Abstract
This work develops a methodology for estimating risk of wind-borne introduction of flying insects into a country, identifying areas and periods of high risk of vector-borne diseases incursion. This risk can be characterized by the role of suitable temperatures and wind currents in small insects’ survival and movements, respectively. The model predicts the number density of introduced insects over space and time based on three processes: the advection due to wind currents, the deposition on the ground and the survival due to climatic conditions. Spanish livestock has suffered many bluetongue outbreaks since 2004 and numerous experts point to Culicoides transported by wind from affected areas in North Africa as a possible cause. This work implements numerical experiments simulating the introduction of Culicoides in 2004. The model identified southern and eastern Spain, particularly between June and November, as being at greatest risk of wind-borne Culicoides introduction, which matches field data on bluetongue outbreaks in Spain this year. This validation suggests that this model may be useful for predicting introduction of airborne pathogens of significance to animal productivity.
Highlights
Introduction of vector-borne diseases can substantially harm public and animal health, causing significant sanitary and financial loss
We developed a methodology for estimating risk of long-range wind-borne transport and deposition of small insects, while taking into account the likelihood of insect survival given certain climatic conditions
Introduction of Culicoides from North Africa to Spain, in order to explain the bluetongue outbreaks that occurred in this territory during 2004
Summary
Introduction of vector-borne diseases can substantially harm public and animal health, causing significant sanitary and financial loss. Long-range wind-borne transportation of infected flying insects has previously been linked to the introduction of viruses affecting humans and/ or animals such as West Nile virus, dengue or Rift Valley fever. Modeling the movement of wind-borne midges or mosquitoes may help identify geographic regions and seasons at higher risk of incursion of several arboviral diseases, improving surveillance efforts. Advection-deposition-survival model to assess the risk of introduction of bluetongue in Spain. European Regional Development Fund (project P12-TIC301); and the MOMAT research group (Ref. 910480), supported by the Universidad Complutense de Madrid. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript
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