Semi-empirical power-law scaling of new infection rate to model epidemic dynamics with inhomogeneous mixing

Semi-empirical power-law scaling of new infection rate to model epidemic dynamics with inhomogeneous mixing

The expected number of new infections per day per infectious person during an epidemic has been found to exhibit power-law scaling with respect to the susceptible fraction of the population. This is in contrast to the linear scaling assumed in traditional epidemiologic modeling. Based on simulated e...

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Veröffentlicht in:Mathematical biosciences 2006-10, Vol.203 (2), p.301-318
Hauptverfasser: Stroud, Phillip D., Sydoriak, Stephen J., Riese, Jane M., Smith, James P., Mniszewski, Susan M., Romero, Phillip R.
Format: Artikel
Sprache:eng
Schlagworte:
Chicago - epidemiology
Computer Simulation
Disease Outbreaks
Epidemic dynamics
Epidemic model
Epidemiologic Methods
Homogeneous mixing
Humans
Incidence
Influenza, Human - epidemiology
Influenza, Human - transmission
Los Angeles - epidemiology
Models, Statistical
Orthomyxoviridae - growth & development
Population Dynamics
Power law
Urban Population
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Zusammenfassung:The expected number of new infections per day per infectious person during an epidemic has been found to exhibit power-law scaling with respect to the susceptible fraction of the population. This is in contrast to the linear scaling assumed in traditional epidemiologic modeling. Based on simulated epidemic dynamics in synthetic populations representing Los Angeles, Chicago, and Portland, we find city-dependent scaling exponents in the range of 1.7–2.06. This scaling arises from variations in the strength, duration, and number of contacts per person. Implementation of power-law scaling of the new infection rate is quite simple for SIR, SEIR, and histogram-based epidemic models. Treatment of the effects of the social contact structure through this power-law formulation leads to significantly lower predictions of final epidemic size than the traditional linear formulation.
ISSN:0025-5564
1879-3134
DOI:10.1016/j.mbs.2006.01.007