Hostname: page-component-76fb5796d-vvkck Total loading time: 0 Render date: 2024-04-26T10:26:07.246Z Has data issue: false hasContentIssue false
  • English
  • Français

Development of the systematic observation of COVID-19 mitigation (SOCOM): Assessing face covering and distancing in schools

Published online by Cambridge University Press:  30 April 2021

Ricky Camplain ,
Nanette V. Lopez ,
Dan M. Cooper ,
Thomas L. McKenzie ,
Kai Zheng  and
Shlomit Radom-Aizik
Ricky Camplain*
Affiliation:
Center for Health Equity Research, Northern Arizona University, Flagstaff, AZ, USA Department of Health Sciences, Northern Arizona University, Flagstaff, AZ, USA
Nanette V. Lopez
Affiliation:
Department of Health Sciences, Northern Arizona University, Flagstaff, AZ, USA
Dan M. Cooper
Affiliation:
Institute for Clinical and Translational Science, University of California Irvine, School of Medicine, Irvine, CA, USA
Thomas L. McKenzie
Affiliation:
School of Exercise and Nutritional Sciences, San Diego State University, San Diego, CA, USA
Kai Zheng
Affiliation:
Institute for Clinical and Translational Science, University of California Irvine, School of Medicine, Irvine, CA, USA Department of Informatics, University of California, Irvine, Irvine, CA, USA
Shlomit Radom-Aizik
Affiliation:
Pediatric Exercise and Genomics Research Center, Department of Pediatrics, University of California Irvine, School of Medicine, Irvine, CA, USA
*
Address for correspondence: R. Camplain, PhD, PO Box 4065, Northern Arizona University, Flagstaff, AZ86011-4065, USA. Email: ricky.camplain@nau.edu, Phone: 928-523-5165.
Rights & Permissions [Opens in a new window]

Abstract

Introduction:

During the COVID-19 pandemic, some K-12 schools resumed in-person classes with varying degrees of mitigation plans in the fall 2020. Physical distancing and face coverings can minimize SARS-CoV-2 spread, the virus that causes COVID-19. However, no research has focused on adherence to mitigation strategies during school days. Thus, we sought to develop a systematic observation protocol to capture COVID-19 mitigation strategy adherence in school environments: The Systematic Observation of COVID-19 Mitigation (SOCOM).

Methods:

We extended previously validated and internationally used tools to develop the SOCOM training and implementation protocols to assess physical-distancing and face-covering behaviors. SOCOM was tested in diverse indoor and outdoor settings (classrooms, lunchrooms, physical education [PE], and recess) among diverse schools (elementary, secondary, and special needs).

Results:

For the unique metrics of physical-distancing and face-covering behaviors, areas with less activity and a maximum of 10–15 students were more favorable for accurately capturing data. Overall proportion of agreement was high for physical distancing (90.9%), face covering (88.6%), activity type (89.2%), and physical activity level (87.9%). Agreement was lowest during active recess, PE, and observation areas with ≥20 students.

Conclusions:

Millions of children throughout the USA are likely to return to school in the months ahead. SOCOM is a relatively inexpensive research tool that can be implemented by schools to determine mitigation strategy adherence and to assess protocols that allow students return to school safely and slow the spread of COVID-19.

Keywords

SARS-CoV-2pediatricschooldirect observationprevention
Type
Research Article
Information
Journal of Clinical and Translational Science , Volume 5 , Issue 1 , 2021 , e124
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of The Association for Clinical and Translational Science

Introduction

The impact of the coronavirus disease 2019 (COVID-19), caused by the novel coronavirus, severe acute respiratory syndrome coronavirus 2 (SARS-Cov-2), has been widespread, with 30 million cases diagnosed and over 550,000 deaths in the USA as of March 31, 2021. When COVID-19 was declared a pandemic, schools were among the first operations to close to prevent community spread. However, in the fall of 2020, 56 million school-aged children (5–17 years of age) resumed education as some schools opened to in-person classes with varying public health mitigation plans [Reference Leeb, Price and Sliwa1]. Children and adolescents comprise asymptomatic, symptomatic, and hospitalized populations of SARS-CoV-2-infected individuals and their capability of spreading disease to school staff and family has yet to be resolved [Reference Yonker, Neilan and Bartsch2Reference Levin, Choyke, Georgiou, Sen and Karaca-Mandic5]. However, mitigation procedures can minimize SARS-CoV-2 outbreaks even in the close quarters of overnight summer camps [Reference Pray, Gibbons-Burgener and Rosenberg6].

