The threshold infection level for Wolbachia invasion in a two-sex mosquito population model
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Publication:2002126
DOI10.1007/s11538-019-00620-1zbMath1417.92182OpenAlexW3032908614WikidataQ92507318 ScholiaQ92507318MaRDI QIDQ2002126
Publication date: 11 July 2019
Published in: Bulletin of Mathematical Biology (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1007/s11538-019-00620-1
Epidemiology (92D30) Bifurcation theory for ordinary differential equations (34C23) Qualitative investigation and simulation of ordinary differential equation models (34C60)
Related Items (8)
The impact of incomplete cytoplasmic incompatibility on mosquito population suppression by \textit{Wolbachia} ⋮ Modeling the impact of migration on mosquito population suppression ⋮ Finding Strategies to Regulate Propagation and Containment of Dengue via Invariant Manifold Analysis ⋮ Analysis and control of \textit{Aedes aegypti} mosquitoes using sterile-insect techniques with \textit{Wolbachia} ⋮ Dynamics of a two-sex model for the population ecology of dengue mosquitoes in the presence of \textit{Wolbachia} ⋮ Releasing Wolbachia-infected mosquitos to mitigate the transmission of Zika virus ⋮ \textit{Wolbachia} infection dynamics in mosquito population with the CI effect suffering by uninfected ova produced by infected females ⋮ Optimal control of dengue vector based on a reaction-diffusion model
Cites Work
- Constraints on the use of lifespan-shortening \textit{Wolbachia} to control dengue fever
- Modelling a wolbachia invasion using a slow-fast dispersal reaction-diffusion approach
- Modelling the use of \textit{Wolbachia} to control dengue fever transmission
- Birth-pulse models of \textit{Wolbachia}-induced cytoplasmic incompatibility in mosquitoes for dengue virus control
- Modeling the effects of augmentation strategies on the control of dengue fever with an impulsive differential equation
- Structured and unstructured continuous models for \(Wolbachia\) infections
- Variance based sensitivity analysis of model output. Design and estimator for the total sensitivity index
- Stage-structured models of intra- and inter-specific competition within age classes
- Models to assess how best to replace dengue virus vectors with \textit{Wolbachia}-infected mosquito populations
- Deploying dengue-suppressing \textit{Wolbachia} : robust models predict slow but effective spatial spread in \textit{Aedes aegypti}
- The threshold infection level for \textit{Wolbachia} invasion in random environments
- Ensuring successful introduction of \textit{Wolbachia} in natural populations of \textit{Aedes aegypti} by means of feedback control
- Optimal control approach for establishing wMelpop Wolbachia infection among wild Aedes aegypti populations
- Reproduction numbers and sub-threshold endemic equilibria for compartmental models of disease transmission
- Infection dynamics of different \textit{Wolbachia}-types within one host population
- Modelling the transmission dynamics of dengue in the presence of \textit{Wolbachia}
- Modelling \textit{Wolbachia} infection in a sex-structured mosquito population carrying West Nile virus
- The Mathematics of Infectious Diseases
- ModelingWolbachiaSpread in Mosquitoes Through Delay Differential Equations
- Two-sex mosquito model for the persistence ofWolbachia
- New revised simple models for interactive wild and sterile mosquito populations and their dynamics
- MODELLING THE INTRODUCTION OF WOLBACHIA INTO AEDES AEGYPTI MOSQUITOES TO REDUCE DENGUE TRANSMISSION
- Global sensitivity indices for nonlinear mathematical models and their Monte Carlo estimates
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