Epidemic Process over the Commute Network in a Metropolitan Area
Authored by Kenta Yashima, Akira Sasaki
Date Published: 2014
DOI: 10.1371/journal.pone.0098518
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Abstract
An understanding of epidemiological dynamics is important for prevention
and control of epidemic outbreaks. However, previous studies tend to
focus only on specific areas, indicating that application to another
area or intervention strategy requires a similar time-consuming
simulation. Here, we study the epidemic dynamics of the disease-spread
over a commute network, using the Tokyo metropolitan area as an example, in an attempt to elucidate the general properties of epidemic spread
over a commute network that could be used for a prediction in any
metropolitan area. The model is formulated on the basis of a
metapopulation network in which local populations are interconnected by
actual commuter flows in the Tokyo metropolitan area and the spread of
infection is simulated by an individual-based model. We find that the
probability of a global epidemic as well as the final epidemic sizes in
both global and local populations, the timing of the epidemic peak, and
the time at which the epidemic reaches a local population are mainly
determined by the joint distribution of the local population sizes
connected by the commuter flows, but are insensitive to geographical or
topological structure of the network. Moreover, there is a strong
relation between the population size and the time that the epidemic
reaches this local population and we are able to determine the reason
for this relation as well as its dependence on the commute network
structure and epidemic parameters. This study shows that the model based
on the connection between the population size classes is sufficient to
predict both global and local epidemic dynamics in metropolitan area.
Moreover, the clear relation of the time taken by the epidemic to reach
each local population can be used as a novel measure for intervention;
this enables efficient intervention strategies in each local population
prior to the actual arrival.
Tags
Model
disease
Pandemic influenza
Strategies
Spread
Recurrent mobility patterns