1. Control of COVID‐19 Outbreaks under Stochastic Community Dynamics, Bimodality, or Limited Vaccination
- Author
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Björn Goldenbogen, Stephan O. Adler, Oliver Bodeit, Judith A. H. Wodke, Ximena Escalera‐Fanjul, Aviv Korman, Maria Krantz, Lasse Bonn, Rafael Morán‐Torres, Johanna E. L. Haffner, Maxim Karnetzki, Ivo Maintz, Lisa Mallis, Hannah Prawitz, Patrick S. Segelitz, Martin Seeger, Rune Linding, and Edda Klipp
- Subjects
bimodality ,COVID‐19 ,epidemiology ,respiratory diseases ,stochastic agent‐based modeling ,Science - Abstract
Abstract Reaching population immunity against COVID‐19 is proving difficult even in countries with high vaccination levels. Thus, it is critical to identify limits of control and effective measures against future outbreaks. The effects of nonpharmaceutical interventions (NPIs) and vaccination strategies are analyzed with a detailed community‐specific agent‐based model (ABM). The authors demonstrate that the threshold for population immunity is not a unique number, but depends on the vaccination strategy. Prioritizing highly interactive people diminishes the risk for an infection wave, while prioritizing the elderly minimizes fatalities when vaccinations are low. Control over COVID‐19 outbreaks requires adaptive combination of NPIs and targeted vaccination, exemplified for Germany for January–September 2021. Bimodality emerges from the heterogeneity and stochasticity of community‐specific human–human interactions and infection networks, which can render the effects of limited NPIs uncertain. The authors' simulation platform can process and analyze dynamic COVID‐19 epidemiological situations in diverse communities worldwide to predict pathways to population immunity even with limited vaccination.
- Published
- 2022
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