The recurrence of influenza A epidemics has originally been explained by a ‘‘continuous antigenic drift’ ’ scenario. Recently, it has been shown that if genetic drift is gradual, the evolution of influenza A main antigen, the haemagglutinin, is punctuated. As a consequence, it has been suggested that influenza A dynamics at the population level should be approximated by a serial SIR model. Here, simple models are used to test whether a serial SIR model requires gradual antigenic drift within groups of strains with the same antigenic properties (antigenic clusters). We compare the effect of status based and history based frameworks and the influence of reduced susceptibility and infectivity assumptions on the transient dynamics of antigenic ...
Understanding the seasonal/periodic reoccurrence of influenza will be very helpful in designing suc-...
The accumulation of cross-immunity in the host population is an important factor driving the antigen...
The enigmatic observation that the rapidly evolving influenza A (H3N2) virus exhibits, at any given ...
The recurrence of influenza A epidemics has originally been explained by a "continuous antigenic dri...
The recurrence of influenza A epidemics has originally been explained by a "continuous antigenic dri...
online Article Number: e7426International audienceThe recurrence of influenza A epidemics has origin...
The main objective of the thesis is to implement a mathematical epidemic model developed by Koelle e...
Since influenza in humans is a major public health threat, the understanding of its dynamics and evo...
Influenza in humans is characterised by strongly annual dynamics and antigenic evolution leading to ...
We use a mathematical model to study the evolution of influenza A during the epidemic dynamics of a ...
We use a mathematical model to study the evolution of influenza A during the epidemic dynamics of a ...
We use a mathematical model to study the evolution of influenza A during the epidemic dynamics of a ...
Influenza in humans is characterised by strongly annual dynamics and antigenic evolution leading to ...
In this paper we explore the consequences of a heterogeneous immune response in individuals on the e...
Abstract Background Since its emergence in 1968, infl...
Understanding the seasonal/periodic reoccurrence of influenza will be very helpful in designing suc-...
The accumulation of cross-immunity in the host population is an important factor driving the antigen...
The enigmatic observation that the rapidly evolving influenza A (H3N2) virus exhibits, at any given ...
The recurrence of influenza A epidemics has originally been explained by a "continuous antigenic dri...
The recurrence of influenza A epidemics has originally been explained by a "continuous antigenic dri...
online Article Number: e7426International audienceThe recurrence of influenza A epidemics has origin...
The main objective of the thesis is to implement a mathematical epidemic model developed by Koelle e...
Since influenza in humans is a major public health threat, the understanding of its dynamics and evo...
Influenza in humans is characterised by strongly annual dynamics and antigenic evolution leading to ...
We use a mathematical model to study the evolution of influenza A during the epidemic dynamics of a ...
We use a mathematical model to study the evolution of influenza A during the epidemic dynamics of a ...
We use a mathematical model to study the evolution of influenza A during the epidemic dynamics of a ...
Influenza in humans is characterised by strongly annual dynamics and antigenic evolution leading to ...
In this paper we explore the consequences of a heterogeneous immune response in individuals on the e...
Abstract Background Since its emergence in 1968, infl...
Understanding the seasonal/periodic reoccurrence of influenza will be very helpful in designing suc-...
The accumulation of cross-immunity in the host population is an important factor driving the antigen...
The enigmatic observation that the rapidly evolving influenza A (H3N2) virus exhibits, at any given ...