Climate is one of the drivers of transmission; however, other factors such as control interventions and socio-economic development can influence the disease dynamics. During the first phase of the project, we developed statistical and mathematical models to quantify the contribution of climatic and non-climatic factors to malaria and evaluate the benefit of mathematical transmission models to outbreak forecasting compared to statistical models. Data from the HDSS in Kisumu showed that temperature has a protective effect similar to the effect of insecticide treated bed net use, but this is opposed by rainfall. These relations varied across seasonal scales. The high correlations between climatic factors and non-linear relations to malaria made it difficult to have always-consistent results from statistical models which are able to estimate associations but neither identify causal relations nor take into account non-linear interactions of the malaria drivers. The non-stationarity of the malaria data and varying effect of predictors across seasons suggested that forecasting models should perform better when non-stationarity is relaxed. The overarching goal of the follow up project is to deepen our understanding of the effects of climate change on the burden of malaria by innovating methods that address the non-linear interactions of the malaria drivers on the transmission dynamics and the non-stationarity of the data. The specific objectives are to: (i) assess time-delayed causal effects of climatic and non-climatic factors on the changes of malaria incidence across different time scales and levels of transmission; (ii) develop age-structured stochastic metapopulation malaria transmission models which incorporate climate and control intervention effects; (iii) develop non-stationary model formulations for short and medium-term malaria forecasts taking into account climate variation across time-scales; and (iv) evaluate the performance of the new tools on common datasets and their computational feasibility of implementation within a model-based early warning system. We will accomplish these specific objectives by (a) employing and further developing methods to assess causality in time series data and to forecast coupling wavelets with machine learning and dynamic, time delay embedding models; (b) using powerful computational algorithms such as iterated filtering, particle Markov chain Monte Carlo (pMCMC) and Hamiltonian Monte Carlo (HMC) simulation; and (c) analysing existing data from the HDSS in Nouna (Burkina Faso) and Kisumu (Kenya), the Health Information System in Burkina Faso and Kenya, outputs of downscaled climate models, high resolution hydrometeorological data, satellite-based climatic products and other gridded environmental proxies.

DFG Programme Research Units

Subproject of FOR 2936:  Climate Change and Health in Sub-Saharan Africa

International Connection Burkina Faso, Kenya, Switzerland

Partner Organisation Schweizerischer Nationalfonds (SNF)

Cooperation Partners Dr. Stephen Munga, Ph.D.; Dr. Ali Sié, Ph.D.