Viral aerosolization can occur due to the general social and physically interactive nature of school-aged children during classroom learning, communal dining, recess, and physical education (PE) classes. Comprehensive return-to-school plans emphasize adherence to accepted SARS-CoV-2 viral mitigation strategies procedures, including physical distancing (staying at least 6 feet from others who are not from the same household) and face cover wearing [Reference Rothe, Schunk and Sothmann7Reference Leung, Chu and Shiu9]. Specifically, new guidelines released by the Centers for Disease Control and Prevention highlight the need to promote behaviors that reduce COVID-19’s spread, including maintaining healthy environments and operations, and preparing for when someone gets sick [10]. Recognizing mitigation strategies represent unnatural behaviors for K-12 students, attention has been focused on strategies to implement and operationalize mitigation protocols in schools. Little emphasis has been given to how to quantify adherence. Without adherence metrics, effectiveness of SARS-CoV-2 transmission mitigation procedures cannot be ascertained.

Existing instruments for quantifying health behaviors could be applied to assess the fidelity of COVID-19 mitigation. These include self-report [Reference Sallis11], wearable technologies [Reference Hafezi, Robertson, Moon, Au-Yeung, Zdeblick and Savage12Reference Turner-McGrievy, Wilcox and Boutté17], and direct observation by trained personnel [Reference Howe, Clevenger, Plow, Porter and Sinha18Reference Evenson, Jones, Holliday, Cohen and McKenzie21]. Self-reports of daily living (e.g., physical activity (PA) or diet) by children and adolescents are highly inaccurate [Reference Howe, Clevenger, Plow, Porter and Sinha18Reference Evenson, Jones, Holliday, Cohen and McKenzie21]. Wearable technologies (accelerometers) are increasingly used to gauge PA and sedentary behavior in children [Reference Sanders, Cliff and Lonsdale22,Reference Van Coevering, Harnack, Schmitz, Fulton, Galuska and Gao23], but necessary technological advances are not designed to assess physical-distancing or face-covering behaviors [Reference Logan, Duncan, Harris, Hinckson and Schofield24Reference Zhu, Wang, Huang and Ding26]. Moreover, the use of cell phone- or GPS-monitoring in school-aged children and adolescents raises questions of health data privacy [Reference Teipel, König and Hoey27], embodied in FERPA and HIPAA regulations.

Direct observation approaches developed to assess levels of PA in a variety of real-world environments were readily adapted to measure COVID-19 mitigation strategies in K-12 schools. The original System for Observing Play and Leisure Activity in Youth (SOPLAY), designed for PA settings in schools, and the System for Observing Play and Recreation in Communities (SOPARC), designed to include playgrounds and parks, were designed to obtain direct information on PA in open spaces [Reference McKenzie, Marshall, Sallis and Conway20,Reference McKenzie, Cohen, Sehgal, Williamson and Golinelli28]. SOPLAY and SOPARC are based on momentary time sampling techniques in which systematic and periodic scans of individuals and contextual factors in PA environments are made and they have been adapted for multiple settings [Reference Evenson, Jones, Holliday, Cohen and McKenzie21]. Given SOPARC’s proven ability to obtain reliable observational data, we sought to test a new strategy of using systematic observation to capture COVID-19 mitigation strategy adherence, including physical distancing and face coverings, among grade-school-aged children in diverse school settings: The Systematic Observation of COVID-19 Mitigation (SOCOM).

