The processes taking place inside the living cell are now understood to the point where predictive computational models can be used to gain detailed understanding of important biological phenomena. A key challenge is to extrapolate this detailed knowledge of the individual cell to be able to explain at the population level how cells interact and respond with each other and their environment. In particular, the goal is to understand how organisms develop, maintain and repair functional tissues and organs. In this paper we propose a novel computational framework for modeling populations of interacting cells. Our framework incorporates mechanistic, constitutive descriptions of biomechanical properties of the cell population, and uses a coarse...
Mechanical heterogeneity in biological tissues, in particular stiffness, can be used to distinguish ...
Multiscale nature of a biological system span at many order of magnitudes in time and space. Molecul...
Deciphering the relationship between cellular processes and the structure of living cells is a key s...
The processes taking place inside the living cell are now understood to the point where predictive c...
Cell signaling and gene transcription occur at faster time scales compared to cellular death, divisi...
In the last decades, mathematical and computational models have become ubiquitous to the field of sy...
The faithful reproduction and accurate prediction of the phenotypes and emergent behaviors of comple...
We introduce a model for describing the dynamics of large numbers of interacting cells. The fundamen...
The coordinated behaviour of populations of cells plays a central role in tissue growth and renewal....
The coordinated behaviour of populations of cells plays a central role in tissue growth and renewal....
In this paper, the authors describe a computational model for the growth of multicellular tissues us...
A state-of-the-art problem in Computational Systems Biology is to provide suitable tools to model an...
The dynamic behaviour of epithelial cell sheets plays a central role during development, growth, dis...
Modelling and simulation are at the heart of the rapidly developing field of systems biology. This p...
Mechanical heterogeneity in biological tissues, in particular stiffness, can be used to distinguish ...
Multiscale nature of a biological system span at many order of magnitudes in time and space. Molecul...
Deciphering the relationship between cellular processes and the structure of living cells is a key s...
The processes taking place inside the living cell are now understood to the point where predictive c...
Cell signaling and gene transcription occur at faster time scales compared to cellular death, divisi...
In the last decades, mathematical and computational models have become ubiquitous to the field of sy...
The faithful reproduction and accurate prediction of the phenotypes and emergent behaviors of comple...
We introduce a model for describing the dynamics of large numbers of interacting cells. The fundamen...
The coordinated behaviour of populations of cells plays a central role in tissue growth and renewal....
The coordinated behaviour of populations of cells plays a central role in tissue growth and renewal....
In this paper, the authors describe a computational model for the growth of multicellular tissues us...
A state-of-the-art problem in Computational Systems Biology is to provide suitable tools to model an...
The dynamic behaviour of epithelial cell sheets plays a central role during development, growth, dis...
Modelling and simulation are at the heart of the rapidly developing field of systems biology. This p...
Mechanical heterogeneity in biological tissues, in particular stiffness, can be used to distinguish ...
Multiscale nature of a biological system span at many order of magnitudes in time and space. Molecul...
Deciphering the relationship between cellular processes and the structure of living cells is a key s...