Epidemiological Impact of SARS-CoV-2 Vaccination: Mathematical Modeling Analyses

Overview

Journal Vaccines (Basel)

Date 2020 Nov 13

PMID 33182403

Citations 57

Authors

Monia Makhoul

Houssein H Ayoub

Hiam Chemaitelly

Shaheen Seedat

Ghina R Mumtaz

Sarah Al-Omari

Laith J Abu-Raddad

Affiliations

Soon will be listed here.

Abstract

This study aims to inform SARS-CoV-2 vaccine development/licensure/decision-making/implementation, using mathematical modeling, by determining key preferred vaccine product characteristics and associated population-level impacts of a vaccine eliciting long-term protection. A prophylactic vaccine with efficacy against acquisition () ≥70% can eliminate the infection. A vaccine with <70% may still control the infection if it reduces infectiousness or infection duration among those vaccinated who acquire the infection, if it is supplemented with <20% reduction in contact rate, or if it is complemented with herd-immunity. At of 50%, the number of vaccinated persons needed to avert one infection is 2.4, and the number is 25.5 to avert one severe disease case, 33.2 to avert one critical disease case, and 65.1 to avert one death. The probability of a major outbreak is zero at ≥70% regardless of the number of virus introductions. However, an increase in social contact rate among those vaccinated (behavior compensation) can undermine vaccine impact. In addition to the reduction in infection acquisition, developers should assess the natural history and disease progression outcomes when evaluating vaccine impact.

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