Materials and Methods

Study Setting

Four schools in Orange County, California, were recruited to participate in a Safe School Restart study to begin essential research on COVID-19 transmission in children and adolescents. The aim of Safe School Restart was to determine how effectively state and regional guidelines slowed viral transmission as schools restarted. Private schools across the country have been able to expend the resources necessary to develop and implement effective mitigation strategies. Public schools, particularly Title 1 public schools, have had greater difficulty in accessing necessary resources [Reference Masonbrink and Hurley29,Reference Cullinane and Montacute30]. Consequently, our study includes four representative schools in Orange County, California:

  1. 1. Private K-12 school serving predominantly middle- and upper-middle socioeconomic status (SES) students.

  2. 2. K-6 public school serving predominantly Latino, lower SES students.

  3. 3. K-8 public charter school located in a predominantly Latino, lower SES neighborhood.

  4. 4. K-6 public charter school serving predominantly children with special needs, including down syndrome, autism spectrum disorders, etc.

The participating schools had varying levels of COVID-19 plans that were made in effort to meet the CDC guidelines that were in place during the study period. Plans included thoughtful and thorough screening, mask wearing, social distancing, hand hygiene, guest visitations, and testing procedures. All schools had some level of in-person learning with three schools permitting only a small proportion of students to attend in-person.

SOCOM was designed to observe during four distinct school day sessions: classroom learning, active recess (regularly scheduled periods for PA and play that was monitored by trained staff or volunteers), instructional PE classes, and communal dining (lunch).

Partnerships with Schools

Schools were selected for Safe School Restart to reflect the wide range of SES, ethnic diversity, and school layouts and facilities that exist within Orange County, California, allowing for a determination of the viability of the SOCOM tool in different settings (Table 1). Building on previous relationships, the schools were approached as colleagues and partners, an approach that facilitated approvals for the study by schools and school districts. Great care was taken to plan with school staff, so elements of the study were clear, acceptable, and followed current school policies established in response to the COVID-19 pandemic.

Table 1. Characteristics within observed schools

SOCOM Development

In the summer of 2020, the SOCOM protocol was developed to focus on assessing COVID-19 mitigation procedures (physical-distancing and face-covering behaviors). Paper and electronic observation forms were developed to capture data (Figs. 1 and 2). The custom electronic data capture system optimized for mobile devices was developed by the Center for Biomedical Informatics, UC Irvine Institute for Clinical and Translational Science. The platform leverages the Bootstrap responsive user interface framework and was programmed in ASP.Net C#. In addition to the SOPARC-based data fields that research coordinators can enter manually based on their field observations, the system is also capable of obtaining local weather information automatically through an application programming interface (API) provided by openweathermap.org. All data captured are stored in a HIPAA-compatible environment hosted at the Enterprise Data Center of the UCI Health.

Fig. 1. Sample Systematic Observation of COVID-19 Mitigation (SOCOM) Electronic Data Collection Form.

Fig. 2. Sample Systematic Observation of COVID-19 Mitigation (SOCOM) Paper Data Collection Form.

Measures

Primary measures included physical-distancing, face-covering behavior, PA levels, and activity type (Table 2). In addition, observed individuals were categorized into sex/age groups (female students, male students, female adults, and male adults). Data were recorded to identify specific observation target area, date, grades in attendance, time of observation, and weather conditions.

Table 2. Systematic observation of COVID-19 mitigation (SOCOM) central measures

Training

In preparation for SOCOM, observers (research assistants from the University of California, Irvine’s Pediatric Exercise and Genomics Research Center) studied the written protocol and participated in a 4-hour workshop. Original written and video SOPARC training materials were used during the workshop (https://activelivingresearch.org/soparc-system-observing-play-and-recreation-communities). Training included reviewing definitions and coding conventions, differentiating among codes, coding practice, and orientation to the observation tools. Observer preparation also included target area mapping strategies. Coding conventions and how to differentiate among various PA levels included video lectures and practice with feedback from videotaped samples through original SOPARC training. Distinguishing between face coverings, physical distancing, and activity type definitions was taught using photographs and videos. Observers practiced coding and received feedback on their scoring before engaging in field practice.

