This paper deals with a nonlinear system of partial differential equations modeling a simplified tumor-induced angiogenesis taking into account only the interplay between tumor angiogenic factors and endothelial cells. Considered model assumes a nonlinear flux at the tumor boundary and a nonlinear chemotactic response. It is proved that the choice of some key parameters influences the long-time behaviour of the system. More precisely, we show the convergence of solutions to different semi-trivial stationary states for different range of parameters.Polish Ministry of Science and Higher EducationMinisterio de Ciencia e InnovaciónFondo Europeo de Desarrollo Regiona
In this paper, we revisit the linear analysis of the transient evolution of a perturbed tumor interf...
AbstractA steady-state analysis of solutions of a generic model for capillary network formation is d...
AbstractWe consider a steady-state non-linear boundary value problem which arises in modelling the f...
In this paper we consider a parabolic problem as well as its stationary counterpart of a model arisi...
AbstractThe main goal of this paper is to study a stationary problem arising from angiogenesis, incl...
The main goal of this paper is to study a stationary problem arising from angiogenesis, including te...
This paper deals with a nonlinear system of partial differential equations modeling the effect of an...
We study a system of equations arising from angiogenesis which contains a nonregular term that vanis...
We present an iterative technique to construct stable solutions for an angiogenesis model set in an ...
AbstractWe propose a mathematical model that governs endothelial cell pattern formation on a biogel ...
To enrich the dynamics of three models, we introduced biologically motivated time-varying delays. Al...
Abstract: We deal with well known two kinds of mathematical models of tumour angiogenesis. We first ...
We study a robust finite difference scheme for integrodifferential kinetic systems of Fokker-Planck ...
We prove existence and uniqueness of nonnegative solutions for a nonlocal in time integrodifferentia...
AbstractAn analysis of a parabolic partial differential equation modelling capillary network formati...
In this paper, we revisit the linear analysis of the transient evolution of a perturbed tumor interf...
AbstractA steady-state analysis of solutions of a generic model for capillary network formation is d...
AbstractWe consider a steady-state non-linear boundary value problem which arises in modelling the f...
In this paper we consider a parabolic problem as well as its stationary counterpart of a model arisi...
AbstractThe main goal of this paper is to study a stationary problem arising from angiogenesis, incl...
The main goal of this paper is to study a stationary problem arising from angiogenesis, including te...
This paper deals with a nonlinear system of partial differential equations modeling the effect of an...
We study a system of equations arising from angiogenesis which contains a nonregular term that vanis...
We present an iterative technique to construct stable solutions for an angiogenesis model set in an ...
AbstractWe propose a mathematical model that governs endothelial cell pattern formation on a biogel ...
To enrich the dynamics of three models, we introduced biologically motivated time-varying delays. Al...
Abstract: We deal with well known two kinds of mathematical models of tumour angiogenesis. We first ...
We study a robust finite difference scheme for integrodifferential kinetic systems of Fokker-Planck ...
We prove existence and uniqueness of nonnegative solutions for a nonlocal in time integrodifferentia...
AbstractAn analysis of a parabolic partial differential equation modelling capillary network formati...
In this paper, we revisit the linear analysis of the transient evolution of a perturbed tumor interf...
AbstractA steady-state analysis of solutions of a generic model for capillary network formation is d...
AbstractWe consider a steady-state non-linear boundary value problem which arises in modelling the f...
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