The Role of Geographic Spreaders in Infectious Pattern Formation and Front Propagation Speeds

Abstract

The pattern formation and spatial spread of infectious populations are investigated using a kernel-based Susceptible-Infectious-Recovered (SIR) model applicable across a wide range of basic reproduction numbers Ro. The focus is on the role of geographic spreaders defined here as a portion of the infected population (φ) experiencing high mobility between identical communities. The spatial organization of the infected population and invasive front speeds (cmax) are determined when the infections are randomly initiated in space within multiple communities. For small but finite φ, scaling analysis in 1-dimension and simulation results in 2-dimensions suggest that cmax (1-φ) γ (Ro-1) σ, where γ is the inverse of the infectious duration, and σ2 is the variance of the spatial kernel describing mobility of long-distance spreaders across communities. Hence, cmax is not significantly affected by the small φ though reductions in φ act as retardation factors to the attainment of cmax. The σ determines the spatial organization of infections across communities. When σ >5dr (long-distance mobility, where dr is the minimum spatial extent defining adjacent communities), the infectious population will experience a transient but spatially coherent pattern with a wavelength that can be derived from the spreading kernel properties.