%0 Journal Article %1 Peterson2005 %A Peterson, A. Townsend %A Martínez-Campos, Carmen %A Nakazawa, Yoshinori %A Martínez-Meyer, Enrique %D 2005 %J Transactions of the Royal Society of Tropical Medicine and Hygiene %K Remotesensing Mexico Spatiotemporalvariation Ecologicalnichemodeling Aedesaegypti Dengue GRASP %N 9 %P 647--655 %T Time-specific ecological niche modeling predicts spatial dynamics of vector insects and human dengue cases %U http://www.sciencedirect.com/science/article/B75GP-4GG8W3C-1/2/0f915525745bc1b224d35800062fb19b %V 99 %X Summary Numerous human diseases--malaria, dengue, yellow fever and leishmaniasis, to name a few--are transmitted by insect vectors with brief life cycles and biting activity that varies in both space and time. Although the general geographic distributions of these epidemiologically important species are known, the spatiotemporal variation in their emergence and activity remains poorly understood. We used ecological niche modeling via a genetic algorithm to produce time-specific predictive models of monthly distributions of Aedes aegypti in Mexico in 1995. Significant predictions of monthly mosquito activity and distributions indicate that predicting spatiotemporal dynamics of disease vector species is feasible; significant coincidence with human cases of dengue indicate that these dynamics probably translate directly into transmission of dengue virus to humans. This approach provides new potential for optimizing use of resources for disease prevention and remediation via automated forecasting of disease transmission risk.

@article{Peterson2005, abstract = {Summary Numerous human diseases--malaria, dengue, yellow fever and leishmaniasis, to name a few--are transmitted by insect vectors with brief life cycles and biting activity that varies in both space and time. Although the general geographic distributions of these epidemiologically important species are known, the spatiotemporal variation in their emergence and activity remains poorly understood. We used ecological niche modeling via a genetic algorithm to produce time-specific predictive models of monthly distributions of Aedes aegypti in Mexico in 1995. Significant predictions of monthly mosquito activity and distributions indicate that predicting spatiotemporal dynamics of disease vector species is feasible; significant coincidence with human cases of dengue indicate that these dynamics probably translate directly into transmission of dengue virus to humans. This approach provides new potential for optimizing use of resources for disease prevention and remediation via automated forecasting of disease transmission risk.}, added-at = {2010-01-14T17:48:22.000+0100}, author = {Peterson, A. Townsend and Martínez-Campos, Carmen and Nakazawa, Yoshinori and Martínez-Meyer, Enrique}, biburl = {https://www.bibsonomy.org/bibtex/2f86a87e217568d2c5f87f17ca5024c06/uvesco}, file = {:Peterson2005.pdf:PDF}, interhash = {44e6d4ec897b374b819e4f29d0fe4734}, intrahash = {f86a87e217568d2c5f87f17ca5024c06}, issn = {0035-9203}, journal = {Transactions of the Royal Society of Tropical Medicine and Hygiene}, keywords = {Remotesensing Mexico Spatiotemporalvariation Ecologicalnichemodeling Aedesaegypti Dengue GRASP}, month = {#sep#}, number = 9, pages = {647--655}, timestamp = {2010-01-14T17:48:22.000+0100}, title = {Time-specific ecological niche modeling predicts spatial dynamics of vector insects and human dengue cases}, url = {http://www.sciencedirect.com/science/article/B75GP-4GG8W3C-1/2/0f915525745bc1b224d35800062fb19b}, volume = 99, year = 2005 }