Separable mixing: The general formulation and a particular example focusing on mask efficiency

M. C.J. Bootsma; K. M.D. Chan; O. Diekmann; H. Inaba

doi:10.3934/mbe.2023785

Separable mixing: The general formulation and a particular example focusing on mask efficiency

M. C.J. Bootsma, K. M.D. Chan, O. Diekmann^*, H. Inaba

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

The aim of this short note is twofold. First, we formulate the general Kermack-McKendrick epidemic model incorporating static heterogeneity and show how it simplifies to a scalar Renewal Equation (RE) when separable mixing is assumed. A key general feature is that all information about the heterogeneity is encoded in one nonlinear real valued function of a real variable. Next, we specialize the model ingredients so that we can study the efficiency of mask wearing as a non-pharmaceutical intervention to reduce the spread of an infectious disease. Our main result affirms that the best way to protect the population as a whole is to protect yourself. This qualitative insight was recently derived in the context of an SIR network model. Here, we extend the conclusion to proportionate mixing models incorporating a general function describing expected infectiousness as a function of time since infection.

Original language	English
Pages (from-to)	17661-17671
Number of pages	11
Journal	Mathematical Biosciences and Engineering
Volume	20
Issue number	10
DOIs	https://doi.org/10.3934/mbe.2023785
Publication status	Published - 2023

Keywords

epidemic model
heterogeneity
Kermack-McKendrick
mask efficiency
separable mixing

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title = "Separable mixing: The general formulation and a particular example focusing on mask efficiency",

abstract = "The aim of this short note is twofold. First, we formulate the general Kermack-McKendrick epidemic model incorporating static heterogeneity and show how it simplifies to a scalar Renewal Equation (RE) when separable mixing is assumed. A key general feature is that all information about the heterogeneity is encoded in one nonlinear real valued function of a real variable. Next, we specialize the model ingredients so that we can study the efficiency of mask wearing as a non-pharmaceutical intervention to reduce the spread of an infectious disease. Our main result affirms that the best way to protect the population as a whole is to protect yourself. This qualitative insight was recently derived in the context of an SIR network model. Here, we extend the conclusion to proportionate mixing models incorporating a general function describing expected infectiousness as a function of time since infection.",

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language = "English",

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T2 - The general formulation and a particular example focusing on mask efficiency

AU - Bootsma, M. C.J.

AU - Chan, K. M.D.

AU - Diekmann, O.

AU - Inaba, H.

PY - 2023

Y1 - 2023

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AB - The aim of this short note is twofold. First, we formulate the general Kermack-McKendrick epidemic model incorporating static heterogeneity and show how it simplifies to a scalar Renewal Equation (RE) when separable mixing is assumed. A key general feature is that all information about the heterogeneity is encoded in one nonlinear real valued function of a real variable. Next, we specialize the model ingredients so that we can study the efficiency of mask wearing as a non-pharmaceutical intervention to reduce the spread of an infectious disease. Our main result affirms that the best way to protect the population as a whole is to protect yourself. This qualitative insight was recently derived in the context of an SIR network model. Here, we extend the conclusion to proportionate mixing models incorporating a general function describing expected infectiousness as a function of time since infection.

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Separable mixing: The general formulation and a particular example focusing on mask efficiency

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