<p>Parameters: Lattice size = 21×21, <i>r</i><sub><i>A</i></sub> = 1.0, 〈<i>r</i><sub><i>B</i></sub>〉 = 1.5, <i>m</i><sub><i>A</i></sub> = 0 (Spatial model in the presence of migration of mutants only).</p
<p>Comparison of invasion probabilities- Analytical and Simulated values for bimodal distributions o...
Populations in spatially structured environments may be divided into a number of (semi-) isolated su...
Spatial heterogeneity greatly affects the population spread. Although the theory for biolo...
<p>Parameters: Lattice size = 21×21, <i>r</i><sub><i>A</i></sub> = 1.0, 〈<i>r</i><sub><i>B</i></sub>...
<p>Parameters: Lattice size = 21×21, <i>r</i><sub><i>A</i></sub> = 1.0, <i>m</i><sub><i>A</i></sub> ...
Numerous experimental studies have demonstrated that the microenvironment is a key regulator influen...
<p>(a) Random distribution of two types of sites with high and low fitness’s for mutant cells. (b) E...
In this work we discuss a spatial evolutionary model for a heterogeneous cancer cell population. We ...
<p>(a) is the initial number of individuals. The square lattice is composed of , and only takes va...
We consider a spatial (line) model for invasion of a population by a single mutant with a stochastic...
Background: We study the selection dynamics in a heterogeneous spatial colony of cells. We use two s...
<p>Proportion of the mutant is calculated as the number of hosts infected by the mutant parasite div...
International audienceWe analyze the role of the spatial distribution of the initial condition in re...
<p>These show that invasion speeds are the same when (i) morphs have asymmetrical mutation rates, (i...
We consider spatial population dynamics on a lattice, following a type of a contact (birth–death) st...
<p>Comparison of invasion probabilities- Analytical and Simulated values for bimodal distributions o...
Populations in spatially structured environments may be divided into a number of (semi-) isolated su...
Spatial heterogeneity greatly affects the population spread. Although the theory for biolo...
<p>Parameters: Lattice size = 21×21, <i>r</i><sub><i>A</i></sub> = 1.0, 〈<i>r</i><sub><i>B</i></sub>...
<p>Parameters: Lattice size = 21×21, <i>r</i><sub><i>A</i></sub> = 1.0, <i>m</i><sub><i>A</i></sub> ...
Numerous experimental studies have demonstrated that the microenvironment is a key regulator influen...
<p>(a) Random distribution of two types of sites with high and low fitness’s for mutant cells. (b) E...
In this work we discuss a spatial evolutionary model for a heterogeneous cancer cell population. We ...
<p>(a) is the initial number of individuals. The square lattice is composed of , and only takes va...
We consider a spatial (line) model for invasion of a population by a single mutant with a stochastic...
Background: We study the selection dynamics in a heterogeneous spatial colony of cells. We use two s...
<p>Proportion of the mutant is calculated as the number of hosts infected by the mutant parasite div...
International audienceWe analyze the role of the spatial distribution of the initial condition in re...
<p>These show that invasion speeds are the same when (i) morphs have asymmetrical mutation rates, (i...
We consider spatial population dynamics on a lattice, following a type of a contact (birth–death) st...
<p>Comparison of invasion probabilities- Analytical and Simulated values for bimodal distributions o...
Populations in spatially structured environments may be divided into a number of (semi-) isolated su...
Spatial heterogeneity greatly affects the population spread. Although the theory for biolo...
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