Open AccessReal-time characterization of the molecular epidemiology of an influenza pandemic
Author(s) -
Jessica Hedge,
Samantha Lycett,
Andrew Rambaut
Publication year - 2013
Publication title -
biology letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.596
H-Index - 110
eISSN - 1744-957X
pISSN - 1744-9561
DOI - 10.1098/rsbl.2013.0331
Subject(s) - pandemic , biology , coalescent theory , bayesian probability , influenza pandemic , bayes' theorem , evolutionary biology , approximate bayesian computation , genome , viral phylodynamics , phylogenetics , range (aeronautics) , computational biology , statistics , covid-19 , genetics , computer science , artificial intelligence , infectious disease (medical specialty) , mathematics , materials science , pathology , medicine , disease , inference , composite material , gene
Early characterization of the epidemiology and evolution of a pandemic is essential for determining the most appropriate interventions. During the 2009 H1N1 influenza A pandemic, public databases facilitated widespread sharing of genetic sequence data from the outset. We use Bayesian phylogenetics to simulate real-time estimates of the evolutionary rate, date of emergence and intrinsic growth rate ( r 0 ) of the pandemic from whole-genome sequences. We investigate the effects of temporal range of sampling and dataset size on the precision and accuracy of parameter estimation. Parameters can be accurately estimated as early as two months after the first reported case, from 100 genomes and the choice of growth model is important for accurate estimation of r 0 . This demonstrates the utility of simple coalescent models to rapidly inform intervention strategies during a pandemic.
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