R01NR020105

Multi-Modal Wireless COVID Monitoring & Infection Alerts for Concentrated Populations

Abstract:
The high aerosolized transmissibility of COVID, long asymptomatic incubation period, and highly variable presentation attributes of the COVID pandemic have proven challenging in many settings where patchwork pandemic responses have disproportionately negatively impacted vulnerable socioeconomic, minority, and disabled sub-populations. Unfortunately, these dire trends are only made more acute in settings that feature populations with limited mobility and little to no ability to self-isolate (dense concentrated populations [DCPs]), such as residential nursing homes, schools, drug rehabilitation services, prison and psychiatric facility populations, and high-frequency essential medical services, such as chemotherapy infusion clinics or dialysis units.

In these DCP settings, limited diagnostic testing, prolonged indoor contact, limitations in cleaning and filtration capacities, support staff shortages, pre-existing comorbidities, and lack of effective infectious disease surveillance systems all collude to drive an increased COVID burden in DCPs. From this, it is clear that alternative detection strategies for DCPs are urgently needed to improve local capacity to monitor COVID outbreaks, mitigate their spread, and thus reduce inequitable disease and mortality burdens in these under-resourced and often overcrowded settings.

In previous work, we developed a first-generation detection system using heart rate data from commercially-available Fitbit Ionic wearable devices to detect the onset of COVID and other infectious diseases up to 10 days before users self-reported symptom onset (overall sensitivity 67% prior to symptom onset). Here, we propose to further develop this system for the improved detection of COVID and other infectious diseases in DCPs using existing wearable fitness devices in a wireless and interoperable digital health framework that centralizes all wearable-derived data on PHD while tailoring its presentation and health event alert system to the IT capabilities and needs of each DCP setting.

In this, not only will we adapt our existing infection detection algorithms for each DCP's particular baseline characteristics, IT infrastructure, and needs, but also use incoming data to further optimize the performance of those algorithms for continuous improvement in the sensitivity, specificity, and alert lead time for COVID onset. This will quickly enable under-resourced DCP support staff to access and use world-class COVID surveillance data in identifying individual infection events, implementing isolation, cleaning, and testing policies, and minimizing transmission, thus reducing the burden of COVID in DCP settings and reducing DCP morbidity and mortality overall.

The Leland Stanford Junior University

NOT APPLICABLE

93.360 - Biomedical Advanced Research and Development Authority (BARDA), Biodefense Medical Countermeasure Development

National Institute of Nursing Research (NINR) [HHS - NIH]

National Institute of Allergy and Infectious Diseases (NIAID) [HHS - NIH]

California United States

State-Wide

Emergency Awards: RADx-RAD Multimodal COVID-19 surveillance methods for high risk clustered populations (R01 Clinical Trial Optional) (RFA-OD-20-016)

COVID-19 $2,183,191 (66%) percent of this Project Grant was funded by COVID-19 emergency acts including the American Rescue Plan Act of 2021 and the Paycheck Protection Program and Health Care Enhancement Act.
Amendment Since initial award the End Date has been extended from 02/28/22 to 11/30/23 and the total obligations have increased 195% from $1,121,730 to $3,304,921.