Observation Preparation

Maps of school grounds from Google Maps or school administrators were used to precisely identify outdoor target areas, spaces in which activities might occur and were small enough to accurately code people using them. The size, location, and boundaries for both indoor and outdoor target areas were identified and the sequential order for observing them established.

As COVID-19 recommendations and restrictions varied among schools and time periods, visiting them was imperative before finalizing school-specific observation protocols and visitation days. Administrative-level school officials escorted observers around the school to note the general layout and major features of the facilities and to specifically identify potential target areas for observation.

Before official data collection began, all observers attended a field-based training at one of the schools using the developed protocol and data collection form to practice using the protocol and form. Observers used the schedule of observations like that for official observations but were able to discuss protocols and category classifications.

Recording Procedures

To establish reliability during visits to target areas, two to three observers simultaneously completed observations either by using paper forms or individual cell phones (Figs. 1 and 2). Timestamps and weather information were uploaded automatically into the electronic form.

After recording the characteristics of a target area, the observers simultaneously completed area scans by making independent “visual sweeps” from left to right using the same pace. Separate scans were conducted for female students, male students, female adults, and male adults, and each characteristic (physical distancing, face covering, PA, and activity type) for a maximum of 16 scans per target area. For example, during the first scan for female students, observers recorded whether each was physically distanced, not physically distanced, or unknown. During the second scan, observers recorded data for each female student’s face covering. For PE classes and active recesses, a third scan was performed to record the PA level of each female student as sedentary, walking, or vigorous. Finally, for female students, a scan was made to categorize each as being interactive or individual. This scanning procedure was then completed for male students, female adults, and male adults in the target area (if any). Observers then moved to the next target area. Occasionally (e.g., unusual large numbers of people in the area), target areas were subdivided into smaller sub-areas so more accurate measures could be obtained and data for these sub-areas were later summed to provide an overall measure. During groups of scans, observers also took qualitative notes on contextual information. When needed, observers used paper observation forms and later entered the information into the electronic data format.

Weekly meetings were conducted with observers and research team to discuss challenges experienced during observations and to review the study protocol.

Planned Data Analysis

For physical-distancing, face-covering behavior, PA level, and activity type, counts will be tallied for those engaged in each group in each school and observation area to obtain a summary score for female students, male students, female adults, and male adults. A proportion of individuals in each physical-distancing scenario, face-covering behavior, PA level, and activity type will be calculated by age/sex group.

Results

Observations

During a school visit, observation times varied by the number of target areas and people present and ranged from 2 min (in classrooms) to 15 min (in dining rooms). Communal areas generally had more people and more target areas and more scans were required. When large numbers of people were present (>20), some observers preferred the paper entry format compared to the electronic form as they could code more easily. Thus, areas with less activity and target areas with a maximum of 10–15 students were more favorable for accurately and confidently capturing data.

The presence of observers may have influenced staff and student behavior, especially indoors. Schools had restrictions on visitors due to COVID-19 protocols and teachers sometimes inquired why observers were there. Meanwhile, when students were more physically active (e.g., PE classes) observers typically went unnoticed.

Reliability

Reliability data for PA, physical-distancing, and face-covering behaviors were collected during all observation periods using two assessors who made simultaneous, independent observations. The overall proportion of agreement from 166 scans was calculated for each variable (face covering, 88.6%; physical distancing, 90.9%; and activity type, 89.2%). When assessed by observation area, agreement was lowest during active recess and PE classes (79.7% to 99.1%). Agreement was lower when there were ≥20 students present (80.2%) compared to <20 students (90.2%). Reliability for PA level calculated for 34 observations (collected during active recess and PE classes) showed the proportion of agreement was 87.9%, similar to previous reliability studies using SOPARC [Reference McKenzie, Cohen, Sehgal, Williamson and Golinelli28].

