Mitigation and herd immunity strategy for COVID-19 is likely to fail-Reference-Cited by-同舟云学术

Mitigation and herd immunity strategy for COVID-19 is likely to fail

Published:2020-03-30 Issue: Volume: Page:
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Adamik Barbara^ORCID,Bawiec Marek^ORCID,Bezborodov Viktor^ORCID,Bock Wolfgang^ORCID,Bodych Marcin^ORCID,Burgard Jan Pablo^ORCID,Götz Thomas,Krueger Tyll^ORCID,Migalska Agata^ORCID,Pabjan Barbara^ORCID,Ożański Tomasz^ORCID,Rafajłowicz Ewaryst^ORCID,Rafajłowicz Wojciech^ORCID,Skubalska-Rafajłowicz Ewa^ORCID,Ryfczyńska Sara,Szczurek Ewa^ORCID,Szymański Piotr^ORCID

Abstract

AbstractOn the basis of a semi-realistic SIR microsimulation for Germany and Poland, we show that the R0 parameter interval for which the COVID-19 epidemic stays overcritical but below the capacity limit of the health care system to reach herd immunity is so narrow that a successful implementation of this strategy is likely to fail, which is in contrast to results obtained from classical differential equation models. Our microsimulation is based on official census data and involves household composition and age distribution as the main population structure variables. Outside household contacts are characterised by an out-reproduction number R* which is the only free parameter of the model. For a subcritical domain we compute the time till extinction and prevalence as a function of the initial number of infected individuals and R*. For the Polish city of Wrocław we also discuss the combined impact of testing coverage and contact reduction. For both countries we estimate R* for disease progression until 20th of March 2020.

Publisher

Cold Spring Harbor Laboratory

Reference20 articles.

1. Community mitigation guidelines to prevent pandemic influenza United States, 2017;MMWR Recommendations and Reports,2017

2. Hollingsworth, T. D. , Klinkenberg, D. , Heesterbeek, H. , & Anderson, R. M. (2011). Mitigation strategies for pandemic influenza A: balancing conflicting policy objectives. PLoS computational biology, 7(2).

3. How will country-based mitigation measures influence the course of the COVID-19 epidemic;The Lancet,2020

4. A Novel Coronavirus from Patients with Pneumonia in China, 2019

5. Wu, J. T. , Leung, K. , Bushman, M. , Kishore, N. , Niehus, R. , de Salazar, P. M. , & Leung, G. M. (2020). Estimating clinical severity of COVID-19 from the transmission dynamics in Wuhan, China. Nature Medicine, 1–5.

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