Using a Real-world Network to Model Localized COVID-19 Control Strategies

Overview

Journal Nat Med

Specialties General Medicine
Molecular Biology

Date 2020 Aug 10

PMID 32770169

Citations 90

Authors

Josh A Firth

Joel Hellewell

Petra Klepac

Stephen Kissler

Adam J Kucharski

Lewis G Spurgin

Affiliations

Soon will be listed here.

Abstract

Case isolation and contact tracing can contribute to the control of COVID-19 outbreaks. However, it remains unclear how real-world social networks could influence the effectiveness and efficiency of such approaches. To address this issue, we simulated control strategies for SARS-CoV-2 transmission in a real-world social network generated from high-resolution GPS data that were gathered in the course of a citizen-science experiment. We found that tracing the contacts of contacts reduced the size of simulated outbreaks more than tracing of only contacts, but this strategy also resulted in almost half of the local population being quarantined at a single point in time. Testing and releasing non-infectious individuals from quarantine led to increases in outbreak size, suggesting that contact tracing and quarantine might be most effective as a 'local lockdown' strategy when contact rates are high. Finally, we estimated that combining physical distancing with contact tracing could enable epidemic control while reducing the number of quarantined individuals. Our findings suggest that targeted tracing and quarantine strategies would be most efficient when combined with other control measures such as physical distancing.

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