Preliminary Results

The SOCOM activity codes had been used in other observation systems [Reference McKenzie, Marshall, Sallis and Conway20,Reference McKenzie, Sallis and Nader31,Reference McKenzie, Sallis and Nader32], and with their construct validity being established via heart rate monitoring among 4- to 18-years-old children [Reference McKenzie, Sallis and Nader31,Reference Rowe, van Der Mars, Schuldheisz and Fox33] and with accelerometers in schools [Reference Scruggs, Beveridge, Eisenman, Watson, Shultz and Ransdell34]. Subsequently, we were able to compare PA results to previous studies.

During recess in the three schools that provided recess, 25.8% of students were sedentary, 21.5% walked, and 52.8% engaged in vigorous activity. The proportion of students engaged in walking or vigorous activity (74.2%) was higher than those in previous studies (51–68%) [Reference McKenzie, Marshall, Sallis and Conway20]. Overall during PE classes, 38.6% of students were sedentary, 25.0% were walking, and 36.4% were engaged in vigorous activity. Meanwhile, the PE class program differed substantially by school as did the resulting activity levels. Students in the K-6 special needs public charter school had PE within their classrooms and subsequently a high proportion of them were sedentary (87.5%) as students were still in the classroom. In the private and public schools providing formal PE classes, 34% of students were sedentary.

Additional preliminary data on mitigation using SOCOM linked to SARS-CoV-2 infection in the four schools are also available [Reference Cooper, Aizik and Camplain35].

Discussion

Systematic observation has been widely used in collecting information on children’s and adolescents’ behaviors [Reference McKenzie, Marshall, Sallis and Conway20,Reference Evenson, Jones, Holliday, Cohen and McKenzie21,Reference McKenzie, Cohen, Sehgal, Williamson and Golinelli28,Reference McKenzie, Sallis and Nader31]. Therefore, we sought to test a new strategy of using systematic observation to capture COVID-19 mitigation strategy adherence, including physical distancing and face coverings, among grade-school-aged children in the school environment. SOCOM may serve as a reliable and useful tool in assessing COVID-19 mitigation procedures in schools.

To safely plan for in-person learning, K-12 schools must understand mitigation strategy adherence among their students and staff. Because physical-distancing and face-covering behaviors are two recognized methods to prevent the spread of COVID-19 [Reference MacIntyre and Wang36], real-time response to poor adherence is an important component of safely re-opening and keeping K-12 schools open for in-person learning.

Following data collection, a verbal summary of the results was provided to each school and formal presentations of the findings and additional COVD-19 findings from the Safe School Restart Study are in progress. SOCOM can be applied by schools to monitor compliance, adjust mitigation strategy messaging, and contribute to informed school policies. The current study was limited to observing only traditional classrooms, communal dining, active recess, and PE classes. Nonetheless, we believe the tool can be used in other school settings, such as music classes, laboratories, teachers’ lounges, and hallways as well as when students arrive at and depart the school grounds. Additional research, however, is needed to assess the viability of using SOCOM in these areas and times.

Interrater reliability profiles for SOCOM were comparable to those found with SOPLAY and SOPARC [Reference McKenzie, Cohen, Sehgal, Williamson and Golinelli28]. After observations, the research team discussed the effectiveness of the SOCOM protocol, observation form, and experience. In general, heuristic assessments of SOCOM was positive with certain limitations in using the electronic form, including the need for access to the internet on the devices used. Although there were limitations with concurrent electronic data entry, observers had access to the paper data collection forms and were able to later enter data into the electronic form. SOCOM worked well, even within the constraints of school environments during the pandemic. However, our study did not train school personnel as observers.

Although we have not yet trained in-school personnel to collect data, we believe the high reliability, ease of training and use, and the ability to modify the instrument, SOCOM could be used by school administrators and staff to help assess school reopening. Interventions (e.g., policies) could subsequently be implemented to further protect students, teachers, families, and the local community.

