Abstract
Given the considerable challenges to the rapid development of an effective vaccine against influenza, antiviral agents will play an important role as a first-line defense if a new pandemic occurs. The large-scale use of drugs for chemoprophylaxis and treatment will impose strong selection for the evolution of drug-resistant strains. The ensuing transmission of those strains could substantially limit the effectiveness of the drugs as a first-line defense. Summarizing recent data on the rate at which the treatment of influenza infection generates resistance de novo and on the transmission fitness of resistant virus, we discuss possible implications for the epidemiological spread of drug resistance in the context of an established population dynamic model.
Publication types
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Research Support, Non-U.S. Gov't
MeSH terms
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Acetamides / pharmacology
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Acetamides / therapeutic use
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Amantadine / pharmacology
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Amantadine / therapeutic use
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Antiviral Agents / pharmacology*
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Antiviral Agents / therapeutic use*
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Computer Simulation
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Disease Outbreaks
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Drug Resistance, Viral* / genetics
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Humans
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Influenza A virus / drug effects*
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Influenza A virus / genetics
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Influenza A virus / pathogenicity
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Influenza, Human / drug therapy*
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Influenza, Human / epidemiology
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Influenza, Human / prevention & control*
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Influenza, Human / virology
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Mathematics
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Models, Biological
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Mutation
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Neuraminidase / antagonists & inhibitors
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Orthomyxoviridae / drug effects*
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Orthomyxoviridae / genetics
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Orthomyxoviridae / pathogenicity
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Oseltamivir
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Population Dynamics
Substances
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Acetamides
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Antiviral Agents
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Oseltamivir
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Amantadine
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Neuraminidase