Periodic forcing in a three level cellular automata model for a vector transmitted disease

TL;DR

This paper presents a three-level cellular automata model for vector-borne diseases like dengue, incorporating seasonal forcing, mobility, and control measures, successfully reproducing real epidemic data and revealing complex spatiotemporal dynamics.

Contribution

The study introduces a novel three-level cellular automata model that captures the effects of seasonality, mobility, and control on dengue epidemics, aligning well with actual data.

Findings

Model reproduces dengue epidemic patterns in Brazilian cities.

External periodic forcing significantly affects epidemic dynamics.

Mobility influences the epidemic threshold transition behavior.

Abstract

The transmission of vector infectious diseases, which produces complex spatiotemporal patterns, is analyzed by a periodically forced two-dimensional cellular automata model. The system, which comprises three population levels, is introduced to describe complex features of the dynamics of the vector transmitted dengue epidemics, known to be very sensitive to seasonal variables. The three coupled levels represent the human, the adult and immature vector populations. The dynamics includes external seasonality forcing (rainfall intensity data), human and mosquito mobility, and vector control effects. The model parameters, even if bounded to well defined intervals obtained from reported data, can be selected to reproduce specific epidemic outbursts. In the current study, explicit results are obtained by comparison with actual data retrieved from the time-series of dengue epidemics in two cities in Brazil. The results show fluctuations that are not captured by mean-field models. It also reveals the qualitative behavior of the spatiotemporal patterns of the epidemics. In the extreme situation of absence of external periodic drive, the model predicts completely distinct long time evolution. The model is robust in the sense that it is able to reproduce the time series of dengue epidemics of different cities, provided the forcing term takes into account the local rainfall modulation. Finally, the dependence between epidemics threshold and vector control undergoes a transition from power law to stretched exponential behavior due to human mobility effect.