A stochastic spatial dynamical model for Aedes aegypti

We develop a stochastic spatial model for Aedes aegypti populations based on the life cycle of the mosquito and its dispersal. Our validation corresponds to a monitoring study performed in Buenos Aires. Lacking information with regard to the number of breeding sites per block, the corresponding para...

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Autores principales:	Otero, M., Schweigmann, N., Solari, H.G.
Formato:	JOUR
Materias:	Aedes aegypti Aedes aegypti dispersal Dengue epidemics Mathematical ecology Population dynamics Spatial model Stochastic model Temperate climate Aedes algorithm animal Argentina article biological model city computer simulation dengue egg laying environment female physiology population dynamics season statistics weather Algorithms Animals Cities Computer Simulation Dengue Environment Female Models, Biological Oviposition Population Dynamics Seasons Stochastic Processes Weather
Acceso en línea:	http://hdl.handle.net/20.500.12110/paper_00928240_v70_n5_p1297_Otero
Aporte de:	Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires

id	todo:paper_00928240_v70_n5_p1297_Otero
record_format	dspace
spelling	todo:paper_00928240_v70_n5_p1297_Otero2023-10-03T14:55:19Z A stochastic spatial dynamical model for Aedes aegypti Otero, M. Schweigmann, N. Solari, H.G. Aedes aegypti Aedes aegypti dispersal Dengue epidemics Mathematical ecology Population dynamics Spatial model Stochastic model Temperate climate Aedes algorithm animal Argentina article biological model city computer simulation dengue egg laying environment female physiology population dynamics season statistics weather Aedes Algorithms Animals Argentina Cities Computer Simulation Dengue Environment Female Models, Biological Oviposition Population Dynamics Seasons Stochastic Processes Weather Aedes aegypti We develop a stochastic spatial model for Aedes aegypti populations based on the life cycle of the mosquito and its dispersal. Our validation corresponds to a monitoring study performed in Buenos Aires. Lacking information with regard to the number of breeding sites per block, the corresponding parameter (BS) was adjusted to the data. The model is able to produce numerical data in very good agreement with field results during most of the year, the exception being the fall season. Possible causes of the disagreement are discussed. We analyzed the mosquito dispersal as an advantageous strategy of persistence in the city and simulated the dispersal of females from a source to the surroundings along a 3-year period observing that several processes occur simultaneously: local extinctions, recolonization processes (resulting from flight and the oviposition performed by flyers), and colonization processes resulting from the persistence of eggs during the winter season. In view of this process, we suggest that eradication campaigns in temperate climates should be performed during the winter time for higher efficiency. © 2008 Society for Mathematical Biology. Fil:Otero, M. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Schweigmann, N. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Solari, H.G. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_00928240_v70_n5_p1297_Otero
institution	Universidad de Buenos Aires
institution_str	I-28
repository_str	R-134
collection	Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic	Aedes aegypti Aedes aegypti dispersal Dengue epidemics Mathematical ecology Population dynamics Spatial model Stochastic model Temperate climate Aedes algorithm animal Argentina article biological model city computer simulation dengue egg laying environment female physiology population dynamics season statistics weather Aedes Algorithms Animals Argentina Cities Computer Simulation Dengue Environment Female Models, Biological Oviposition Population Dynamics Seasons Stochastic Processes Weather Aedes aegypti
spellingShingle	Aedes aegypti Aedes aegypti dispersal Dengue epidemics Mathematical ecology Population dynamics Spatial model Stochastic model Temperate climate Aedes algorithm animal Argentina article biological model city computer simulation dengue egg laying environment female physiology population dynamics season statistics weather Aedes Algorithms Animals Argentina Cities Computer Simulation Dengue Environment Female Models, Biological Oviposition Population Dynamics Seasons Stochastic Processes Weather Aedes aegypti Otero, M. Schweigmann, N. Solari, H.G. A stochastic spatial dynamical model for Aedes aegypti
topic_facet	Aedes aegypti Aedes aegypti dispersal Dengue epidemics Mathematical ecology Population dynamics Spatial model Stochastic model Temperate climate Aedes algorithm animal Argentina article biological model city computer simulation dengue egg laying environment female physiology population dynamics season statistics weather Aedes Algorithms Animals Argentina Cities Computer Simulation Dengue Environment Female Models, Biological Oviposition Population Dynamics Seasons Stochastic Processes Weather Aedes aegypti
description	We develop a stochastic spatial model for Aedes aegypti populations based on the life cycle of the mosquito and its dispersal. Our validation corresponds to a monitoring study performed in Buenos Aires. Lacking information with regard to the number of breeding sites per block, the corresponding parameter (BS) was adjusted to the data. The model is able to produce numerical data in very good agreement with field results during most of the year, the exception being the fall season. Possible causes of the disagreement are discussed. We analyzed the mosquito dispersal as an advantageous strategy of persistence in the city and simulated the dispersal of females from a source to the surroundings along a 3-year period observing that several processes occur simultaneously: local extinctions, recolonization processes (resulting from flight and the oviposition performed by flyers), and colonization processes resulting from the persistence of eggs during the winter season. In view of this process, we suggest that eradication campaigns in temperate climates should be performed during the winter time for higher efficiency. © 2008 Society for Mathematical Biology.
format	JOUR
author	Otero, M. Schweigmann, N. Solari, H.G.
author_facet	Otero, M. Schweigmann, N. Solari, H.G.
author_sort	Otero, M.
title	A stochastic spatial dynamical model for Aedes aegypti
title_short	A stochastic spatial dynamical model for Aedes aegypti
title_full	A stochastic spatial dynamical model for Aedes aegypti
title_fullStr	A stochastic spatial dynamical model for Aedes aegypti
title_full_unstemmed	A stochastic spatial dynamical model for Aedes aegypti
title_sort	stochastic spatial dynamical model for aedes aegypti
url	http://hdl.handle.net/20.500.12110/paper_00928240_v70_n5_p1297_Otero
work_keys_str_mv	AT oterom astochasticspatialdynamicalmodelforaedesaegypti AT schweigmannn astochasticspatialdynamicalmodelforaedesaegypti AT solarihg astochasticspatialdynamicalmodelforaedesaegypti AT oterom stochasticspatialdynamicalmodelforaedesaegypti AT schweigmannn stochasticspatialdynamicalmodelforaedesaegypti AT solarihg stochasticspatialdynamicalmodelforaedesaegypti
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A stochastic spatial dynamical model for Aedes aegypti

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