science and Applications, Inc. accelerometer. Med Sci Sports Exerc 30: 777-781. doi: 10.1097/00005768-199805000-00021
    [12] Pedisic Z, Bauman A. (2015) Accelerometer-based measures in physical activity surveillance: current practices and issues. Br J Sports Med 49: 219-223.
    [13] Healy GN, Clark BK, Winkler EA, et al. (2011) Measurement of adults' sedentary time in population-based studies. Am J Prev Med 41: 216-227. doi: 10.1016/j.amepre.2011.05.005
    [14] Kozey-Keadle S, Libertine A, Lyden K, et al. (2011) Validation of wearable monitors for assessing sedentary behavior. Med Sci Sports Exerc 43: 1561-1567. doi: 10.1249/MSS.0b013e31820ce174
    [15] Lyden K, Kozey Keadle SL, Staudenmayer JW, et al. (2012) Validity of two wearable monitors to estimate breaks from sedentary time. Med Sci Sports Exerc 44: 2243-2252. doi: 10.1249/MSS.0b013e318260c477
    [16] Hendelman D, Miller K, Baggett C, et al. (2000) Validity of accelerometry for the assessment of moderate intensity physical activity in the field. Med Sci Sports Exerc 32: S442-449. doi: 10.1097/00005768-200009001-00002
    [17] Strath SJ, Bassett DR, Jr., Swartz AM. (2003) Comparison of MTI accelerometer cut-points for predicting time spent in physical activity. Int J Sports Med 24: 298-303. doi: 10.1055/s-2003-39504
    [18] Swartz AM, Strath SJ, Bassett DR, Jr., et al. (2000) Estimation of energy expenditure using CSA accelerometers at hip and wrist sites. Med Sci Sports Exerc 32: S450-456. doi: 10.1097/00005768-200009001-00003
    [19] Bey L, Hamilton MT. (2003) Suppression of skeletal muscle lipoprotein lipase activity during physical inactivity: a molecular reason to maintain daily low-intensity activity. J Physiol 551: 673-682.
    [20] Katzmarzyk PT. (2014) Standing and mortality in a prospective cohort of Canadian adults. Med Sci Sports Exerc 46: 940-946. doi: 10.1249/MSS.0000000000000198
    [21] Lyden K, Kozey SL, Staudenmeyer JW, et al. (2011) A comprehensive evaluation of commonly used accelerometer energy expenditure and MET prediction equations. Eur J Appl Physiol 111: 187-201. doi: 10.1007/s00421-010-1639-8
    [22] Staudenmayer J, Pober D, Crouter S, et al. (2009) An artificial neural network to estimate physical activity energy expenditure and identify physical activity type from an accelerometer. J Apple Physiol 107: 1300-1307. doi: 10.1152/japplphysiol.00465.2009
    [23] Montoye AH, Mudd LM, Biswas S, et al. (2015) Energy Expenditure Prediction Using Raw Accelerometer Data in Simulated Free Living. Med Sci Sports Exerc 47: 1735-1746. doi: 10.1249/MSS.0000000000000597
    [24] Lyden K, Keadle SK, Staudenmayer J, et al. (2013) A Method to Estimate Free-Living Active and Sedentary Behavior from an Accelerometer. Med Sci Sports Exerc 46: 386-397.
    [25] Preece SJ, Goulermas JY, Kenney LP, et al. (2009) Activity identification using body-mounted sensors--a review of classification techniques. Physiol Meas 30: R1-33. doi: 10.1088/0967-3334/30/4/R01
    [26] Rowlands AV, Olds TS, Hillsdon M, et al. (2014) Assessing sedentary behavior with the GENEActiv: introducing the sedentary sphere. Med Sci Sports Exerc 46: 1235-1247. doi: 10.1249/MSS.0000000000000224
    [27] Steeves JA, Bowles HR, McClain JJ, et al. (2015) Ability of thigh-worn ActiGraph and activPAL monitors to classify posture and motion. Med Sci Sports Exerc 47: 952-959. doi: 10.1249/MSS.0000000000000497
    [28] Malina R. (1995) Anthropometry. Physiological assessment of human fitness: 205-219.
