International audienceIn this work, we develop a mathematical framework for predicting and quantifying virus diversity evolution during infection of a host organism. It is specified as a virus density distribution with respect to genotype and time governed by a reaction-diffusion integro-differential equation taking virus mutations, replication, and elimination by immune cells and medical treatment into account. Conditions for the existence of virus strains that correspond to localized density distributions in the space of genotypes are determined. It is shown that common viral evolutionary traits like diversification and extinction are driven by nonlocal interactions via immune responses, target-cell competition, and therapy. This provides...
We consider two viral strains competing against each other within individual hosts (at cellular leve...
Chronic viral infections can persist for decades spanning thousands of viral generations, leading to...
We consider two viral strains competing against each other within individual hosts (at cellular leve...
International audienceIn this work, we develop a mathematical framework for predicting and quantifyi...
In this work, we develop a mathematical framework for predicting and quantifying virus diversity evo...
This work is devoted to the investigation of virus quasi-species evolution and diversification due t...
International audienceThis work is devoted to the investigation of virus quasi-species evolution and...
Virus density distribution as a function of genotype considered as a continuous variable and of time...
This work is devoted to the investigation of virus quasi-species evolution and diversification due t...
This work is devoted to the study of persistence and evolution of two viruses in the host organism t...
The paper is devoted to a nonlocal reaction-diffusion equation describing the development of viral i...
This paper is devoted to the study of persistence and evolution of two viruses taking into account v...
This article investigate a nonlocal reaction-diffusion system of equations modeling virus distributi...
Due to their very high replication and mutation rates, RNA viruses can serve as an excellent testing...
A new model of viral infection spreading in cell cultures is proposed taking into account virus muta...
We consider two viral strains competing against each other within individual hosts (at cellular leve...
Chronic viral infections can persist for decades spanning thousands of viral generations, leading to...
We consider two viral strains competing against each other within individual hosts (at cellular leve...
International audienceIn this work, we develop a mathematical framework for predicting and quantifyi...
In this work, we develop a mathematical framework for predicting and quantifying virus diversity evo...
This work is devoted to the investigation of virus quasi-species evolution and diversification due t...
International audienceThis work is devoted to the investigation of virus quasi-species evolution and...
Virus density distribution as a function of genotype considered as a continuous variable and of time...
This work is devoted to the investigation of virus quasi-species evolution and diversification due t...
This work is devoted to the study of persistence and evolution of two viruses in the host organism t...
The paper is devoted to a nonlocal reaction-diffusion equation describing the development of viral i...
This paper is devoted to the study of persistence and evolution of two viruses taking into account v...
This article investigate a nonlocal reaction-diffusion system of equations modeling virus distributi...
Due to their very high replication and mutation rates, RNA viruses can serve as an excellent testing...
A new model of viral infection spreading in cell cultures is proposed taking into account virus muta...
We consider two viral strains competing against each other within individual hosts (at cellular leve...
Chronic viral infections can persist for decades spanning thousands of viral generations, leading to...
We consider two viral strains competing against each other within individual hosts (at cellular leve...