Effects of delayed recovery and nonuniform transmission on the spreading of diseases in complex networks

Cheng Yi Xia; Zhen Wang; Joaquin Sanz; Sandro Meloni; Yamir Moreno

doi:10.1016/j.physa.2012.11.043

Effects of delayed recovery and nonuniform transmission on the spreading of diseases in complex networks

Cheng Yi Xia^*, Zhen Wang, Joaquin Sanz, Sandro Meloni, Yamir Moreno

^*Corresponding author for this work

Department of Physics

Research output: Contribution to journal › Journal article › peer-review

108 Citations (Scopus)

Abstract

We investigate the effects of delaying the time to recovery (delayed recovery) and of nonuniform transmission on the propagation of diseases on structured populations. Through a mean-field approximation and large-scale numerical simulations, we find that postponing the transition from the infectious to the recovered states can largely reduce the epidemic threshold, therefore promoting the outbreak of epidemics. On the other hand, if we consider nonuniform transmission among individuals, the epidemic threshold increases, thus inhibiting the spreading process. When both mechanisms are at work, the latter might prevail, hence resulting in an increase of the epidemic threshold with respect to the standard case, in which both ingredients are absent. Our findings are of interest for a better understanding of how diseases propagate on structured populations and to a further design of efficient immunization strategies.

Original language	English
Pages (from-to)	1577-1585
Number of pages	9
Journal	Physica A: Statistical Mechanics and its Applications
Volume	392
Issue number	7
DOIs	https://doi.org/10.1016/j.physa.2012.11.043
Publication status	Published - 1 Apr 2013

User-Defined Keywords

Complex networks
Disease spreading
Heterogeneous mean-field approach
SIS model

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10.1016/j.physa.2012.11.043

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title = "Effects of delayed recovery and nonuniform transmission on the spreading of diseases in complex networks",

abstract = "We investigate the effects of delaying the time to recovery (delayed recovery) and of nonuniform transmission on the propagation of diseases on structured populations. Through a mean-field approximation and large-scale numerical simulations, we find that postponing the transition from the infectious to the recovered states can largely reduce the epidemic threshold, therefore promoting the outbreak of epidemics. On the other hand, if we consider nonuniform transmission among individuals, the epidemic threshold increases, thus inhibiting the spreading process. When both mechanisms are at work, the latter might prevail, hence resulting in an increase of the epidemic threshold with respect to the standard case, in which both ingredients are absent. Our findings are of interest for a better understanding of how diseases propagate on structured populations and to a further design of efficient immunization strategies.",

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author = "Xia, {Cheng Yi} and Zhen Wang and Joaquin Sanz and Sandro Meloni and Yamir Moreno",

note = "CYX is partially supported by the National Natural Science Foundation of China under Grant No. 60904063, the Tianjin Municipal Natural Science Foundation under Grant No. 11JCYBJC06600 and the 7th Overseas Training Project for the Young and Middle Teachers in Tianjin Municipal Universities. SM is supported by the Spanish Ministry of Science and Innovation (MICINN) through project FIS2009-13364-C02-01. YM is supported by the Spanish MICINN through projects FIS2009-13364-C02-01 and FIS2011-25167. Publisher copyright: {\textcopyright} 2012 Elsevier B.V. All rights reserved.",

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AU - Xia, Cheng Yi

AU - Wang, Zhen

AU - Sanz, Joaquin

AU - Meloni, Sandro

AU - Moreno, Yamir

N1 - CYX is partially supported by the National Natural Science Foundation of China under Grant No. 60904063, the Tianjin Municipal Natural Science Foundation under Grant No. 11JCYBJC06600 and the 7th Overseas Training Project for the Young and Middle Teachers in Tianjin Municipal Universities. SM is supported by the Spanish Ministry of Science and Innovation (MICINN) through project FIS2009-13364-C02-01. YM is supported by the Spanish MICINN through projects FIS2009-13364-C02-01 and FIS2011-25167. Publisher copyright: © 2012 Elsevier B.V. All rights reserved.

PY - 2013/4/1

Y1 - 2013/4/1

N2 - We investigate the effects of delaying the time to recovery (delayed recovery) and of nonuniform transmission on the propagation of diseases on structured populations. Through a mean-field approximation and large-scale numerical simulations, we find that postponing the transition from the infectious to the recovered states can largely reduce the epidemic threshold, therefore promoting the outbreak of epidemics. On the other hand, if we consider nonuniform transmission among individuals, the epidemic threshold increases, thus inhibiting the spreading process. When both mechanisms are at work, the latter might prevail, hence resulting in an increase of the epidemic threshold with respect to the standard case, in which both ingredients are absent. Our findings are of interest for a better understanding of how diseases propagate on structured populations and to a further design of efficient immunization strategies.

AB - We investigate the effects of delaying the time to recovery (delayed recovery) and of nonuniform transmission on the propagation of diseases on structured populations. Through a mean-field approximation and large-scale numerical simulations, we find that postponing the transition from the infectious to the recovered states can largely reduce the epidemic threshold, therefore promoting the outbreak of epidemics. On the other hand, if we consider nonuniform transmission among individuals, the epidemic threshold increases, thus inhibiting the spreading process. When both mechanisms are at work, the latter might prevail, hence resulting in an increase of the epidemic threshold with respect to the standard case, in which both ingredients are absent. Our findings are of interest for a better understanding of how diseases propagate on structured populations and to a further design of efficient immunization strategies.

KW - Complex networks

KW - Disease spreading

KW - Heterogeneous mean-field approach

KW - SIS model

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Effects of delayed recovery and nonuniform transmission on the spreading of diseases in complex networks

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