    [29] Dong B, Montoye A, Moore R, et al. (2013) Energy-aware activity classification using wearable sensor networks. 87230Y-87230Y.
    [30] Montoye A, Dong B, Biswas S, et al. (2014) Use of a wireless network of accelerometers for improved measurement of human energy expenditure. Electronics 3: 205-220. doi: 10.3390/electronics3020205
    [31] Skotte J, Korshoj M, Kristiansen J, et al. (2014) Detection of physical activity types using triaxial accelerometers. J Phys Act Health 11: 76-84. doi: 10.1123/jpah.2011-0347
    [32] Cleland I, Kikhia B, Nugent C, et al. (2013) Optimal placement of accelerometers for the detection of everyday activities. Sensors 13: 9183-9200. doi: 10.3390/s130709183
    [33] Montoye AHK, Mudd LM, Pivarnik JM, et al. (2016) Comparison of activity type classification accuracy from accelerometers worn on the hip, wrists, and thigh in young, apparently healthy adults. Meas Phys Ed Exerc Sci In Press.
    [34] Ainsworth BE, Haskell WL, Herrmann SD, et al. (2011) Compendium of Physical Activities: a second update of codes and MET values. Med Sci Sports Exerc 43: 1575-1581. doi: 10.1249/MSS.0b013e31821ece12
    [35] Altman D. (1991) Practical Statistics for Medical Research. London, UK: Chapman & Hall.
    [36] Di Pietro L, Dziura J, Blair SN. (2004) Estimated change in physical activity level (PAL) and prediction of 5-year weight change in men: the Aerobics Center Longitudinal Study. Int J Obes Relat Metab Disord 28: 1541-1547. doi: 10.1038/sj.ijo.0802821
    [37] Staudenmayer J, He S, Hickey A, et al. (2015) Methods to estimate aspects of physical activity and sedentary behavior from high-frequency wrist accelerometer measurements. J Appl Physiol 119: 396-403. doi: 10.1152/japplphysiol.00026.2015
    [38] Edwardson C, Winkler E, Bodicoat D, et al. (2016) Considerations when using the activPAL monitor in field based research with adult populations. J Sport Health Sci In Press.
    [39] Esliger DW, Rowlands AV, Hurst TL, et al. (2011) Validation of the GENEA Accelerometer. Med Sci Sports Exerc 43: 1085-1093. doi: 10.1249/MSS.0b013e31820513be
    [40] Rowlands AV, Yates T, Olds TS, et al. (2016) Sedentary Sphere: Wrist-Worn Accelerometer-Brand Independent Posture Classification. Med Sci Sports Exerc 48: 748-754.
    [41] Pavey TG, Gomersall SR, Clark BK, et al. (2016) The validity of the GENEActiv wrist-worn accelerometer for measuring adult sedentary time in free living. J Sci Med Sport 19: 395-399.
    [42] Troiano RP, McClain JJ, Brychta RJ, et al. (2014) Evolution of accelerometer methods for physical activity research. Br J Sports Med 48: 1019-1023. doi: 10.1136/bjsports-2014-093546
    [43] Orme M, Wijndaele K, Sharp SJ, et al. (2014) Combined influence of epoch length, cut-point and bout duration on accelerometry-derived physical activity. Int J Behav Nutr Phys Act 11: 34. doi: 10.1186/1479-5868-11-34
    [44] Ayabe M, Kumahara H, Morimura K, et al. (2013) Epoch length and the physical activity bout analysis: an accelerometry research issue. BMC Res Notes 6: 20. doi: 10.1186/1756-0500-6-20
    [45] John D, Sasaki J, Staudenmayer J, et al. (2013) Comparison of raw acceleration from the GENEA and ActiGraph GT3X+ activity monitors. Sensors 13: 14754-14763. doi: 10.3390/s131114754