Due to the complex, novel nature of capturing COVID-19 mitigation strategy adherence, training and observation preparation were important. Training materials for SOCOM were obtained from existing valid and reliable methods. Although previous training materials focused mainly on capturing PA levels, we found that training to observe physical-distancing and face-covering behaviors was readily adaptable. Field-based observational training using the protocol in real-time were imperative. Our training included an initial visit to each school to familiarize observers with features of the school’s physical environment and review details of the school’s COVID-19 schedule, rules, and restrictions. Visits permitted the development of appropriate weekly and daily observation schedules for each school and was welcomed by school leadership and staff. Visits were necessary for positioning observers in areas where they could have a clear view and to minimize interactions with students and staff. However, a limitation of SOCOM is the potential for observation bias as individuals may be inclined to be on their best behavior while under observation. To decrease observation bias in the future, observers should be school personnel. Training teachers, staff, and administration to use SOCOM in schools can also provide schools with real-time feedback that may impact practices and policies for in-person learning.

Conclusions

Despite fears of possible surges of COVID-19 cases due to SARS-CoV-2 variants, millions of children and staff will be in schools under various conditions. Moreover, COVID-19 the vaccination of adults in the USA is proceeding, the vaccination of enough people to approach herd immunity has yet to be achieved. At the time of this writing, a vaccine has not been approved to be used among children <16 years old and no child under the age of 12 years has been enrolled in any safety or efficacy vaccine trials, thus the potential for widespread COVID-19 vaccinations in school-aged children to diminish the need for mitigation procedures in schools is many months away. Quantifying the success of SARS-CoV-2 transmission mitigation in school settings is likely to be useful for the foreseeable future. Standardized methods of measuring the fidelity of mitigation procedures will likely aid in identifying the most effective ways to minimize SARS-CoV-2 viral transmission. SOCOM is a relatively inexpensive tool that can be implemented by schools in various settings, including the school day, after school programs, and school sports and competitions, to determine mitigation strategy adherence to help students return to school safely and slow the spread of COVID-19.

Acknowledgements

The research team would like to thank Cherryl Nugas, data collection coordinator and observer, and Hoang Pham, Rula Ballat, and Rebecca Mai Huynh, observers, from the Pediatric Exercise and Genomics Research Center for their dedication to the project. We would additionally like to thank James F. Sallis, PhD, and Deborah A. Cohen, MD, for thoughtful insight and guidance during the development phases of the study.

The project was funded by the University of California Irvine (UC Irvine) Clinical and Translational Science Award (NCATS UL1; TR001414), the Orange County Health Care Agency, UC Irvine COVID-19 Research Fund, and the Northern Arizona University Southwest Health Equity Research Collaborative (NIH/NIMHD U54; U54MD012388).

Disclosures

The authors have no conflicts of interest to declare.

