doi: 10.3390/ijerph10051698.
A rainfall- and temperature-driven abundance model for Aedes albopictus populations
Affiliations
- PMID: 23624579
- PMCID: PMC3709343
- DOI: 10.3390/ijerph10051698
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A rainfall- and temperature-driven abundance model for Aedes albopictus populations
Int J Environ Res Public Health.
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Abstract
The mosquito Aedes (Stegomyia) albopictus (Skuse) (Diptera: Culicidae) is an invasive species which has colonized Southern Europe in the last two decades. As it is a competent vector for several arboviruses, its spread is of increasing public health concern, and there is a need for appropriate monitoring tools. In this paper, we have developed a modelling approach to predict mosquito abundance over time, and identify the main determinants of mosquito population dynamics. The model is temperature- and rainfall-driven, takes into account egg diapause during unfavourable periods, and was used to model the population dynamics of Ae. albopictus in the French Riviera since 2008. Entomological collections of egg stage from six locations in Nice conurbation were used for model validation. We performed a sensitivity analysis to identify the key parameters of the mosquito population dynamics. Results showed that the model correctly predicted entomological field data (Pearson r correlation coefficient values range from 0.73 to 0.93). The model's main control points were related to adult's mortality rates, the carrying capacity in pupae of the environment, and the beginning of the unfavourable period. The proposed model can be efficiently used as a tool to predict Ae. albopictus population dynamics, and to assess the efficiency of different control strategies.
Figures
Study area including the municipalities of Nice, La Gaude, Cagnes-sur-Mer, Villeneuve-Loubet, and Biot. Source: © IGN BD Adresse v2—EID Méditerranée, September 2011.
Model diagram of Aedes albopictus population dynamics in temperate climate. Aquatic stages are drawn in blue, adult females in yellow. The green compartments indicate the adult females which move to seek for a host or an oviposition site. Adapted from Cailly et al. [17]. Reprinted from Ecological Modelling, 227/24 February 2012, Cailly, P.; Tran, A.; Balenghien, T.; L’Ambert, G.; Toty, C.; Ezanno, P., A climate-driven abundance model to assess mosquito control strategies, Pages 7–17, Copyright (2012), with permission from Elsevier.
Aedes albopictus population dynamics simulated over four years according to temperatures and rainfall, Nice region, 2008–2011. (a) Daily mean temperature (red) and rainfall (blue). (b) Simulated number of individuals in the aquatic stages (eggs, larvae and pupae). (c) Simulated number of individuals in the aerial stages (A1h: nulliparous host-seeking; A1g: nulliparous engorged; A1o: nulliparous seeking oviposition site; A2h: parous host-seeking; A2g: parous engorged; A2o: parous seeking oviposition site). The alternation of favorable and unfavorable periods is represented in white and grey, respectively.
Model validation. (a) The simulated dynamics of eggs laid at time t El(t) (black line) based on observed temperatures and precipitations from 2008 to 2011 was compared to the mean number of eggs collected per ovitrap in Nice-city area (red dots) using relative abundances. The alternation of favorable and unfavorable periods is represented in white and grey, respectively. (b) Simulated and observed eggs abundances, Nice area, 2010–2011. Symbols represent the observed mosquito abundance data in the different sites, and the black line is the simulated mosquito abundance.
Contribution of model parameters to model output variance. Only parameters contributing to more than 1% of output variance were retained here. No interaction was retained.
Variations of model outputs (in lines) with parameters contributing to more than 10% of their variance (in columns): 3 levels were tested per factor (nominal value ±10%). For each considered parameter and model output, a box-and-whisker diagram graphically depicts the maximum, minimum, median, lower and upper quartiles values of the model output obtained from the simulations with three different levels of the parameter tested.
Aedes albopictus adult population dynamics with an egg hatching function driven either by rainfall or artificial flooding. Simulations were computed for different thresholds applied to daily rainfall for triggering egg hatching (P > 0 mm, P > 2 mm, and P > 4 mm).
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References
-
- Mitchell C.J. The role of Aedes albopictus as an arbovirus vector. Parassitologia. 1995;37:109–113. - PubMed
-
- European Network for Arthropod Vector Surveillance for Human Public Health (ECDC VBORNET) [(accessed on 11 March 2013)]. Available online: http://www.vbornet.eu/index.php?p=11.
-
- Delaunay P., Mathieu B., Marty P., Fauran P., Schaffner F. Chronology of the development of Aedes albopictus in the Alpes-Maritimes Department of France, from 2002 to 2005. Med. Trop. 2007;67:310–311. - PubMed
-
- ECDC Guidelines for the Surveillance of Invasive Mosquitoes in Europe. [(accessed on 12 March 2013)]. Available online: http://ecdc.europa.eu/en/publications/Publications/TER-Mosquito-surveill....
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