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    30. Joana Chong, Petra Tjurin, Maisa Niemelä, Timo Jämsä, Vahid Farrahi, Machine-learning models for activity class prediction: A comparative study of feature selection and classification algorithms, 2021, 89, 09666362, 45, 10.1016/j.gaitpost.2021.06.017
    31. Sonia W.M. Cheng, Jennifer A. Alison, Emmanuel Stamatakis, Sarah M. Dennis, Zoe J. McKeough, Validity and Accuracy of Step Count as an Indicator of a Sedentary Lifestyle in People With Chronic Obstructive Pulmonary Disease, 2023, 00039993, 10.1016/j.apmr.2023.01.020
    32. Mary C. Hidde, Kate Lyden, Kim Henry, Heather J. Leach, Reallocating Time to Physical Activity and Sleep: Associations with Body Mass Index in Cancer Survivors, 2023, 1070-5503, 10.1007/s12529-023-10152-7
    33. Mary C. Hidde, Mary E. Crisafio, Emma Gomes, Kate Lyden, Heather J. Leach, An Evaluation of Participant Perspectives and Wear-Time Compliance for a Wrist-Worn Versus Thigh-Worn Accelerometer in Cancer Survivors, 2023, 20, 1543-3080, 129, 10.1123/jpah.2022-0346
    34. Alexander H.K. Montoye, Bradford S. Westgate, Kimberly A. Clevenger, Karin A. Pfeiffer, Joseph D. Vondrasek, Morgan R. Fonley, Joshua M. Bock, Leonard A. Kaminsky, Individual versus Group Calibration of Machine Learning Models for Physical Activity Assessment Using Body-Worn Accelerometers, 2021, Publish Ahead of Print, 0195-9131, 10.1249/MSS.0000000000002752
    35. Ayda Karaca, Necip Demirci, Vedat Yılmaz, Sinem Hazır Aytar, Sema Can, Evrim Ünver, Validation of the ActiGraph wGT3X-BT Accelerometer for Step Counts at Five Different Body Locations in Laboratory Settings, 2022, 26, 1091-367X, 63, 10.1080/1091367X.2021.1948414
    36. Aleksandra Makarewicz, Małgorzata Jamka, Maria Wasiewicz-Gajdzis, Joanna Bajerska, Anna Miśkiewicz-Chotnicka, Jarosław Kwiecień, Aleksandra Lisowska, Dominque Gagnon, Karl-Heinz Herzig, Edyta Mądry, Jarosław Walkowiak, Comparison of Subjective and Objective Methods to Measure the Physical Activity of Non-Depressed Middle-Aged Healthy Subjects with Normal Cognitive Function and Mild Cognitive Impairment—A Cross-Sectional Study, 2021, 18, 1660-4601, 8042, 10.3390/ijerph18158042
    37. Shu Ning Ch’ng, Joanne A. McVeigh, David Manners, Terry Boyle, Carolyn J. Peddle-McIntyre, Rajesh Thomas, Jeanie Leong, Samantha Bowyer, Kirsten Mooney, Leon Straker, Daniel A. Galvão, Vinicius Cavalheri, Sedentary Behaviour, Physical Activity, and Their Associations with Health Outcomes at the Time of Diagnosis in People with Inoperable Lung Cancer, 2022, 11, 2077-0383, 5870, 10.3390/jcm11195870
    38. Fangyu Liu, Amal A Wanigatunga, Jennifer A Schrack, Assessment of Physical Activity in Adults Using Wrist Accelerometers, 2021, 43, 1478-6729, 65, 10.1093/epirev/mxab004
    39. Riccardo Femiano, Charlotte Werner, Matthias Wilhelm, Prisca Eser, Validation of open-source step-counting algorithms for wrist-worn tri-axial accelerometers in cardiovascular patients, 2022, 92, 09666362, 206, 10.1016/j.gaitpost.2021.11.035
    40. Matthew C. Ruder, Roger Zauel, Brian J. Diefenbach, Michael J. Bey, Quantifying shoulder activity after rotator cuff repair: Technique and preliminary results, 2022, 40, 0736-0266, 917, 10.1002/jor.25122
