Modeling and Detection of Respiratory-related Outbreak Signatures

Overview

Journal BMC Med Inform Decis Mak

Publisher Biomed Central

Specialty Medical Informatics

Date 2007 Oct 9

PMID 17919318

Citations 7

Authors

Peter F Craigmile

Namhee Kim

Soledad A Fernandez

Bema K Bonsu

Affiliations

Soon will be listed here.

Abstract

Background: Time series methods are commonly used to detect disease outbreak signatures (e.g., signals due to influenza outbreaks and anthrax attacks) from varying respiratory-related diagnostic or syndromic data sources. Typically this involves two components: (i) Using time series methods to model the baseline background distribution (the time series process that is assumed to contain no outbreak signatures), (ii) Detecting outbreak signatures using filter-based time series methods.

Methods: We consider time series models for chest radiograph data obtained from Midwest children's emergency departments. These models incorporate available covariate information such as patient visit counts and smoothed ambient temperature series, as well as time series dependencies on daily and weekly seasonal scales. Respiratory-related outbreak signature detection is based on filtering the one-step-ahead prediction errors obtained from the time series models for the respiratory-complaint background.

Results: Using simulation experiments based on a stochastic model for an anthrax attack, we illustrate the effect of the choice of filter and the statistical models upon radiograph-attributed outbreak signature detection.

Conclusion: We demonstrate the importance of using seasonal autoregressive integrated average time series models (SARIMA) with covariates in the modeling of respiratory-related time series data. We find some homogeneity in the time series models for the respiratory-complaint backgrounds across the Midwest emergency departments studied. Our simulations show that the balance between specificity, sensitivity, and timeliness to detect an outbreak signature differs by the emergency department and the choice of filter. The linear and exponential filters provide a good balance.

Citing Articles

The utility of LASSO-based models for real time forecasts of endemic infectious diseases: A cross country comparison.

Chen Y, Chu C, Chen M, Cook A J Biomed Inform. 2018; 81:16-30.

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Hopkins R, Tong C, Burkom H, Akkina J, Berezowski J, Shigematsu M Public Health Rep. 2017; 132(1_suppl):116S-126S.

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Validity and timeliness of syndromic influenza surveillance during the autumn/winter wave of A (H1N1) influenza 2009: results of emergency medical dispatch, ambulance and emergency department data from three European regions.

Rosenkotter N, Ziemann A, Riesgo L, Gillet J, Vergeiner G, Krafft T BMC Public Health. 2013; 13:905.

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Soyiri I, Reidpath D PLoS One. 2012; 7(10):e47823.

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Zhao Y, Zeng D, Herring A, Ising A, Waller A, Richardson D Biometrics. 2011; 67(4):1508-17.

PMID: 21418049 PMC: 3698245. DOI: 10.1111/j.1541-0420.2011.01585.x.

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