Generation of swine movement network and analysis of efficient mitigation strategies for African swine fever virus

Animal movement networks are essential in understanding and containing the spread of infectious diseases in farming industries. Due to its confidential nature, movement data for the US swine farming population is not readily available. Hence, we propose a method to generate such networks from limite...

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Veröffentlicht in:	PloS one 2019-12, Vol.14 (12), p.e0225785-e0225785
Hauptverfasser:	Ferdousi, Tanvir, Moon, Sifat Afroj, Self, Adrian, Scoglio, Caterina
Format:	Artikel
Sprache:	eng
Schlagworte:	African swine fever African Swine Fever - prevention & control African Swine Fever - virology African Swine Fever Virus - physiology Algorithms Animals Asfarviridae Biology and Life Sciences Computer and Information Sciences Computer engineering Disease control Disease Outbreaks - veterinary Disease spread Epidemics Epidemiology Farming Farms Fever Hogs Infectious diseases Livestock Medicine and Health Sciences Minnesota Mitigation Mortality Networks Pork Public domain Swine Time Factors Transportation Vaccination Veterinary medicine Viruses
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creator	Ferdousi, Tanvir Moon, Sifat Afroj Self, Adrian Scoglio, Caterina
description	Animal movement networks are essential in understanding and containing the spread of infectious diseases in farming industries. Due to its confidential nature, movement data for the US swine farming population is not readily available. Hence, we propose a method to generate such networks from limited data available in the public domain. As a potentially devastating candidate, we simulate the spread of African swine fever virus (ASFV) in our generated network and analyze how the network structure affects the disease spread. We find that high in-degree farm operations (i.e., markets) play critical roles in the disease spread. We also find that high in-degree based targeted isolation and hypothetical vaccinations are more effective for disease control compared to other centrality-based mitigation strategies. The generated networks can be made more robust by validation with more data whenever more movement data will be available.
doi_str_mv	10.1371/journal.pone.0225785
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subjects	African swine fever African Swine Fever - prevention & control African Swine Fever - virology African Swine Fever Virus - physiology Algorithms Animals Asfarviridae Biology and Life Sciences Computer and Information Sciences Computer engineering Disease control Disease Outbreaks - veterinary Disease spread Epidemics Epidemiology Farming Farms Fever Hogs Infectious diseases Livestock Medicine and Health Sciences Minnesota Mitigation Mortality Networks Pork Public domain Swine Time Factors Transportation Vaccination Veterinary medicine Viruses
title	Generation of swine movement network and analysis of efficient mitigation strategies for African swine fever virus
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