About: We formulate an epidemic model for the spread of an infectious disease along with population dispersal over an arbitrary number of distinct regions. Structuring the population by the time elapsed since the start of travel, we describe the infectious disease dynamics during transportation as well as in the regions. As a result, we obtain a system of delay differential equations. We define the basic reproduction number [Formula: see text] as the spectral radius of a next generation matrix. For multi-regional systems with strongly connected transportation networks, we prove that if [Formula: see text] then the disease will be eradicated from each region, while if [Formula: see text] there is a globally asymptotically stable equilibrium, which is endemic in every region. If the transportation network is not strongly connected, then the model analysis shows that numerous endemic patterns can exist by admitting a globally asymptotically stable equilibrium, which may be disease free in some regions while endemic in other regions. We provide a procedure to detect the disease free and the endemic regions according to the network topology and local reproduction numbers. The main ingredients of the mathematical proofs are the inductive applications of the theory of asymptotically autonomous semiflows and cooperative dynamical systems. We visualise stability boundaries of equilibria in a parameter plane to illustrate the influence of the transportation network on the disease dynamics. For a system consisting of two regions, we find that due to spatial heterogeneity characterised by different local reproduction numbers, [Formula: see text] may depend non-monotonically on the dispersal rates, thus travel restrictions are not always beneficial.   Goto Sponge  NotDistinct  Permalink

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  • We formulate an epidemic model for the spread of an infectious disease along with population dispersal over an arbitrary number of distinct regions. Structuring the population by the time elapsed since the start of travel, we describe the infectious disease dynamics during transportation as well as in the regions. As a result, we obtain a system of delay differential equations. We define the basic reproduction number [Formula: see text] as the spectral radius of a next generation matrix. For multi-regional systems with strongly connected transportation networks, we prove that if [Formula: see text] then the disease will be eradicated from each region, while if [Formula: see text] there is a globally asymptotically stable equilibrium, which is endemic in every region. If the transportation network is not strongly connected, then the model analysis shows that numerous endemic patterns can exist by admitting a globally asymptotically stable equilibrium, which may be disease free in some regions while endemic in other regions. We provide a procedure to detect the disease free and the endemic regions according to the network topology and local reproduction numbers. The main ingredients of the mathematical proofs are the inductive applications of the theory of asymptotically autonomous semiflows and cooperative dynamical systems. We visualise stability boundaries of equilibria in a parameter plane to illustrate the influence of the transportation network on the disease dynamics. For a system consisting of two regions, we find that due to spatial heterogeneity characterised by different local reproduction numbers, [Formula: see text] may depend non-monotonically on the dispersal rates, thus travel restrictions are not always beneficial.
subject
  • Epidemiology
  • Biodiversity
  • Network topology
  • Habitat
  • Decentralization
  • Biology terminology
  • Differential equations
  • Endemism
  • Stability theory
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