Abstract
Background: The transmission of malaria is highly variable and depends on a range of climatic and anthropogenic factors. In addition, the dispersal of Anopheles mosquitoes is a key determinant that affects the persistence and dynamics of malaria. Simple, lumped-population models of malaria prevalence have been insufficient for predicting the complex responses of malaria to environmental changes. Methods and results: A stochastic lattice-based model that couples a mosquito dispersal and a susceptible-exposed-infected-recovered epidemics model was developed for predicting the dynamics of malaria in heterogeneous environments. The It $$\hat{o}$$ o ^ approximation of stochastic integrals with respect to Brownian motion was used to derive a model of stochastic differential equations. The results show that stochastic equations that capture uncertainties in the life cycle of mosquitoes and interactions among vectors, parasites, and hosts provide a mechanism for the disruptions of malaria. Finally, model simulations for a case study in the rural area of Kilifi county, Kenya are presented. Conclusions: A stochastic lattice-based integrated malaria model has been developed. The applicability of the model for capturing the climate-driven hydrologic factors and demographic variability on malaria transmission has been demonstrated.
Original language | English |
---|---|
Article number | 250 |
Journal | Malaria Journal |
Volume | 17 |
Issue number | 1 |
DOIs | |
State | Published - Jul 5 2018 |
Externally published | Yes |
Funding
PVVL received support from Computational Science and Engineering (CSE) fellowship. PK received support fromNSF (CBET1209402, ACI 1261582, EAR 1331906, EAR 1417444). We would like to thank people in Kumar research group at Ven Te Chow Hydrosystem Laboratory for their help andsupport with this study. The work also used the ROGER supercomputer, which is supported by NSF grant num-berACI 1429699.
Funders | Funder number |
---|---|
Computational Science and Engineering | |
National Science Foundation | 1261582, 1331906, 1417444, num-berACI 1429699, 1209402 |
National Science Foundation |
Keywords
- Climate change
- Ecohydrology
- Malaria
- Metapopulation
- Stochastic