Efficient real-time monitoring of an emerging influenza pandemic: How feasible?

Paul J. Birrell; Lorenz Wernisch; Brian D.M. Tom; Leonhard Held; Gareth O. Roberts; Richard Pebody; Daniela De Angelis

doi:10.1214/19-AOAS1278

Efficient real-time monitoring of an emerging influenza pandemic: How feasible?

Paul J. Birrell, Lorenz Wernisch, Brian D.M. Tom, Leonhard Held, Gareth O. Roberts, Richard Pebody, Daniela De Angelis

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

12 Citations (Scopus)

Abstract

A prompt public health response to a new epidemic relies on the ability to monitor and predict its evolution in real time as data accumulate. The 2009 A/H1N1 outbreak in the UK revealed pandemic data as noisy, contaminated, potentially biased and originating from multiple sources. This seriously challenges the capacity for real-time monitoring. Here, we assess the feasibility of real-time inference based on such data by constructing an analytic tool combining an age-stratified SEIR transmission model with various observa-tion models describing the data generation mechanisms. As batches of data become available, a sequential Monte Carlo (SMC) algorithm is developed to synthesise multiple imperfect data streams, iterate epidemic inferences and assess model adequacy amidst a rapidly evolving epidemic environment, substantially reducing computation time in comparison to standard MCMC, to ensure timely delivery of real-time epidemic assessments. In application to simulated data designed to mimic the 2009 A/H1N1 epidemic, SMC is shown to have additional benefits in terms of assessing predictive performance and coping with parameter nonidentifiability.

Original language	English
Pages (from-to)	74-93
Number of pages	20
Journal	Annals of Applied Statistics
Volume	14
Issue number	1
DOIs	https://doi.org/10.1214/19-AOAS1278
Publication status	Published - Mar 2020

Bibliographical note

Funding Information: The first, fifth and seventh authors were supported in part by the National Institute for Health Research (HTA Project:11/46/03). The second, third and seventh authors were supported by the UK Medical Research Council (programme codes MC_UU_00002/1, MC_UU_00002/2, and MC_UU_00002/11).

Open Access: Free to read, but no Open Access licence.

Publisher Copyright: © Institute of Mathematical Statistics, 2020.

Citation: Birrell, Paul J., et al. "Efficient real-time monitoring of an emerging influenza pandemic: How feasible?." The Annals of Applied Statistics 14.1 (2020): 74-93.

DOI: 10.1214/19-AOAS1278

Keywords

Pandemic influenza
Real-time inference
Resample-move
SEIR transmission model
Sequential Monte Carlo

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1214/19-AOAS1278

Cite this

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title = "Efficient real-time monitoring of an emerging influenza pandemic: How feasible?",

abstract = "A prompt public health response to a new epidemic relies on the ability to monitor and predict its evolution in real time as data accumulate. The 2009 A/H1N1 outbreak in the UK revealed pandemic data as noisy, contaminated, potentially biased and originating from multiple sources. This seriously challenges the capacity for real-time monitoring. Here, we assess the feasibility of real-time inference based on such data by constructing an analytic tool combining an age-stratified SEIR transmission model with various observa-tion models describing the data generation mechanisms. As batches of data become available, a sequential Monte Carlo (SMC) algorithm is developed to synthesise multiple imperfect data streams, iterate epidemic inferences and assess model adequacy amidst a rapidly evolving epidemic environment, substantially reducing computation time in comparison to standard MCMC, to ensure timely delivery of real-time epidemic assessments. In application to simulated data designed to mimic the 2009 A/H1N1 epidemic, SMC is shown to have additional benefits in terms of assessing predictive performance and coping with parameter nonidentifiability.",

keywords = "Pandemic influenza, Real-time inference, Resample-move, SEIR transmission model, Sequential Monte Carlo",

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note = "Funding Information: The first, fifth and seventh authors were supported in part by the National Institute for Health Research (HTA Project:11/46/03). The second, third and seventh authors were supported by the UK Medical Research Council (programme codes MC\_UU\_00002/1, MC\_UU\_00002/2, and MC\_UU\_00002/11). Open Access: Free to read, but no Open Access licence. Publisher Copyright: {\textcopyright} Institute of Mathematical Statistics, 2020. Citation: Birrell, Paul J., et al. {"}Efficient real-time monitoring of an emerging influenza pandemic: How feasible?.{"} The Annals of Applied Statistics 14.1 (2020): 74-93. DOI: 10.1214/19-AOAS1278",

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AU - Tom, Brian D.M.

AU - Held, Leonhard

AU - Roberts, Gareth O.

AU - Pebody, Richard

AU - Angelis, Daniela De

N1 - Funding Information: The first, fifth and seventh authors were supported in part by the National Institute for Health Research (HTA Project:11/46/03). The second, third and seventh authors were supported by the UK Medical Research Council (programme codes MC_UU_00002/1, MC_UU_00002/2, and MC_UU_00002/11). Open Access: Free to read, but no Open Access licence. Publisher Copyright: © Institute of Mathematical Statistics, 2020. Citation: Birrell, Paul J., et al. "Efficient real-time monitoring of an emerging influenza pandemic: How feasible?." The Annals of Applied Statistics 14.1 (2020): 74-93. DOI: 10.1214/19-AOAS1278

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N2 - A prompt public health response to a new epidemic relies on the ability to monitor and predict its evolution in real time as data accumulate. The 2009 A/H1N1 outbreak in the UK revealed pandemic data as noisy, contaminated, potentially biased and originating from multiple sources. This seriously challenges the capacity for real-time monitoring. Here, we assess the feasibility of real-time inference based on such data by constructing an analytic tool combining an age-stratified SEIR transmission model with various observa-tion models describing the data generation mechanisms. As batches of data become available, a sequential Monte Carlo (SMC) algorithm is developed to synthesise multiple imperfect data streams, iterate epidemic inferences and assess model adequacy amidst a rapidly evolving epidemic environment, substantially reducing computation time in comparison to standard MCMC, to ensure timely delivery of real-time epidemic assessments. In application to simulated data designed to mimic the 2009 A/H1N1 epidemic, SMC is shown to have additional benefits in terms of assessing predictive performance and coping with parameter nonidentifiability.

AB - A prompt public health response to a new epidemic relies on the ability to monitor and predict its evolution in real time as data accumulate. The 2009 A/H1N1 outbreak in the UK revealed pandemic data as noisy, contaminated, potentially biased and originating from multiple sources. This seriously challenges the capacity for real-time monitoring. Here, we assess the feasibility of real-time inference based on such data by constructing an analytic tool combining an age-stratified SEIR transmission model with various observa-tion models describing the data generation mechanisms. As batches of data become available, a sequential Monte Carlo (SMC) algorithm is developed to synthesise multiple imperfect data streams, iterate epidemic inferences and assess model adequacy amidst a rapidly evolving epidemic environment, substantially reducing computation time in comparison to standard MCMC, to ensure timely delivery of real-time epidemic assessments. In application to simulated data designed to mimic the 2009 A/H1N1 epidemic, SMC is shown to have additional benefits in terms of assessing predictive performance and coping with parameter nonidentifiability.

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KW - Resample-move

KW - SEIR transmission model

KW - Sequential Monte Carlo

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Efficient real-time monitoring of an emerging influenza pandemic: How feasible?

Abstract

Bibliographical note

Keywords

UN SDGs

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