Abstract
Heterogeneous mixing fundam entally changes the dynamics of infectious diseases; finding ways to incorporate it into models represents a critical challenge. Phenomenological approaches are deficient in their lack of attention to underlying processes; individual-based models, on the other hand, may obscure the essential interactions in a sea of detail. The challenge then is to find ways to bridge these levels of description, starting from individual-based models and deriving macroscopic descriptions from them that retain essential detail, and filter out the rest. In this paper, attempts to achieve this transformation are described for a class of models where nonrandom mixing arises from the spatial localization of interactions. In general, the epidemic threshold is found to be larger owing to spatial localization than for a homogeneously mixing population. An improved estimate of the dynamics is developed by the use of moment equations, and a simple estimate of the threshold in terms of a ‘dyad heuristic’. For more general models in which local infection is not described by mass action, the connection with related partial differential equations is investigated.
Subject
General Agricultural and Biological Sciences,General Biochemistry, Genetics and Molecular Biology
Reference25 articles.
1. The dynamics of simultaneous infections with altered susceptibilities
2. Susceptible-infected-removed epidemic models with dynamic partnerships. J. math;Altmann M.;Biol.,1995
3. Anderson R. M. & May R. M. 1991 Infectious diseases of humans: dynamics and control. Oxford: Oxford Science Publications.
4. Bolker B. M. & Pacala S. W. 1996 Understanding stochastically driven spatial pattern formation in ecological systems using moment equations. Theor. Popul. Biol. (Submitted).
5. a Results on the dynamics for models for the sexual transmission of the, human immunodeficiency virus. Appl. math;Castillo-Chavez C.;Lett.,1989
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