    41. MIKAEL ANNE GREENWOOD-HICKMAN, SUPUN NAKANDALA, MARTA M. JANKOWSKA, DORI E. ROSENBERG, FATIMA TUZ-ZAHRA, JOHN BELLETTIERE, JORDAN CARLSON, PAUL R. HIBBING, JINGJING ZOU, ANDREA Z. LACROIX, ARUN KUMAR, LOKI NATARAJAN, The CNN Hip Accelerometer Posture (CHAP) Method for Classifying Sitting Patterns from Hip Accelerometers: A Validation Study, 2021, 53, 1530-0315, 2445, 10.1249/MSS.0000000000002705
    42. Thomas D. Griffiths, Diane Crone, Mike Stembridge, Rachel N. Lord, Co-Production at Work: The Process of Breaking Up Sitting Time to Improve Cardiovascular Health. A Pilot Study, 2021, 19, 1660-4601, 361, 10.3390/ijerph19010361
    43. Willie Leung, Layne Case, Ming-Chih Sung, Jaehun Jung, A meta-analysis of Fitbit devices: same company, different models, different validity evidence, 2022, 46, 0309-1902, 102, 10.1080/03091902.2021.2006350
    44. Charlotte L Edwardson, Benjamin D Maylor, Nathan P Dawkins, Tatiana Plekhanova, Alex V Rowlands, Comparability of Postural and Physical Activity Metrics from Different Accelerometer Brands Worn on the Thigh: Data Harmonization Possibilities, 2022, 26, 1091-367X, 39, 10.1080/1091367X.2021.1944154
    45. Mikael Anne Greenwood-Hickman, Jing Zhou, Andrea Cook, Kayne D. Mettert, Bev Green, Jennifer McClure, David Arterburn, Stefani Florez-Acevedo, Dori E. Rosenberg, Exploring Differences in Older Adult Accelerometer-Measured Sedentary Behavior and Resting Blood Pressure Before and During the COVID-19 Pandemic, 2022, 8, 2333-7214, 233372142210960, 10.1177/23337214221096007
    46. Alexander H.K. Montoye, Olivia Coolman, Amberly Keyes, Megan Ready, Jaedyn Shelton, Ethan Willett, Brian C. Rider, Evaluation of Two Thigh-Worn Accelerometer Brands in Laboratory and Free-Living Settings, 2022, 5, 2575-6605, 233, 10.1123/jmpb.2022-0012
    47. Karin A Pfeiffer, Kimberly A Clevenger, Andrew Kaplan, Cailyn A Van Camp, Scott J Strath, Alexander H K Montoye, Accessibility and use of novel methods for predicting physical activity and energy expenditure using accelerometry: a scoping review, 2022, 43, 0967-3334, 09TR01, 10.1088/1361-6579/ac89ca
    48. James D. Amor, Christopher J. James, Validation of a Commercial Android Smartwatch as an Activity Monitoring Platform, 2018, 22, 2168-2194, 968, 10.1109/JBHI.2017.2732678
    49. Nolan Gall, Ruopeng Sun, Matthew Smuck, A Comparison of Wrist- Versus Hip-Worn ActiGraph Sensors for Assessing Physical Activity in Adults: A Systematic Review, 2022, 5, 2575-6605, 252, 10.1123/jmpb.2021-0045
    50. Thomas Bilterys, Eveline Van Looveren, Olivier Mairesse, Jo Nijs, Mira Meeus, Kelly Ickmans, Barbara Cagnie, Dorien Goubert, Ward Willaert, Robby De Pauw, Lieven Danneels, Maarten Moens, Anneleen Malfliet, Predictors for physical activity and its change after active physical therapy in people with spinal pain and insomnia: Secondary analysis of a randomized controlled trial, 2022, 26, 14133555, 100456, 10.1016/j.bjpt.2022.100456
    51. Xiaoping Zheng, Michiel F Reneman, Rita HR Schiphorst Preuper, Egbert Otten, Claudine JC Lamoth, Relationship between physical activity and central sensitization in chronic low back pain: Insights from machine learning, 2023, 232, 01692607, 107432, 10.1016/j.cmpb.2023.107432
    52. Anne-Christine Auge, Gabriel Blouin-Demers, Dennis L. Murray, William David Halliday, Developing a classification system to assign activity states to two species of freshwater turtles, 2022, 17, 1932-6203, e0277491, 10.1371/journal.pone.0277491
