Add to ORKG\emph{In vitro} experiments in which tumour cells are seeded in a gelatinous medium, or hydrogel, show how mechanical interactions between tumour cells and the tissue in which they are embedded, together with local levels of an externally-supplied, diffusible nutrient (e.g., oxygen), affect the tumour's growth dynamics. In this article, we present a mathematical model that describes these \emph{in vitro} experiments. We use the model to understand how tumour growth generates mechanical deformations in the hydrogel and how these deformations in turn influence the tumour's growth. The hydrogel is viewed as a nonlinear hyperelastic material and the tumour is modelled as a two-phase mixture, comprising a viscous tumour cell phase and an isotrop...
In vivo tumours are highly heterogeneous entities which often comprise intratumoural regions of hypo...
Mechanical forces play a crucial role in tumor patho-physiology. Compression of cancer cells inhibit...
Mechanical feedback has been identified as a key regulator of tissue growth, by which external signa...
A mathematical model is adapted to the description of the growth of an avascular tumour spheroid emb...
It is now widely accepted that cells are mechanically integrated structures which dynamically respon...
Mechanical factors play a major role in tumor development and response to treatment. This is more ev...
This paper presents a mathematical model of normal and abnormal tissue growth. The modelling focuses...
Mechanical factors play a major role in tumor development and response to treatment. This is more ev...
Mechanical forces are generated during tumor growth and progression. Numerous studies have ...
The unchecked growth of a solid tumor produces solid stress, causing deformation of the surrounding ...
<div><p>Mechanical forces play a crucial role in tumor patho-physiology. Compression of cancer cells...
In this paper we study tumor growth within the framework of Continuum Mechanics, considering a tumo...
Biological soft tissues develop mechanical stresses when they grow. In close association with biolog...
In vivo tumours are highly heterogeneous entities which often comprise intratumoural regions of hypo...
Mechanical forces play a crucial role in tumor patho-physiology. Compression of cancer cells inhibit...
Mechanical feedback has been identified as a key regulator of tissue growth, by which external signa...
A mathematical model is adapted to the description of the growth of an avascular tumour spheroid emb...
It is now widely accepted that cells are mechanically integrated structures which dynamically respon...
Mechanical factors play a major role in tumor development and response to treatment. This is more ev...
This paper presents a mathematical model of normal and abnormal tissue growth. The modelling focuses...
Mechanical factors play a major role in tumor development and response to treatment. This is more ev...
Mechanical forces are generated during tumor growth and progression. Numerous studies have ...
The unchecked growth of a solid tumor produces solid stress, causing deformation of the surrounding ...
<div><p>Mechanical forces play a crucial role in tumor patho-physiology. Compression of cancer cells...
In this paper we study tumor growth within the framework of Continuum Mechanics, considering a tumo...
Biological soft tissues develop mechanical stresses when they grow. In close association with biolog...
In vivo tumours are highly heterogeneous entities which often comprise intratumoural regions of hypo...
Mechanical forces play a crucial role in tumor patho-physiology. Compression of cancer cells inhibit...
Mechanical feedback has been identified as a key regulator of tissue growth, by which external signa...