Add to ORKGIn this paper, we revisit and extend our recent work (Holden et al. (2018) A multiphase multiscale model for nutrient limited tissue growth, The ANZIAM Journal, 59(4), 499–532), that considers the derivation of an effective macroscale description suitable to describe the growth of biological tissue within a porous tissue-engineering scaffold. The underlying tissue dynamics is described as a multiphase mixture, thereby naturally accommodating features such as interstitial growth and active cell motion. Via a linearisation of the underlying multiphase model (whose nonlinearity poses significant challenge for such analyses), we obtain, by means of multiple-scales homogenisation, a simplified macroscale model that nevertheless retains explicit ...
In this article we consider the spatial homogenization of a multi- phase model for avascular tumour ...
In this paper a macroscopic model of tumor cord growth is developed, relying on the mathematical the...
Tissue Engineering is a strongly interdisciplinary scientific area aimed at understanding the princi...
In this paper, we revisit and extend our recent work (Holden et al. (2018) A multiphase multiscale m...
We derive an effective macroscale description for the growth of tissue on a porous scaffold. A multi...
Biological tissue is distinguished from materials described historically by continuum mechanical the...
In this paper, we consider the derivation of macroscopic equations appropriate to describe the growt...
The detailed understanding of growth and transport dynamics within biological tissue is made particu...
We derive a multiphase, moving boundary model to represent the development of tissue in vitro in a p...
How morphogenesis depends on cell properties is an active direction of research. Here, we focus on m...
In this thesis we consider several approaches to modelling interactions between fluid flow and cell ...
A contemporary procedure to grow artificial tissue is to seed cells onto a porous biomaterial scaffo...
International audienceHow morphogenesis depends on cell properties is an active direction of researc...
In this thesis, a series of mathematical models suitable for describing biological tissue growth are...
In this article we consider the spatial homogenization of a multi- phase model for avascular tumour ...
In this paper a macroscopic model of tumor cord growth is developed, relying on the mathematical the...
Tissue Engineering is a strongly interdisciplinary scientific area aimed at understanding the princi...
In this paper, we revisit and extend our recent work (Holden et al. (2018) A multiphase multiscale m...
We derive an effective macroscale description for the growth of tissue on a porous scaffold. A multi...
Biological tissue is distinguished from materials described historically by continuum mechanical the...
In this paper, we consider the derivation of macroscopic equations appropriate to describe the growt...
The detailed understanding of growth and transport dynamics within biological tissue is made particu...
We derive a multiphase, moving boundary model to represent the development of tissue in vitro in a p...
How morphogenesis depends on cell properties is an active direction of research. Here, we focus on m...
In this thesis we consider several approaches to modelling interactions between fluid flow and cell ...
A contemporary procedure to grow artificial tissue is to seed cells onto a porous biomaterial scaffo...
International audienceHow morphogenesis depends on cell properties is an active direction of researc...
In this thesis, a series of mathematical models suitable for describing biological tissue growth are...
In this article we consider the spatial homogenization of a multi- phase model for avascular tumour ...
In this paper a macroscopic model of tumor cord growth is developed, relying on the mathematical the...
Tissue Engineering is a strongly interdisciplinary scientific area aimed at understanding the princi...