HIV can spread through its target cell population either via cell-free transmission, or by cell-to-cell transmission, presumably through virological synapses. Synaptic transmission entails the transfer of tens to hundreds of viruses per synapse, a fraction of which successfully integrate into the target cell genome. It is currently not understood how synaptic transmission affects viral fitness. Using a mathematical model, we investigate how different synaptic transmission strategies, defined by the number of viruses passed per synapse, influence the basic reproductive ratio of the virus, R(0), and virus load. In the most basic scenario, the model suggests that R(0) is maximized if a single virus particle is transferred per synapse. R(0) dec...
The spread of viral infections can be initiated by the release of cell-free virus particles that inf...
In this work, we created three mathematical models to describe HIV infection. Our goal was to invest...
In this work, we created three mathematical models to describe HIV infection. Our goal was to invest...
HIV can spread through its target cell population either via cell-free transmission, or by cell-to-c...
Recombination in HIV infection can impact virus evolution in vivo in complex ways, as has been shown...
We study the contributions of within-host (virus-to-cell) and synaptic (cell-to-cell) transmissions ...
In this dissertation three mathematical studies on the evolution of human immunodeficiency virus (HI...
Although cell-to-cell HIV transmission was defined in early 90's, in the last five years, several gr...
In this work, we explore the in vivo population dynamics of HIV with mathematical and computational ...
HIV-1 can move directly between T cells via virological synapses (VS). Although aspects of the molec...
HIV-1 can move directly between T cells via virological synapses (VS). Although aspects of the molec...
AbstractHIV-1 can move directly between T cells via virological synapses (VS). Although aspects of t...
Recombination has been shown to contribute to human immunodeficiency virus-1 (HIV-1) evolution in vi...
<p>Here, uninfected cells are represented by white circles, infected cell by shaded circles, and vir...
HIV-1 is believed to spread by two mechanisms in an infected host: by cell-free virions and by cell-...
The spread of viral infections can be initiated by the release of cell-free virus particles that inf...
In this work, we created three mathematical models to describe HIV infection. Our goal was to invest...
In this work, we created three mathematical models to describe HIV infection. Our goal was to invest...
HIV can spread through its target cell population either via cell-free transmission, or by cell-to-c...
Recombination in HIV infection can impact virus evolution in vivo in complex ways, as has been shown...
We study the contributions of within-host (virus-to-cell) and synaptic (cell-to-cell) transmissions ...
In this dissertation three mathematical studies on the evolution of human immunodeficiency virus (HI...
Although cell-to-cell HIV transmission was defined in early 90's, in the last five years, several gr...
In this work, we explore the in vivo population dynamics of HIV with mathematical and computational ...
HIV-1 can move directly between T cells via virological synapses (VS). Although aspects of the molec...
HIV-1 can move directly between T cells via virological synapses (VS). Although aspects of the molec...
AbstractHIV-1 can move directly between T cells via virological synapses (VS). Although aspects of t...
Recombination has been shown to contribute to human immunodeficiency virus-1 (HIV-1) evolution in vi...
<p>Here, uninfected cells are represented by white circles, infected cell by shaded circles, and vir...
HIV-1 is believed to spread by two mechanisms in an infected host: by cell-free virions and by cell-...
The spread of viral infections can be initiated by the release of cell-free virus particles that inf...
In this work, we created three mathematical models to describe HIV infection. Our goal was to invest...
In this work, we created three mathematical models to describe HIV infection. Our goal was to invest...