Literature DB >> 25181466

A method for detecting and characterizing outbreaks of infectious disease from clinical reports.

Gregory F Cooper1, Ricardo Villamarin2, Fu-Chiang Rich Tsui2, Nicholas Millett2, Jeremy U Espino2, Michael M Wagner2.   

Abstract

Outbreaks of infectious disease can pose a significant threat to human health. Thus, detecting and characterizing outbreaks quickly and accurately remains an important problem. This paper describes a Bayesian framework that links clinical diagnosis of individuals in a population to epidemiological modeling of disease outbreaks in the population. Computer-based diagnosis of individuals who seek healthcare is used to guide the search for epidemiological models of population disease that explain the pattern of diagnoses well. We applied this framework to develop a system that detects influenza outbreaks from emergency department (ED) reports. The system diagnoses influenza in individuals probabilistically from evidence in ED reports that are extracted using natural language processing. These diagnoses guide the search for epidemiological models of influenza that explain the pattern of diagnoses well. Those epidemiological models with a high posterior probability determine the most likely outbreaks of specific diseases; the models are also used to characterize properties of an outbreak, such as its expected peak day and estimated size. We evaluated the method using both simulated data and data from a real influenza outbreak. The results provide support that the approach can detect and characterize outbreaks early and well enough to be valuable. We describe several extensions to the approach that appear promising.
Copyright © 2014 Elsevier Inc. All rights reserved.

Entities:  

Keywords:  Bayesian modeling; Clinical reports; Infectious disease; Outbreak characterization; Outbreak detection

Mesh:

Year:  2014        PMID: 25181466      PMCID: PMC4441330          DOI: 10.1016/j.jbi.2014.08.011

Source DB:  PubMed          Journal:  J Biomed Inform        ISSN: 1532-0464            Impact factor:   6.317


  24 in total

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8.  Probabilistic, Decision-theoretic Disease Surveillance and Control.

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Review 3.  Public Health, Population Health, and Epidemiology Informatics: Recent Research and Trends in the United States.

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6.  A Bayesian system to detect and characterize overlapping outbreaks.

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7.  Dynamic graph and polynomial chaos based models for contact tracing data analysis and optimal testing prescription.

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8.  A study of the transferability of influenza case detection systems between two large healthcare systems.

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9.  A Bayesian approach for detecting a disease that is not being modeled.

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  10 in total

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