npj Digital Medicine (Sep 2022)

A method for intelligent allocation of diagnostic testing by leveraging data from commercial wearable devices: a case study on COVID-19

  • Md Mobashir Hasan Shandhi,
  • Peter J. Cho,
  • Ali R. Roghanizad,
  • Karnika Singh,
  • Will Wang,
  • Oana M. Enache,
  • Amanda Stern,
  • Rami Sbahi,
  • Bilge Tatar,
  • Sean Fiscus,
  • Qi Xuan Khoo,
  • Yvonne Kuo,
  • Xiao Lu,
  • Joseph Hsieh,
  • Alena Kalodzitsa,
  • Amir Bahmani,
  • Arash Alavi,
  • Utsab Ray,
  • Michael P. Snyder,
  • Geoffrey S. Ginsburg,
  • Dana K. Pasquale,
  • Christopher W. Woods,
  • Ryan J. Shaw,
  • Jessilyn P. Dunn

DOI
https://doi.org/10.1038/s41746-022-00672-z
Journal volume & issue
Vol. 5, no. 1
pp. 1 – 13

Abstract

Read online

Abstract Mass surveillance testing can help control outbreaks of infectious diseases such as COVID-19. However, diagnostic test shortages are prevalent globally and continue to occur in the US with the onset of new COVID-19 variants and emerging diseases like monkeypox, demonstrating an unprecedented need for improving our current methods for mass surveillance testing. By targeting surveillance testing toward individuals who are most likely to be infected and, thus, increasing the testing positivity rate (i.e., percent positive in the surveillance group), fewer tests are needed to capture the same number of positive cases. Here, we developed an Intelligent Testing Allocation (ITA) method by leveraging data from the CovIdentify study (6765 participants) and the MyPHD study (8580 participants), including smartwatch data from 1265 individuals of whom 126 tested positive for COVID-19. Our rigorous model and parameter search uncovered the optimal time periods and aggregate metrics for monitoring continuous digital biomarkers to increase the positivity rate of COVID-19 diagnostic testing. We found that resting heart rate (RHR) features distinguished between COVID-19-positive and -negative cases earlier in the course of the infection than steps features, as early as 10 and 5 days prior to the diagnostic test, respectively. We also found that including steps features increased the area under the receiver operating characteristic curve (AUC-ROC) by 7–11% when compared with RHR features alone, while including RHR features improved the AUC of the ITA model’s precision-recall curve (AUC-PR) by 38–50% when compared with steps features alone. The best AUC-ROC (0.73 ± 0.14 and 0.77 on the cross-validated training set and independent test set, respectively) and AUC-PR (0.55 ± 0.21 and 0.24) were achieved by using data from a single device type (Fitbit) with high-resolution (minute-level) data. Finally, we show that ITA generates up to a 6.5-fold increase in the positivity rate in the cross-validated training set and up to a 4.5-fold increase in the positivity rate in the independent test set, including both symptomatic and asymptomatic (up to 27%) individuals. Our findings suggest that, if deployed on a large scale and without needing self-reported symptoms, the ITA method could improve the allocation of diagnostic testing resources and reduce the burden of test shortages.