Biomedical and health informatics approaches remain essential for addressing the COVID-19 pandemic

Abstract

As this March issue of the Journal of the American Medical Informatics Association (JAMIA) is published, we have experienced a year of sheltering-in-place, wearing masks, frequent handwashing, and COVID-19 testing. For some of us, this year also included COVID-19 infection and loss of family, friends, and colleagues— and more recently, COVID-19 vaccination. I accepted JAMIA’s first COVID-related paper on March 19, 2020 less than 24 hours after its submission, and the accepted version was available online within days. To date, JAMIA has received almost 400 COVIDrelated submissions and published 69 contributions in issues since June 2020. The March issue includes 7 papers and correspondence related to COVID-19 including a call from World Health Organization authors to strengthen data in response to COVID-19 and beyond, a report on virtual care expansion in the Veterans Health Administration, and correspondence about telemedicine, privacy, and information security in the age of COVID-19. In this editorial, I highlight 5 papers that reflect the breadth of biomedical and health informatics approaches to addressing the COVID-19 pandemic. Haendel and colleagues provide an overview of the rationale, design, infrastructure, and deployment of the National COVID Cohort Collaborative (N3C). N3C (covid.cd2h.org), an open science community focused on analyzing individual-level data from many centers, was developed by the Clinical and Translational Award Program, the National Center for Translational Sciences, and the scientific community to enable rapid collaboration among clinicians, researchers, and data scientists to identify treatments and specialized care and subsequently reduce the immediate and long-term consequences of COVID-19. To overcome technical, regulatory, policy, and governance barriers to sharing and harmonizing individual-level clinical data, N3C developed (a) legal agreements and governance for organizations and researchers; (b) data extraction scripts to identify and ingest positive, negative, and possible COVID-19 cases; (c) a data quality assurance and harmonization pipeline to create a single harmonized dataset; (d) a secure data enclave with data, machine learning, and statistical analytics tools; (e) dissemination mechanisms; and (f) a synthetic data pilot to democratize data access. There are 3 datasets for analysis: synthetic, deidentified, and limited. The Attribution and Publication Policy encompasses all N3C contributions as reflected in the author contribution statement for this paper. Analyses posted within the N3C enclave leverage the contributor attribution model to track the transitive credit of all upstream contributors. The N3C infrastructure is designed to be scalable and extensible to other topics. Sun and colleagues designed COVID-19 Trial Finder, an opensource semantic search engine, to facilitate patient-centered search of COVID-19 trials. It is powered by a machine-readable dataset for all COVID-19 trials in the United States. COVID-19 Trial Finder also includes a web-based visualization of the geographic distribution of COVID-19 trials. The initial search is by location and radius distance from trial sites; this is refined through a set of dynamically generated medical questions to assess patient eligibility for nearby COVID-19 trials. They assessed the precision of COVID-19 Trial Finder for COVID19 using 20 case reports from LitCOVID. Overall precision across the 20 cases was 79.76%, although it varied widely across cases. The major factor contributing to imprecision was the inability to generate relevant questions in some instances which prevented filtering out irrelevant trials. The system (https://covidtrialx.dbmi.columbia.edu) and its source code (https://github.com/WengLab-InformaticsResearch/COVID19-TrialFinder) are accessible online. Hassandoust, Akhaghpour, and Johnson examine individual privacy concerns and intention to adopt contact tracing mobile applications through a situational privacy calculus model. Using structural equation modeling and a national sample (N1⁄4853) of survey