References

Leeb, RT, Price, S, Sliwa, S, et al. COVID-19 trends among school-aged children—United States, March 1–September 19, 2020. Morbidity and Mortality Weekly Report 2020; 69(39): 14101415.CrossRefGoogle Scholar
Yonker, LM, Neilan, AM, Bartsch, Y, et al. Pediatric severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2): clinical presentation, infectivity, and immune responses. The Journal of Pediatrics 2020; 227: 4552. e45.CrossRefGoogle ScholarPubMed
Badal, S, Bajgain, KT, Badal, S, Thapa, R, Bajgain, BB, Santana, MJ Prevalence, Clinical characteristics, and Outcomes of Pediatric COVID-19: A systematic review and meta-analysis. Journal of Clinical Virology 2020: 104715.Google ScholarPubMed
Feldstein, LR, Tenforde, MW, Friedman, KG, et al. Characteristics and Outcomes of US Children and Adolescents With Multisystem Inflammatory Syndrome in Children (MIS-C) Compared With Severe Acute COVID-19. JAMA 2021; 325(11): 10741087.CrossRefGoogle ScholarPubMed
Levin, Z, Choyke, K, Georgiou, A, Sen, S, Karaca-Mandic, P Trends in Pediatric Hospitalizations for Coronavirus Disease 2019. JAMA Pediatrics 2021; 175(4): 415417. doi: 10.1001/jamapediatrics.2020.5535.CrossRefGoogle ScholarPubMed
Pray, IW, Gibbons-Burgener, SN, Rosenberg, AZ, et al. COVID-19 Outbreak at an Overnight Summer School Retreat―Wisconsin, July–August 2020. Morbidity and Mortality Weekly Report 2020; 69(43): 1600.CrossRefGoogle ScholarPubMed
Rothe, C, Schunk, M, Sothmann, P, et al. Transmission of 2019-nCoV infection from an asymptomatic contact in Germany. New England Journal of Medicine 2020; 382(10): 970971.CrossRefGoogle ScholarPubMed
Pan, X, Chen, D, Xia, Y, et al. Asymptomatic cases in a family cluster with SARS-CoV-2 infection. The Lancet Infectious Diseases 2020; 20(4): 410411.CrossRefGoogle Scholar
Leung, NH, Chu, DK, Shiu, EY, et al. Respiratory virus shedding in exhaled breath and efficacy of face masks. Nature Medicine 2020; 26(5): 676680.CrossRefGoogle ScholarPubMed
Centers for Disease Control and Prevention. Operating schools during COVID-19: CDC’s Considerations. 2021 [cited Mar 31, 2021]. (https://www.cdc.gov/coronavirus/2019-ncov/community/schools-childcare/schools.html)Google Scholar
Sallis, JF Self-report measures of children’s physical activity. Journal of School Health 1991; 61(5): 215220.CrossRefGoogle ScholarPubMed
Hafezi, H, Robertson, TL, Moon, GD, Au-Yeung, K-Y, Zdeblick, MJ, Savage, GM An ingestible sensor for measuring medication adherence. IEEE Transactions on Biomedical Engineering 2014; 62(1): 99109.CrossRefGoogle Scholar
Hassannejad, H, Matrella, G, Ciampolini, P, De Munari, I, Mordonini, M, Cagnoni, S Automatic diet monitoring: a review of computer vision and wearable sensor-based methods. International Journal of Food Sciences and Nutrition 2017; 68(6): 656670.CrossRefGoogle ScholarPubMed
Rich, E, Miah, A Mobile, wearable and ingestible health technologies: towards a critical research agenda. Health Sociology Review. 2017;26(1):8497.CrossRefGoogle Scholar
Rundle, AG, Sheehan, DM, Quinn, JW, et al. Using GPS data to study neighborhood walkability and physical activity. American Journal of Preventive Medicine 2016; 50(3): e65e72.CrossRefGoogle ScholarPubMed
Steinhubl, SR, Muse, ED, Topol, EJ The emerging field of mobile health. Science Translational Medicine 2015; 7(283): 283rv283–283rv283.CrossRefGoogle ScholarPubMed
Turner-McGrievy, GM, Wilcox, S, Boutté, A, et al. The Dietary Intervention to Enhance Tracking with Mobile Devices (DIET Mobile) study: a 6-month randomized weight loss trial. Obesity 2017; 25(8): 13361342.CrossRefGoogle ScholarPubMed
Howe, CA, Clevenger, KA, Plow, B, Porter, S, Sinha, G Using video direct observation to assess children’s physical activity during recess. Pediatric Exercise Science 2018; 30(4): 516523.CrossRefGoogle ScholarPubMed
Patterson, TL, Sallis, JF, Nader, PR, et al. Direct observation of physical activity and dietary behaviors in a structured environment: Effects of a family-based health promotion program. Journal of Behavioral Medicine 1988; 11(5): 447458.CrossRefGoogle Scholar
