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BMC Infectious Diseases

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Open Access 01-12-2016 | Research Article

Recalibrating disease parameters for increasing realism in modeling epidemics in closed settings

Authors: Livio Bioglio, Mathieu Génois, Christian L. Vestergaard, Chiara Poletto, Alain Barrat, Vittoria Colizza

Published in: BMC Infectious Diseases | Issue 1/2016

Abstract

Background

The homogeneous mixing assumption is widely adopted in epidemic modelling for its parsimony and represents the building block of more complex approaches, including very detailed agent-based models. The latter assume homogeneous mixing within schools, workplaces and households, mostly for the lack of detailed information on human contact behaviour within these settings. The recent data availability on high-resolution face-to-face interactions makes it now possible to assess the goodness of this simplified scheme in reproducing relevant aspects of the infection dynamics.

Methods

We consider empirical contact networks gathered in different contexts, as well as synthetic data obtained through realistic models of contacts in structured populations. We perform stochastic spreading simulations on these contact networks and in populations of the same size under a homogeneous mixing hypothesis. We adjust the epidemiological parameters of the latter in order to fit the prevalence curve of the contact epidemic model. We quantify the agreement by comparing epidemic peak times, peak values, and epidemic sizes.

Results

Good approximations of the peak times and peak values are obtained with the homogeneous mixing approach, with a median relative difference smaller than 20 % in all cases investigated. Accuracy in reproducing the peak time depends on the setting under study, while for the peak value it is independent of the setting. Recalibration is found to be linear in the epidemic parameters used in the contact data simulations, showing changes across empirical settings but robustness across groups and population sizes.

Conclusions

An adequate rescaling of the epidemiological parameters can yield a good agreement between the epidemic curves obtained with a real contact network and a homogeneous mixing approach in a population of the same size. The use of such recalibrated homogeneous mixing approximations would enhance the accuracy and realism of agent-based simulations and limit the intrinsic biases of the homogeneous mixing.

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Title: Recalibrating disease parameters for increasing realism in modeling epidemics in closed settings
Authors: Livio Bioglio
Mathieu Génois
Christian L. Vestergaard
Chiara Poletto
Alain Barrat
Vittoria Colizza
Publication date: 01-12-2016
Publisher: BioMed Central
Published in: BMC Infectious Diseases / Issue 1/2016
Electronic ISSN: 1471-2334
DOI: https://doi.org/10.1186/s12879-016-2003-3

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