Bayesian uncertainty quantification for transmissibility of influenza, norovirus and Ebola using information geometry

Thomas House; Ashley  Ford; Shiwei  Lan; Samuel  Bilson; Elizabeth Buckingham-Jeffery; Mark  Girolami

doi:10.1098/rsif.2016.0279

Bayesian uncertainty quantification for transmissibility of influenza, norovirus and Ebola using information geometry

Thomas House
, Ashley Ford
, Shiwei Lan
, Samuel Bilson
, Elizabeth Buckingham-Jeffery
, Mark Girolami

University of Bristol
The University of Warwick

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

Abstract

Infectious diseases exert a large and in many contexts growing burden on human health, but violate most of the assumptions of classical epidemiological statistics and hence require a mathematically sophisticated approach. Viral shedding data are collected during human studies—either where volunteers are infected with a disease or where existing cases are recruited—in which the levels of live virus produced over time are measured. These have traditionally been difficult to analyse due to strong, complex correlations between parameters. Here, we show how a Bayesian approach to the inverse problem together with modern Markov chain Monte Carlo algorithms based on information geometry can overcome these difficulties and yield insights into the disease dynamics of two of the most prevalent human pathogens—influenza and norovirus—as well as Ebola virus disease.

Original language	English
Journal	Journal of the Royal Society Interface
Volume	13
Issue number	121
DOIs	https://doi.org/10.1098/rsif.2016.0279
Publication status	Published - 24 Aug 2016

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10.1098/rsif.2016.0279Licence: CC BY

Cite this

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AU - Ford, Ashley

AU - Lan , Shiwei

AU - Bilson, Samuel

AU - Buckingham-Jeffery, Elizabeth

AU - Girolami , Mark

PY - 2016/8/24

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AB - Infectious diseases exert a large and in many contexts growing burden on human health, but violate most of the assumptions of classical epidemiological statistics and hence require a mathematically sophisticated approach. Viral shedding data are collected during human studies—either where volunteers are infected with a disease or where existing cases are recruited—in which the levels of live virus produced over time are measured. These have traditionally been difficult to analyse due to strong, complex correlations between parameters. Here, we show how a Bayesian approach to the inverse problem together with modern Markov chain Monte Carlo algorithms based on information geometry can overcome these difficulties and yield insights into the disease dynamics of two of the most prevalent human pathogens—influenza and norovirus—as well as Ebola virus disease.

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JO - Journal of the Royal Society Interface

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ER -

Bayesian uncertainty quantification for transmissibility of influenza, norovirus and Ebola using information geometry

Abstract

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