    53. Mayara S. Bianchim, Melitta A. McNarry, Rachel Evans, Lena Thia, Alan R. Barker, Craig A. Williams, Sarah Denford, Kelly A Mackintosh, Calibration and Cross-validation of Accelerometry in Children and Adolescents with Cystic Fibrosis, 2023, 27, 1091-367X, 51, 10.1080/1091367X.2022.2065919
    54. Vincenza Gianfredi, Pietro Ferrara, Flavia Pennisi, Giulia Casu, Andrea Amerio, Anna Odone, Daniele Nucci, Monica Dinu, Association between Daily Pattern of Physical Activity and Depression: A Systematic Review, 2022, 19, 1660-4601, 6505, 10.3390/ijerph19116505
    55. Zeynep S. Akinci, Oriol Marquet, Xavier Delclòs-Alió, Carme Miralles-Guasch, Urban vitality and seniors’ outdoor rest time in Barcelona, 2022, 98, 09666923, 103241, 10.1016/j.jtrangeo.2021.103241
    56. Duncan S Buchan, Benjamin D Maylor, Comparison of physical activity metrics from two research-grade accelerometers worn on the non-dominant wrist and thigh in children, 2023, 0264-0414, 1, 10.1080/02640414.2023.2197726
    57. John P. Rech, Priyanka Chaudhary, Michaela Schenkelberg, Danae Dinkel, A Convergent Mixed Methods Study to Explore Physical Activity Among Teachers and Children During the Preschool Day, 2023, 1082-3301, 10.1007/s10643-023-01486-8
    58. Naureen Akber Ali Meghani, Joanne Hudson, Gareth Stratton, Jane Mullins, Deepak Sahoo, A multi-method feasibility trial of a multi-component behaviour change intervention to reduce sedentary behaviour and increase physical activity among ethnically diverse older adults, 2024, 14, 2044-6055, e084645, 10.1136/bmjopen-2024-084645
    59. Avirup Roy, Hrishikesh Dutta, Amit Kumar Bhuyan, Subir Biswas, On-Device Semi-Supervised Activity Detection: A New Privacy-Aware Personalized Health Monitoring Approach, 2024, 24, 1424-8220, 4444, 10.3390/s24144444
    60. Guilherme Moraes Balbim, Ryan S Falck, Nárlon Cássio Boa Sorte Silva, Arthur F Kramer, Michelle Voss, Teresa Liu-Ambrose, Lewis A Lipsitz, The Association of the 24-Hour Activity Cycle Profiles With Cognition in Older Adults With Mild Cognitive Impairment: A Cross-Sectional Study, 2024, 79, 1079-5006, 10.1093/gerona/glae099
    61. Udeni Jayasinghe, Faustina Hwang, William S. Harwin, Inertial measurement data from loose clothing worn on the lower body during everyday activities, 2023, 10, 2052-4463, 10.1038/s41597-023-02567-4
    62. Benjamin D. Maylor, Charlotte L. Edwardson, Alexandra M. Clarke-Cornwell, Melanie J. Davies, Nathan P. Dawkins, David W. Dunstan, Kamlesh Khunti, Tom Yates, Alex V. Rowlands, Physical Activity Assessed by Wrist and Thigh Worn Accelerometry and Associations with Cardiometabolic Health, 2023, 23, 1424-8220, 7353, 10.3390/s23177353
    63. Zhi Cao, Jiahao Min, Yabing Hou, Keyi Si, Mingwei Wang, Chenjie Xu, Association of accelerometer-derived physical activity with all-cause and cause-specific mortality among individuals with cardiovascular diseases: a prospective cohort study, 2024, 2047-4873, 10.1093/eurjpc/zwae248
    64. Li‐Tang Tsai, Eleanor Boyle, Sussi F Buhl, Gry Kock, Jan C Brønd, Marjolein Visser, Nuno Mendonça, Eric J Shiroma, Paolo Caserotti, Associations between appetite, physical activity and sedentary behaviour from hip‐ and wrist‐worn accelerometers in community‐dwelling older adults, 2023, 23, 1444-1586, 411, 10.1111/ggi.14588