McKenzie, TL, Marshall, SJ, Sallis, JF, Conway, TL Leisure-time physical activity in school environments: an observational study using SOPLAY. Preventive Medicine 2000; 30(1): 7077.CrossRefGoogle ScholarPubMed
Evenson, KR, Jones, SA, Holliday, KM, Cohen, DA, McKenzie, TL Park characteristics, use, and physical activity: A review of studies using SOPARC (System for Observing Play and Recreation in Communities). Preventive Medicine 2016; 86: 153166.CrossRefGoogle Scholar
Sanders, T, Cliff, DP, Lonsdale, C Measuring adolescent boys’ physical activity: bout length and the influence of accelerometer epoch length. PloS one 2014; 9(3): e92040.CrossRefGoogle ScholarPubMed
Van Coevering, P, Harnack, L, Schmitz, K, Fulton, JE, Galuska, DA, Gao, S Feasibility of using accelerometers to measure physical activity in young adolescents. Medicine and Science in Sports and Exercise 2005; 37(5): 867871.CrossRefGoogle ScholarPubMed
Logan, GR, Duncan, S, Harris, NK, Hinckson, EA, Schofield, G Adolescent physical activity levels: discrepancies with accelerometer data analysis. Journal of Sports Sciences 2016; 34(21): 20472053.CrossRefGoogle ScholarPubMed
Atallah, L, Lo, B, King, R, Yang, G-Z Sensor positioning for activity recognition using wearable accelerometers. IEEE Transactions on Biomedical Circuits and Systems 2011; 5(4): 320329.CrossRefGoogle ScholarPubMed
Zhu, J, Wang, W, Huang, S, Ding, W An improved calibration technique for mems accelerometer-based inclinometers. Sensors 2020; 20(2): 452.CrossRefGoogle ScholarPubMed
Teipel, S, König, A, Hoey, J, et al. Use of nonintrusive sensor-based information and communication technology for real-world evidence for clinical trials in dementia. Alzheimer’s & Dementia 2018; 14(9): 12161231.CrossRefGoogle ScholarPubMed
McKenzie, TL, Cohen, DA, Sehgal, A, Williamson, S, Golinelli, D System for Observing Play and Recreation in Communities (SOPARC): reliability and feasibility measures. Journal of Physical Activity and Health 2006; 3(s1): S208S222.CrossRefGoogle ScholarPubMed
Masonbrink, AR, Hurley, E Advocating for children during the COVID-19 school closures. Pediatrics 2020; 146(3): 19.CrossRefGoogle Scholar
Cullinane, C, Montacute, R COVID-19 and social mobility impact brief# 1: school shutdown. The Sutton Trust 2020.Google Scholar
McKenzie, TL, Sallis, JF, Nader, PR, et al. BEACHES: an observational system for assessing children’s eating and physical activity behaviors and associated events. Journal of Applied Behavior Analysis 1991; 24(1): 141151.CrossRefGoogle ScholarPubMed
McKenzie, TL, Sallis, JF, Nader, PR SOFIT: System for observing fitness instruction time. Journal of Teaching in Physical Education 1992; 11(2): 195205.CrossRefGoogle Scholar
Rowe, P, van Der Mars, H, Schuldheisz, J, Fox, S Measuring students’ physical activity levels: validating SOFIT for use with high-school students. Journal of Teaching in Physical Education 2004; 23(3): 235251.CrossRefGoogle Scholar
Scruggs, PW, Beveridge, SK, Eisenman, PA, Watson, DL, Shultz, BB, Ransdell, LB Quantifying physical activity via pedometry in elementary physical education. Medicine & Science in Sports & Exercise 2003; 35(6): 10651071.CrossRefGoogle ScholarPubMed
Cooper, DM, Aizik, S, Camplain, RL, et al. SARS-CoV-2 Acquisition and Immune Pathogenesis Among School-Aged Learners in Four K-12 Schools. medRxiv 2021.Google ScholarPubMed
MacIntyre, CR, Wang, Q Physical distancing, face masks, and eye protection for prevention of COVID-19. The Lancet 2020; 395(10242): 19501951.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Characteristics within observed schools

Figure 1

Fig. 1. Sample Systematic Observation of COVID-19 Mitigation (SOCOM) Electronic Data Collection Form.

Figure 2

Fig. 2. Sample Systematic Observation of COVID-19 Mitigation (SOCOM) Paper Data Collection Form.

Figure 3

Table 2. Systematic observation of COVID-19 mitigation (SOCOM) central measures