Multiscale approaches to modelling biological phenomena are growing rapidly. We present here some recent results on the formulation of a theoretical framework which can be developed into a fully integrative model for cancer growth. The model takes account of vascular adaptation and cell-cycle dynamics. We explore the effects of spatial inhomogeneity induced by the blood flow through the vascular network and of the possible effects of p27 on the cell cycle. We show how the model may be used to investigate the efficiency of drug-delivery protocols
We investigate a three-dimensional multiscale model of vascular tumour growth, which couples blood f...
The biology of cancer is a complex interplay of many underlying processes, taking place at different...
We investigate a three-dimensional multiscale model of vascular tumour growth, which couples blood f...
Multiscale approaches to modelling biological phenomena are growing rapidly. We present here some re...
Multiscale approaches to modelling biological phenomena are growing rapidly. We present here some re...
Multiscale approaches to modelling biological phenomena are growing rapidly. We present here some re...
The modelling of cancer provides an enormous mathematical challenge because of its inherent multi-sc...
The modelling of cancer provides an enormous mathematical challenge because of its inherent multi-sc...
The modelling of cancer provides an enormous mathematical challenge because of its inherent multisca...
Abstract. We present a physiologically structured lattice model for vascular tumor growth which acco...
Abstract. A multiscale model for vascular tumour growth is presented which includes systems of ordin...
We present a physiologically structured lattice model for vascular tumor growth which accounts for b...
We present a physiologically structured lattice model for vascular tumor growth which accounts for b...
We present a physiologically structured lattice model for vascular tumor growth which accounts for b...
A multiscale model for vascular tumour growth is presented which includes systems of ordinary differ...
We investigate a three-dimensional multiscale model of vascular tumour growth, which couples blood f...
The biology of cancer is a complex interplay of many underlying processes, taking place at different...
We investigate a three-dimensional multiscale model of vascular tumour growth, which couples blood f...
Multiscale approaches to modelling biological phenomena are growing rapidly. We present here some re...
Multiscale approaches to modelling biological phenomena are growing rapidly. We present here some re...
Multiscale approaches to modelling biological phenomena are growing rapidly. We present here some re...
The modelling of cancer provides an enormous mathematical challenge because of its inherent multi-sc...
The modelling of cancer provides an enormous mathematical challenge because of its inherent multi-sc...
The modelling of cancer provides an enormous mathematical challenge because of its inherent multisca...
Abstract. We present a physiologically structured lattice model for vascular tumor growth which acco...
Abstract. A multiscale model for vascular tumour growth is presented which includes systems of ordin...
We present a physiologically structured lattice model for vascular tumor growth which accounts for b...
We present a physiologically structured lattice model for vascular tumor growth which accounts for b...
We present a physiologically structured lattice model for vascular tumor growth which accounts for b...
A multiscale model for vascular tumour growth is presented which includes systems of ordinary differ...
We investigate a three-dimensional multiscale model of vascular tumour growth, which couples blood f...
The biology of cancer is a complex interplay of many underlying processes, taking place at different...
We investigate a three-dimensional multiscale model of vascular tumour growth, which couples blood f...