Modeling the complex hatching and development of Aedes aegypti in temperate climates

Here, we present and discuss a compartmental stochastic model for Aedes aegypti conceived as a mathematical structure able to interpolate and extrapolate (predict) biological phenomena, and direct the attention to biological matters that need experimental elucidation. The model incorporates weather...

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Autores principales: Otero, Marcelo Javier, De Majo, María Sol, Fischer, Sylvia Cristina, Solari, Hernán Gustavo
Publicado: 2013
Materias:
Bacteria
Food
Local strains
Rain
Stochastic model
Temperature
Adult populations
Aedes aegypti
Biological matter
Biological phenomena
Control methods
Daily temperatures
Egg hatching
Environmental conditions
Field record
Larval density
Larval development
Local characteristics
Local populations
Mathematical structure
Physiological parameters
Standard procedures
Temperate climate
Weather information
Winter seasons
Climatology
Drought
Food products
Stochastic models
Strain
Physiological models
bacterium
drought
environmental conditions
food availability
hatching
inhibition
larva
mortality
mosquito
physiological response
pupation
rainfall
stochasticity
temperate environment
temperature effect
winter
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_03043800_v253_n_p44_RomeoAznar
http://hdl.handle.net/20.500.12110/paper_03043800_v253_n_p44_RomeoAznar
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id paper:paper_03043800_v253_n_p44_RomeoAznar
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spelling paper:paper_03043800_v253_n_p44_RomeoAznar2023-06-08T15:29:17Z Modeling the complex hatching and development of Aedes aegypti in temperate climates Otero, Marcelo Javier De Majo, María Sol Fischer, Sylvia Cristina Solari, Hernán Gustavo Bacteria Food Local strains Rain Stochastic model Temperature Adult populations Aedes aegypti Biological matter Biological phenomena Control methods Daily temperatures Egg hatching Environmental conditions Field record Larval density Larval development Local characteristics Local populations Local strains Mathematical structure Physiological parameters Standard procedures Temperate climate Weather information Winter seasons Bacteria Climatology Drought Food products Rain Stochastic models Strain Temperature Physiological models bacterium drought environmental conditions food availability hatching inhibition larva mortality mosquito physiological response pupation rainfall stochasticity temperate environment temperature effect winter Here, we present and discuss a compartmental stochastic model for Aedes aegypti conceived as a mathematical structure able to interpolate and extrapolate (predict) biological phenomena, and direct the attention to biological matters that need experimental elucidation. The model incorporates weather information in the form of daily temperatures and rain and pays particular attention to determining factors in temperate climates. Sufficiently large rains trigger egg hatching, which in turn leads to peaks in larval densities. Hatching is inhibited by the absence of bacteria (Gillett effect), a mechanism of relevance during the winter season and in seasons with isolated rains. The model also incorporates egg hatching independent of rains. Both egg hatching and larval development depend on the availability of food, which is modeled as bacteria produced at rates that depend on the temperature. Larval mortality and pupation rates depend on the larvae to bacteria ratio. The results of the model for egg laying activity were compared with field records during a normal season and a drought. Both the model and the records indicate that the egg laying activity of Ae. aegypti is not zero during the drought and recovers quickly when normal weather is reestablished. We studied the sensitivity of the model to different sets of physiological parameters published for a few different local populations of this species, and found that there is an important sensitivity to local characteristics that will affect some predictions of the model. We emphasize that if the information is going to be used to evaluate control methods, the life cycle of the mosquito must be studied for the local strain under the local environmental conditions (including food). We showed that the adult populations produced by the model are insensitive to certain combinations of parameters and that this insensitivity is related to the variability reported for different strains obtained from closely located places. When the model is considered in a larger biological context, it indicates that some standard procedures performed to measure the life cycle of Ae. aegypti in the laboratory might have a determining influence in the results. © 2013 Elsevier B.V. Fil:Otero, M. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:De Majo, M.S. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Fischer, S. 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. 2013 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_03043800_v253_n_p44_RomeoAznar http://hdl.handle.net/20.500.12110/paper_03043800_v253_n_p44_RomeoAznar
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Bacteria
Food
Local strains
Rain
Stochastic model
Temperature
Adult populations
Aedes aegypti
Biological matter
Biological phenomena
Control methods
Daily temperatures
Egg hatching
Environmental conditions
Field record
Larval density
Larval development
