Controlling viral outbreaks: Quantitative strategies

Preparing for and responding to outbreaks of serious livestock infectious diseases are critical measures to safeguard animal health, public health, and food supply. Almost all of the current control strategies are empirical, and mass culling or "stamping out" is frequently the principal st...

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Veröffentlicht in:	PloS one 2017-02, Vol.12 (2), p.e0171199-e0171199
Hauptverfasser:	Mummert, Anna, Weiss, Howard
Format:	Artikel
Sprache:	eng
Schlagworte:	Agricultural economics Animal health Animals Antiviral agents Antiviral drugs Avian flu Bacterial infections Biology and Life Sciences Birds Computer simulation Control methods Culling Disease control Disease Outbreaks - prevention & control Disease transmission Disinfection Economic models Epidemics Epidemiology Ethics Farms Food Food supply Foot & mouth disease Immunization Infections Infectious diseases Influenza A virus - pathogenicity Influenza in Birds - epidemiology Influenza in Birds - mortality Influenza in Birds - transmission Livestock Load distribution Medicine and Health Sciences Models, Theoretical Outbreaks People and Places Population decline Poultry Poultry - virology Poultry farming Prevention Public health Turkeys - virology Vaccination Veterinarians Veterinary medicine Viral Load Viruses Zoonoses
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description	Preparing for and responding to outbreaks of serious livestock infectious diseases are critical measures to safeguard animal health, public health, and food supply. Almost all of the current control strategies are empirical, and mass culling or "stamping out" is frequently the principal strategy for controlling epidemics. However, there are ethical, ecological, and economic reasons to consider less drastic control strategies. Here we use modeling to quantitatively study the efficacy of different control measures for viral outbreaks, where the infectiousness, transmissibility and death rate of animals commonly depends on their viral load. We develop a broad theoretical framework for exploring and understanding this heterogeneity. The model includes both direct transmission from infectious animals and indirect transmission from an environmental reservoir. We then incorporate a large variety of control measures, including vaccination, antivirals, isolation, environmental disinfection, and several forms of culling, which may result in fewer culled animals. We provide explicit formulae for the basic reproduction number, R0, for each intervention and for combinations. We evaluate the control methods for a realistic simulated outbreak of low pathogenic avian influenza on a mid-sized turkey farm. In this simulated outbreak, culling results in more total dead birds and dramatically more when culling all of the infected birds.
doi_str_mv	10.1371/journal.pone.0171199
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Almost all of the current control strategies are empirical, and mass culling or "stamping out" is frequently the principal strategy for controlling epidemics. However, there are ethical, ecological, and economic reasons to consider less drastic control strategies. Here we use modeling to quantitatively study the efficacy of different control measures for viral outbreaks, where the infectiousness, transmissibility and death rate of animals commonly depends on their viral load. We develop a broad theoretical framework for exploring and understanding this heterogeneity. The model includes both direct transmission from infectious animals and indirect transmission from an environmental reservoir. We then incorporate a large variety of control measures, including vaccination, antivirals, isolation, environmental disinfection, and several forms of culling, which may result in fewer culled animals. We provide explicit formulae for the basic reproduction number, R0, for each intervention and for combinations. We evaluate the control methods for a realistic simulated outbreak of low pathogenic avian influenza on a mid-sized turkey farm. In this simulated outbreak, culling results in more total dead birds and dramatically more when culling all of the infected birds.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>28187137</pmid><doi>10.1371/journal.pone.0171199</doi><tpages>e0171199</tpages><oa>free_for_read</oa></addata></record>
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subjects	Agricultural economics Animal health Animals Antiviral agents Antiviral drugs Avian flu Bacterial infections Biology and Life Sciences Birds Computer simulation Control methods Culling Disease control Disease Outbreaks - prevention & control Disease transmission Disinfection Economic models Epidemics Epidemiology Ethics Farms Food Food supply Foot & mouth disease Immunization Infections Infectious diseases Influenza A virus - pathogenicity Influenza in Birds - epidemiology Influenza in Birds - mortality Influenza in Birds - transmission Livestock Load distribution Medicine and Health Sciences Models, Theoretical Outbreaks People and Places Population decline Poultry Poultry - virology Poultry farming Prevention Public health Turkeys - virology Vaccination Veterinarians Veterinary medicine Viral Load Viruses Zoonoses
title	Controlling viral outbreaks: Quantitative strategies
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