Probability of extinction and peak time for multi-type epidemics with application to COVID-19 variants of concern

•The dynamics of strain invasion and establishment are subject to high stochasticity.•We describe a model of the early growth of a putative COVID-19 variant of concern in the UK.•We derive a novel approximation for the time to establishment of an invading strain.•Our estimates of uncertainty are use...

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Published inJournal of theoretical biology Vol. 608; p. 112135
Main Authors Curran-Sebastian, Jacob, Dyson, Louise, Hill, Edward M., Hall, Ian, Pellis, Lorenzo, House, Thomas
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 07.07.2025
Subjects
Computer Simulation
COVID-19
COVID-19 - epidemiology
COVID-19 - transmission
COVID-19 - virology
Epidemics
Heterogeneity
Humans
Models, Biological
Multi-type branching process
Pandemics
Probability
SARS-CoV-2
Stochastic model
Stochastic Processes
Time Factors
United Kingdom - epidemiology
Variant of concern
United Kingdom
COVID-19
Heterogeneity
Stochastic model
Variant of concern
Multi-type branching process
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Abstract •The dynamics of strain invasion and establishment are subject to high stochasticity.•We describe a model of the early growth of a putative COVID-19 variant of concern in the UK.•We derive a novel approximation for the time to establishment of an invading strain.•Our estimates of uncertainty are useful for intervention and scenario planning. During the COVID-19 pandemic, the emergence of novel variants of concern (VoCs) prompted different responses from governments across the world aimed at mitigating the impacts of more transmissible or more harmful strains. We model the invasion of a novel VoC into a population with heterogeneous vaccine- and infection-acquired immunity using a multi-type branching process framework with immigration. We define the number of cases needed to be reached to ensure stochastic extinction of this strain is unlikely and, therefore, the strain has become established in the population. To estimate the first-passage time distribution to reach this number of cases we use a mixture of stochastic simulations and analytic results. The first-passage time distribution gives a time window that is useful for policymakers planning interventions aimed at suppressing or delaying the introduction of novel VoC. We apply our method to a model of COVID-19 in the United Kingdom, though our results are applicable to other pathogens and settings.
AbstractList •The dynamics of strain invasion and establishment are subject to high stochasticity.•We describe a model of the early growth of a putative COVID-19 variant of concern in the UK.•We derive a novel approximation for the time to establishment of an invading strain.•Our estimates of uncertainty are useful for intervention and scenario planning. During the COVID-19 pandemic, the emergence of novel variants of concern (VoCs) prompted different responses from governments across the world aimed at mitigating the impacts of more transmissible or more harmful strains. We model the invasion of a novel VoC into a population with heterogeneous vaccine- and infection-acquired immunity using a multi-type branching process framework with immigration. We define the number of cases needed to be reached to ensure stochastic extinction of this strain is unlikely and, therefore, the strain has become established in the population. To estimate the first-passage time distribution to reach this number of cases we use a mixture of stochastic simulations and analytic results. The first-passage time distribution gives a time window that is useful for policymakers planning interventions aimed at suppressing or delaying the introduction of novel VoC. We apply our method to a model of COVID-19 in the United Kingdom, though our results are applicable to other pathogens and settings.
During the COVID-19 pandemic, the emergence of novel variants of concern (VoCs) prompted different responses from governments across the world aimed at mitigating the impacts of more transmissible or more harmful strains. We model the invasion of a novel VoC into a population with heterogeneous vaccine- and infection-acquired immunity using a multi-type branching process framework with immigration. We define the number of cases needed to be reached to ensure stochastic extinction of this strain is unlikely and, therefore, the strain has become established in the population. To estimate the first-passage time distribution to reach this number of cases we use a mixture of stochastic simulations and analytic results. The first-passage time distribution gives a time window that is useful for policymakers planning interventions aimed at suppressing or delaying the introduction of novel VoC. We apply our method to a model of COVID-19 in the United Kingdom, though our results are applicable to other pathogens and settings.During the COVID-19 pandemic, the emergence of novel variants of concern (VoCs) prompted different responses from governments across the world aimed at mitigating the impacts of more transmissible or more harmful strains. We model the invasion of a novel VoC into a population with heterogeneous vaccine- and infection-acquired immunity using a multi-type branching process framework with immigration. We define the number of cases needed to be reached to ensure stochastic extinction of this strain is unlikely and, therefore, the strain has become established in the population. To estimate the first-passage time distribution to reach this number of cases we use a mixture of stochastic simulations and analytic results. The first-passage time distribution gives a time window that is useful for policymakers planning interventions aimed at suppressing or delaying the introduction of novel VoC. We apply our method to a model of COVID-19 in the United Kingdom, though our results are applicable to other pathogens and settings.
During the COVID-19 pandemic, the emergence of novel variants of concern (VoCs) prompted different responses from governments across the world aimed at mitigating the impacts of more transmissible or more harmful strains. We model the invasion of a novel VoC into a population with heterogeneous vaccine- and infection-acquired immunity using a multi-type branching process framework with immigration. We define the number of cases needed to be reached to ensure stochastic extinction of this strain is unlikely and, therefore, the strain has become established in the population. To estimate the first-passage time distribution to reach this number of cases we use a mixture of stochastic simulations and analytic results. The first-passage time distribution gives a time window that is useful for policymakers planning interventions aimed at suppressing or delaying the introduction of novel VoC. We apply our method to a model of COVID-19 in the United Kingdom, though our results are applicable to other pathogens and settings.
ArticleNumber 112135
Author Curran-Sebastian, Jacob
Hall, Ian
Hill, Edward M.
House, Thomas
Dyson, Louise
Pellis, Lorenzo
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Keywords COVID-19
Heterogeneity
Stochastic model
Variant of concern
Multi-type branching process
Language English
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Copyright © 2025 The Authors. Published by Elsevier Ltd.. All rights reserved.
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Snippet •The dynamics of strain invasion and establishment are subject to high stochasticity.•We describe a model of the early growth of a putative COVID-19 variant of...
During the COVID-19 pandemic, the emergence of novel variants of concern (VoCs) prompted different responses from governments across the world aimed at...
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StartPage 112135
SubjectTerms Computer Simulation
COVID-19
COVID-19 - epidemiology
COVID-19 - transmission
COVID-19 - virology
Epidemics
Heterogeneity
Humans
Models, Biological
Multi-type branching process
Pandemics
Probability
SARS-CoV-2
Stochastic model
Stochastic Processes
Time Factors
United Kingdom - epidemiology
Variant of concern
Title Probability of extinction and peak time for multi-type epidemics with application to COVID-19 variants of concern
URI https://dx.doi.org/10.1016/j.jtbi.2025.112135
https://www.ncbi.nlm.nih.gov/pubmed/40306569
https://www.proquest.com/docview/3198304956
Volume 608
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