Nonlinear effects of noise on outbreaks of mosquito-borne diseases

Mosquito-borne diseases are a significant and growing public health burden globally. Predictions about the future spread and impact of mosquito-borne disease outbreaks can help inform direct control and prevention measures. However, climate change is expected to increase weather variability, which may shape the future of mosquito-borne disease outbreaks globally. In this study, we sought to determine the effects of demographic and environmental noise (stochasticity) on the duration and size of outbreaks predicted by models of mosquito-borne disease. We developed a demographically and environmentally stochastic Ross-Macdonald model to assess how noise affects the probability of an outbreak, the peak number of cases, and the duration of outbreaks at increasing levels of the basic reproduction number ( R ₀ ) and environmental noise strength. Increasing environmental noise lowers the risk of endemic disease from 100% down to almost 0%, but the largest outbreaks occur at intermediate environmental noise levels. In this case, if an outbreak dies out, it ends quickly. With noise present, R ₀ alone is insufficient to predict definitively whether an outbreak occurs. Surprisingly, our model suggests that increasing environmental noise may reduce the risk of endemic disease and epidemics due to more frequent extreme conditions dramatically affecting mosquito populations.