    65. Priyanka Chaudhary, John P Rech, Gaurav Kumar, Danae Dinkel, Perceived barriers and facilitators of childcare providers’ physical activity: A mixed-methods study, 2024, 83, 0017-8969, 137, 10.1177/00178969231222543
    66. Inge de Wolf, Anne Elevelt, Femke van Nassau, Vera Toepoel, Ellen de Hollander, Maaike E. Kompier, Annemieke Luiten, Barry Schouten, G. C. Wanda Wendel-Vos, Hidde P. van der Ploeg, Comparing national device-based physical activity surveillance systems: a systematic review, 2024, 21, 1479-5868, 10.1186/s12966-024-01612-8
    67. Kirkke Reisberg, Eva-Maria Riso, Liina Animägi, Jaak Jürimäe, Longitudinal Relationships of Physical Activity, Sedentary Time, Cardiorespiratory Fitness, and Muscular Fitness with Body Fatness in Preschoolers, 2024, 12, 2075-4663, 237, 10.3390/sports12090237
    68. Kyle R. Leister, Sara E. Burke, Joon Young Kim, Victor H. Duenas, Tiago V. Barreira, Comparison of daily step count between the Fitbit Inspire 3 and the activPAL 3 in adults with transtibial amputation, 2024, 5, 2673-6861, 10.3389/fresc.2024.1331005
    69. Iris Parés-Salomón, Anna M. Señé-Mir, Fernando Martín-Bozas, Bette Loef, Alan Coffey, Kieran P. Dowd, Guillem Jabardo-Camprubí, Karin I. Proper, Anna Puig-Ribera, Judit Bort-Roig, Effectiveness of workplace interventions with digital elements to reduce sedentary behaviours in office employees: a systematic review and meta-analysis, 2024, 21, 1479-5868, 10.1186/s12966-024-01595-6
    70. Taylor McCoy, Anthony J. Sochan, Andrea M. Spaeth, The Relationship between Sleep and Physical Activity by Age, Race, and Gender, 2024, 25, 1530-6550, 10.31083/j.rcm2510378
    71. Franziska Beck, Isabel Marzi, Alina Eisenreich, Selina Seemüller, Clara Tristram, Anne K. Reimers, Determination of cut-off points for the Move4 accelerometer in children aged 8–13 years, 2023, 15, 2052-1847, 10.1186/s13102-023-00775-4
    72. S.A. Pomeshkina, E.A. Demchenko, Methods of sedentary lifestyle study: possibilities and limitations, 2024, 27, 2305-4948, 97, 10.17116/profmed20242705197
    73. Agus Salim, Christian J. Brakenridge, Dulari Hakamuwa Lekamlage, Erin Howden, Ruth Grigg, Hayley T. Dillon, Howard D. Bondell, Julie A. Simpson, Genevieve N. Healy, Neville Owen, David W. Dunstan, Elisabeth A. H. Winkler, Detection of sedentary time and bouts using consumer-grade wrist-worn devices: a hidden semi-Markov model, 2024, 24, 1471-2288, 10.1186/s12874-024-02311-5
    74. Andrea Weber, Daniela Schmid, Michael F. Leitzmann, 2023, Chapter 67-1, 978-1-4614-6625-3, 1, 10.1007/978-1-4614-6625-3_67-1
    75. S. M. J. Janssen, M. A. Spruit, R. S. Djamin, J. C. C. M in ‘t Veen, H. A. C. van Helvoort, A. J. van ‘t Hul, Reliability of 24-h measurement of physical activity, sleep, and sedentary time in adult patients with asthma using a triaxial accelerometer, 2024, 0277-0903, 1, 10.1080/02770903.2024.2420758
    76. Amie Wallman-Jones, Carina Nigg, Valentin Benzing, Mirko Schmidt, Leave the screen: The influence of everyday behaviors on self-reported interoception, 2023, 181, 03010511, 108600, 10.1016/j.biopsycho.2023.108600
    77. Elyse Letts, Josephine S Jakubowski, Sara King-Dowling, Kimberly Clevenger, Dylan Kobsar, Joyce Obeid, Accelerometer techniques for capturing human movement validated against direct observation: a scoping review, 2024, 45, 0967-3334, 07TR01, 10.1088/1361-6579/ad45aa
