Predicting outbreaks: a spatial risk assessment of West Nile virus in British Columbia Export

@article{Tachiiri2006_wnv_predict, abstract = {Background West Nile virus (WNv) has recently emerged as a health threat to the North American population. After the initial disease outbreak in New York City in 1999, WNv has spread widely and quickly across North America to every contiguous American state and Canadian province, with the exceptions of British Columbia (BC), Prince Edward Island and Newfoundland. In this study we develop models of mosquito population dynamics for Culex tarsalis and C. pipiens, and create a spatial risk assessment of WNv prior to its arrival in BC by creating a raster-based mosquito abundance model using basic geographic and temperature data. Among the parameters included in the model are spatial factors determined from the locations of BC Centre for Disease Control mosquito traps (e.g., distance of the trap from the closest wetland or lake), while other parameters were obtained from the literature. Factors not considered in the current assessment but which could influence the results are also discussed. Results Since the model performs much better for C. tarsalis than for C. pipiens, the risk assessment is carried out using the output of C. tarsalis model. The result of the spatially-explicit mosquito abundance model indicates that the Okanagan Valley, the Thompson Region, Greater Vancouver, the Fraser Valley and southeastern Vancouver Island have the highest potential abundance of the mosquitoes. After including human population data, Greater Vancouver, due to its high population density, increases in significance relative to the other areas. Conclusion Creating a raster-based mosquito abundance map enabled us to quantitatively evaluate WNv risk throughout BC and to identify the areas of greatest potential risk, prior to WNv introduction. In producing the map important gaps in our knowledge related to mosquito ecology in BC were identified, as well, it became evident that increased efforts in bird and mosquito surveillance are required if more accurate models and maps are to be produced. Access to real time climatic data is the key for developing a real time early warning system for forecasting vector borne disease outbreaks, while including social factors is important when producing a detailed assessment in urban areas.}, author = {Tachiiri, Kaoru and Klinkenberg, Brian and Mak, Sunny and Kazmi, Jamil}, citeulike-article-id = {686054}, citeulike-linkout-0 = {http://dx.doi.org/10.1186/1476-072X-5-21}, citeulike-linkout-1 = {http://view.ncbi.nlm.nih.gov/pubmed/16704737}, citeulike-linkout-2 = {http://www.hubmed.org/display.cgi?uids=16704737}, comment = {http://www.biomedcentral.com/content/supplementary/1476-072X-5-21-S1.xls}, day = {16}, doi = {10.1186/1476-072X-5-21}, issn = {1476-072X}, journal = {International Journal of Health Geographics}, keywords = {culex, disease, gdd, mosquito, mosquito-borne, risk, spatial, west-nile}, month = {May}, number = {1}, pages = {21+}, posted-at = {2009-02-17 12:21:48}, priority = {2}, title = {Predicting outbreaks: a spatial risk assessment of West Nile virus in British Columbia}, url = {http://dx.doi.org/10.1186/1476-072X-5-21}, volume = {5}, year = {2006} }

TY - JOUR ID - Tachiiri2006_wnv_predict L3 - citeulike-article-id:686054 N2 - Background West Nile virus (WNv) has recently emerged as a health threat to the North American population. After the initial disease outbreak in New York City in 1999, WNv has spread widely and quickly across North America to every contiguous American state and Canadian province, with the exceptions of British Columbia (BC), Prince Edward Island and Newfoundland. In this study we develop models of mosquito population dynamics for Culex tarsalis and C. pipiens, and create a spatial risk assessment of WNv prior to its arrival in BC by creating a raster-based mosquito abundance model using basic geographic and temperature data. Among the parameters included in the model are spatial factors determined from the locations of BC Centre for Disease Control mosquito traps (e.g., distance of the trap from the closest wetland or lake), while other parameters were obtained from the literature. Factors not considered in the current assessment but which could influence the results are also discussed. Results Since the model performs much better for C. tarsalis than for C. pipiens, the risk assessment is carried out using the output of C. tarsalis model. The result of the spatially-explicit mosquito abundance model indicates that the Okanagan Valley, the Thompson Region, Greater Vancouver, the Fraser Valley and southeastern Vancouver Island have the highest potential abundance of the mosquitoes. After including human population data, Greater Vancouver, due to its high population density, increases in significance relative to the other areas. Conclusion Creating a raster-based mosquito abundance map enabled us to quantitatively evaluate WNv risk throughout BC and to identify the areas of greatest potential risk, prior to WNv introduction. In producing the map important gaps in our knowledge related to mosquito ecology in BC were identified, as well, it became evident that increased efforts in bird and mosquito surveillance are required if more accurate models and maps are to be produced. Access to real time climatic data is the key for developing a real time early warning system for forecasting vector borne disease outbreaks, while including social factors is important when producing a detailed assessment in urban areas. IS - 1 JF - International Journal of Health Geographics SN - 1476-072X TI - Predicting outbreaks: a spatial risk assessment of West Nile virus in British Columbia VL - 5 SP - 21 KW - culex KW - disease KW - gdd KW - mosquito KW - mosquito-borne KW - risk KW - spatial KW - west-nile N1 - http://www.biomedcentral.com/content/supplementary/1476-072X-5-21-S1.xls AU - Tachiiri, Kaoru AU - Klinkenberg, Brian AU - Mak, Sunny AU - Kazmi, Jamil PY - 2006/05/16/ UR - http://dx.doi.org/10.1186/1476-072X-5-21 ER -