A multi-region discrete time chain binomial model for infectious disease transmission

Conventional mathematical models of infectious diseases often overlook the spatial spread of the disease, focusing only on local transmission. However, spatial propagation of various diseases has been observed mainly due to the movement of infectious individuals from one geographical region to another. In this work, we propose a multiregion discrete-time chain binomial framework to model the dependencies between the multiple infection time series from neighboring regions. It is assumed that infection counts in each region at various time points are governed not only by local transmissions but also by interactions of individuals between spatial units. The effects of intervention strategies such as vaccination campaigns used in disease control and various other sociodemographic factors such as live births, population density, vaccination coverage, and disruption in disease surveillance have been taken into account while modeling multiple infection time series. For estimating these multiregion chain-binomial models, an appropriate likelihood function maximization approach is proposed. Simulation results considering effects of seasonal pattern in disease outbreaks, out-of-sync outbreaks in connected geographical regions, variations in interventions have been considered to depict realistic disease scenarios. Forecasting of spatial infections have also been studied. A real world application based on measles counts from adjoining spatial regions is presented to motivate the proposed modeling approach.