The reproduction number $R_t$ in structured and nonstructured populations

The reproduction number $R_t$ in structured and nonstructured populations

Using daily counts of newly infected individuals, Wallinga and Teunis (WT) introduced aconceptually simple method to estimate the number of secondary cases per primary case ($R_t$)for a given day. The method requires an estimate of the generation interval probability density function (pdf),which sp...

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Bibliographic Details
Main Authors: Tom Burr, Gerardo Chowell
Format: Article
Language:English
Published: AIMS Press 2009-02-01
Series:Mathematical Biosciences and Engineering
Subjects:
reproduction number; generation interval; structured population.
Online Access:https://www.aimspress.com/article/doi/10.3934/mbe.2009.6.239
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Summary:Using daily counts of newly infected individuals, Wallinga and Teunis (WT) introduced aconceptually simple method to estimate the number of secondary cases per primary case ($R_t$)for a given day. The method requires an estimate of the generation interval probability density function (pdf),which specifies the probabilities for the times between symptom onset in a primary case and symptom onset ina corresponding secondary case. Other methods to estimate $R_t$ arebased on explicit models such as the SIR model; therefore, onemight expect the WT method to be more robust to departures from SIR-type behavior.This paper uses simulated data to compare the quality of daily $R_t$ estimates based on a SIR model tothose using the WT method for both structured(classical SIR assumptions are violated) and nonstructured (classical SIR assumptions hold) populations.By using detailed simulations that record the infection day of each new infectionand the donor-recipient identities, the true $R_t$ and the generation interval pdf isknown with negligible error. We find that the generation interval pdf is timedependent in all cases, which agrees with recent results reported elsewhere.We also find that the WT method performs essentially the samein the structured populations (except for a spatial network) as it does in the nonstructured population. And,the WT method does as well or better than a SIR-model based method in three of the four structured populations.Therefore, even if the contact patterns are heterogeneous as in the structured populations evaluated here,the WT method provides reasonable estimates of $R_t$, as does the SIR method.
ISSN:1551-0018

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