    78. Songtao Lu, Jun Sun, Zhiguang Guo, Mingyu Yi, Yuheng Zhang, Jiali Wang, Yue Wang, Instrumented measures of sedentary behavior and physical activity are associated with depression among children and adolescents: a systematic review and dose–response meta-analysis of observational studies, 2024, 15, 1664-1078, 10.3389/fpsyg.2024.1465974
    79. Anis Davoudi, Jacek K. Urbanek, Lacey Etzkorn, Romil Parikh, Elsayed Z. Soliman, Amal A. Wanigatunga, Kelley Pettee Gabriel, Josef Coresh, Jennifer A. Schrack, Lin Yee Chen, Validation of a Zio XT Patch Accelerometer for the Objective Assessment of Physical Activity in the Atherosclerosis Risk in Communities (ARIC) Study, 2024, 24, 1424-8220, 761, 10.3390/s24030761
    80. Arto J. Pesola, Samad Esmaeilzadeh, Pirjo Hakala, Nina Kallio, Päivi Berg, Marko Havu, Tiina Rinne, Sensitivity and specificity of measuring children's free-living cycling with a thigh-worn Fibion® accelerometer, 2023, 5, 2624-9367, 10.3389/fspor.2023.1113687
    81. Johan Y. Y. Ng, Joni H. Zhang, Stanley S. Hui, Guanxian Jiang, Fung Yau, James Cheng, Amy S. Ha, Yaodong Gu, Development of a multi-wear-site, deep learning-based physical activity intensity classification algorithm using raw acceleration data, 2024, 19, 1932-6203, e0299295, 10.1371/journal.pone.0299295
    82. Julie Riopel-Meunier, Paul Poirier, Jean-Pierre Després, Marie-Eve Piché, Is the time right for preventive cardiology guidelines on sedentary behaviors and sitting time?, 2024, 0828282X, 10.1016/j.cjca.2024.12.024
    83. Kimberly A. Clevenger, Melitta A. McNarry, Kelly A. Mackintosh, Karin A. Pfeiffer, M. Benjamin Nelson, Joshua M. Bock, Mary T. Imboden, Leonard A. Kaminsky, Alexander H.K. Montoye, A Consensus Method for Estimating Moderate to Vigorous Physical Activity Levels in Adults Using Wrist-Worn Accelerometers, 2024, 7, 2575-6605, 10.1123/jmpb.2024-0013
    84. Brandon D. Willingham, Marcos Daou, Jake VanArsdale, Meghan Thomas, Patrick G. Saracino, Energy Availability in Female Collegiate Beach Volleyball Athletes, 2024, 1064-8011, 10.1519/JSC.0000000000004884
    85. Dawei Wang, Yuheng Zhang, Zhiguang Guo, Songtao Lu, Sedentary behavior and physical activity are associated with risk of depression among adult and older populations: a systematic review and dose–response meta-analysis, 2025, 16, 1664-1078, 10.3389/fpsyg.2025.1542340
    86. Barbara Engels, Manon A. T. Bloemen, Richard Felius, Karlijn Damen, Eline A. M. Bolster, Harriët Wittink, Raoul H. H. Engelbert, Jan Willem Gorter, Monitoring of child-specific activities in ambulatory children with and without developmental disabilities, 2025, 25, 1471-2431, 10.1186/s12887-025-05489-9
    87. Arto J. Pesola, Marko Havu, Automated Algorithm for Accurate Waking Sitting and Physical Activity Estimates Without Diaries Using Thigh-Worn Fibion Accelerometers in 10- to 12-Year-Old Children, 2025, 8, 2575-6605, 10.1123/jmpb.2024-0022
    88. Reagan E. Garcia, Anne B. Newman, Eileen Johnson, Yujia Susanna Qiao, Peggy M. Cawthon, Barbara J. Nicklas, Bret H. Goodpaster, Nancy W. Glynn, Using Wearable Devices to Examine the Associations of Sedentary Behavior with Perceived and Performance Fatigability Among Older Adults: The Study of Muscle, Mobility and Aging (SOMMA), 2025, 25, 1424-8220, 2722, 10.3390/s25092722
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