Spatial heterogeneity in simple deterministic sir models assessed ecologically

E. K. Waters; H. S. Sidhu; G. N. Mercer

doi:10.1017/S1446181113000035

Spatial heterogeneity in simple deterministic sir models assessed ecologically

E. K. Waters^*, H. S. Sidhu, G. N. Mercer

^*Corresponding author for this work

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

7 Citations (Scopus)

Abstract

Patchy or divided populations can be important to infectious disease transmission. We first show that Lloyd's mean crowding index, an index of patchiness from ecology, appears as a term in simple deterministic epidemic models of the SIR type. Using these models, we demonstrate that the rate of movement between patches is crucial for epidemic dynamics. In particular, there is a relationship between epidemic final size and epidemic duration in patchy habitats: controlling inter-patch movement will reduce epidemic duration, but also final size. This suggests that a strategy of quarantining infected areas during the initial phases of a virulent epidemic might reduce epidemic duration, but leave the population vulnerable to future epidemics by inhibiting the development of herd immunity.

Original language	English
Pages (from-to)	23-36
Number of pages	14
Journal	ANZIAM Journal
Volume	54
Issue number	1-2
DOIs	https://doi.org/10.1017/S1446181113000035
Publication status	Published - 2012

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title = "Spatial heterogeneity in simple deterministic sir models assessed ecologically",

abstract = "Patchy or divided populations can be important to infectious disease transmission. We first show that Lloyd's mean crowding index, an index of patchiness from ecology, appears as a term in simple deterministic epidemic models of the SIR type. Using these models, we demonstrate that the rate of movement between patches is crucial for epidemic dynamics. In particular, there is a relationship between epidemic final size and epidemic duration in patchy habitats: controlling inter-patch movement will reduce epidemic duration, but also final size. This suggests that a strategy of quarantining infected areas during the initial phases of a virulent epidemic might reduce epidemic duration, but leave the population vulnerable to future epidemics by inhibiting the development of herd immunity.",

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T1 - Spatial heterogeneity in simple deterministic sir models assessed ecologically

AU - Waters, E. K.

AU - Sidhu, H. S.

AU - Mercer, G. N.

PY - 2012

Y1 - 2012

N2 - Patchy or divided populations can be important to infectious disease transmission. We first show that Lloyd's mean crowding index, an index of patchiness from ecology, appears as a term in simple deterministic epidemic models of the SIR type. Using these models, we demonstrate that the rate of movement between patches is crucial for epidemic dynamics. In particular, there is a relationship between epidemic final size and epidemic duration in patchy habitats: controlling inter-patch movement will reduce epidemic duration, but also final size. This suggests that a strategy of quarantining infected areas during the initial phases of a virulent epidemic might reduce epidemic duration, but leave the population vulnerable to future epidemics by inhibiting the development of herd immunity.

AB - Patchy or divided populations can be important to infectious disease transmission. We first show that Lloyd's mean crowding index, an index of patchiness from ecology, appears as a term in simple deterministic epidemic models of the SIR type. Using these models, we demonstrate that the rate of movement between patches is crucial for epidemic dynamics. In particular, there is a relationship between epidemic final size and epidemic duration in patchy habitats: controlling inter-patch movement will reduce epidemic duration, but also final size. This suggests that a strategy of quarantining infected areas during the initial phases of a virulent epidemic might reduce epidemic duration, but leave the population vulnerable to future epidemics by inhibiting the development of herd immunity.

KW - SIR model

KW - ecology

KW - infectious diseases

KW - spatial dynamics

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DO - 10.1017/S1446181113000035

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VL - 54

SP - 23

EP - 36

JO - ANZIAM Journal

JF - ANZIAM Journal

IS - 1-2

ER -

Spatial heterogeneity in simple deterministic sir models assessed ecologically

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