Add to ORKGIn this paper we present a new model framework for studying vascular tumour growth, in which the blood vessel density is explicitly considered. Our continuum model comprises conservation of mass and momentum equations for the volume fractions of tumour cells, extracellular material and blood vessels. We include the physical mechanisms that we believe to be dominant, namely birth and death of tumour cells, supply and removal of extracellular fluid via the blood and lymph drainage vessels, angiogenesis and blood vessel occlusion. We suppose that the tumour cells move in order to relieve the increase in mechanical stress caused by their proliferation. We show how to reduce the model to a system of coupled partial differential equations for the...
In this paper, we develop a simple mathematical model of the vascularization and subsequent growth o...
In this chapter we briefly discuss the results of a mathematical model formulated in [22] that incor...
In this article, we present a new multiscale mathematical model for solid tumour growth which couple...
In this paper we present a new model framework for studying vascular tumour growth, in which the blo...
In this paper we present a new model framework for studying vascular tumour growth, in which the blo...
In this paper we present a new model framework for studying vascular tumour growth, in which the blo...
In this paper we present a continuum mathematical model of vascular tumour growth which is based on ...
In this paper we present a continuum mathematical model of vascular tumour growth which is based on ...
In this paper, we develop a mathematical model to describe interactions between tumour cells and a c...
In this chapter we briefly discuss the results of a mathematical model formulated in [22] that incor...
In this paper, we develop a simple mathematical model of the vascularization and subsequent growth o...
Summary. In this paper we brie y discuss the results of a mathematical model for-mulated in [22] tha...
The biology of cancer is a complex interplay of many underlying processes, taking place at different...
In this paper, we develop a simple mathematical model of the vascularization and subsequent growth o...
In this chapter we briefly discuss the results of a mathematical model formulated in [22] that incor...
In this paper, we develop a simple mathematical model of the vascularization and subsequent growth o...
In this chapter we briefly discuss the results of a mathematical model formulated in [22] that incor...
In this article, we present a new multiscale mathematical model for solid tumour growth which couple...
In this paper we present a new model framework for studying vascular tumour growth, in which the blo...
In this paper we present a new model framework for studying vascular tumour growth, in which the blo...
In this paper we present a new model framework for studying vascular tumour growth, in which the blo...
In this paper we present a continuum mathematical model of vascular tumour growth which is based on ...
In this paper we present a continuum mathematical model of vascular tumour growth which is based on ...
In this paper, we develop a mathematical model to describe interactions between tumour cells and a c...
In this chapter we briefly discuss the results of a mathematical model formulated in [22] that incor...
In this paper, we develop a simple mathematical model of the vascularization and subsequent growth o...
Summary. In this paper we brie y discuss the results of a mathematical model for-mulated in [22] tha...
The biology of cancer is a complex interplay of many underlying processes, taking place at different...
In this paper, we develop a simple mathematical model of the vascularization and subsequent growth o...
In this chapter we briefly discuss the results of a mathematical model formulated in [22] that incor...
In this paper, we develop a simple mathematical model of the vascularization and subsequent growth o...
In this chapter we briefly discuss the results of a mathematical model formulated in [22] that incor...
In this article, we present a new multiscale mathematical model for solid tumour growth which couple...