Local characteristics
Local populations
Local strains
Mathematical structure
Physiological parameters
Standard procedures
Temperate climate
Weather information
Winter seasons
Bacteria
Climatology
Drought
Food products
Rain
Stochastic models
Strain
Temperature
Physiological models
bacterium
drought
environmental conditions
food availability
hatching
inhibition
larva
mortality
mosquito
physiological response
pupation
rainfall
stochasticity
temperate environment
temperature effect
winter
spellingShingle Bacteria
Food
Local strains
Rain
Stochastic model
Temperature
Adult populations
Aedes aegypti
Biological matter
Biological phenomena
Control methods
Daily temperatures
Egg hatching
Environmental conditions
Field record
Larval density
Larval development
Local characteristics
Local populations
Local strains
Mathematical structure
Physiological parameters
Standard procedures
Temperate climate
Weather information
Winter seasons
Bacteria
Climatology
Drought
Food products
Rain
Stochastic models
Strain
Temperature
Physiological models
bacterium
drought
environmental conditions
food availability
hatching
inhibition
larva
mortality
mosquito
physiological response
pupation
rainfall
stochasticity
temperate environment
temperature effect
winter
Otero, Marcelo Javier
De Majo, María Sol
Fischer, Sylvia Cristina
Solari, Hernán Gustavo
Modeling the complex hatching and development of Aedes aegypti in temperate climates
topic_facet Bacteria
Food
Local strains
Rain
Stochastic model
Temperature
Adult populations
Aedes aegypti
Biological matter
Biological phenomena
Control methods
Daily temperatures
Egg hatching
Environmental conditions
Field record
Larval density
Larval development
Local characteristics
Local populations
Local strains
Mathematical structure
Physiological parameters
Standard procedures
Temperate climate
Weather information
Winter seasons
Bacteria
Climatology
Drought
Food products
Rain
Stochastic models
Strain
Temperature
Physiological models
bacterium
drought
environmental conditions
food availability
hatching
inhibition
larva
mortality
mosquito
physiological response
pupation
rainfall
stochasticity
temperate environment
temperature effect
winter
description Here, we present and discuss a compartmental stochastic model for Aedes aegypti conceived as a mathematical structure able to interpolate and extrapolate (predict) biological phenomena, and direct the attention to biological matters that need experimental elucidation. The model incorporates weather information in the form of daily temperatures and rain and pays particular attention to determining factors in temperate climates. Sufficiently large rains trigger egg hatching, which in turn leads to peaks in larval densities. Hatching is inhibited by the absence of bacteria (Gillett effect), a mechanism of relevance during the winter season and in seasons with isolated rains. The model also incorporates egg hatching independent of rains. Both egg hatching and larval development depend on the availability of food, which is modeled as bacteria produced at rates that depend on the temperature. Larval mortality and pupation rates depend on the larvae to bacteria ratio. The results of the model for egg laying activity were compared with field records during a normal season and a drought. Both the model and the records indicate that the egg laying activity of Ae. aegypti is not zero during the drought and recovers quickly when normal weather is reestablished. We studied the sensitivity of the model to different sets of physiological parameters published for a few different local populations of this species, and found that there is an important sensitivity to local characteristics that will affect some predictions of the model. We emphasize that if the information is going to be used to evaluate control methods, the life cycle of the mosquito must be studied for the local strain under the local environmental conditions (including food). We showed that the adult populations produced by the model are insensitive to certain combinations of parameters and that this insensitivity is related to the variability reported for different strains obtained from closely located places. When the model is considered in a larger biological context, it indicates that some standard procedures performed to measure the life cycle of Ae. aegypti in the laboratory might have a determining influence in the results. © 2013 Elsevier B.V.
author Otero, Marcelo Javier
De Majo, María Sol
Fischer, Sylvia Cristina
Solari, Hernán Gustavo
author_facet Otero, Marcelo Javier
De Majo, María Sol
Fischer, Sylvia Cristina
Solari, Hernán Gustavo
author_sort Otero, Marcelo Javier
title Modeling the complex hatching and development of Aedes aegypti in temperate climates
title_short Modeling the complex hatching and development of Aedes aegypti in temperate climates
title_full Modeling the complex hatching and development of Aedes aegypti in temperate climates
title_fullStr Modeling the complex hatching and development of Aedes aegypti in temperate climates
title_full_unstemmed Modeling the complex hatching and development of Aedes aegypti in temperate climates
title_sort modeling the complex hatching and development of aedes aegypti in temperate climates
publishDate 2013
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_03043800_v253_n_p44_RomeoAznar
http://hdl.handle.net/20.500.12110/paper_03043800_v253_n_p44_RomeoAznar
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