# Multiscale dynamics of a heterotypic cancer cell population within a   fibrous extracellular matrix

**Authors:** Robyn Shuttleworth, Dumitru Trucu

arXiv: 1907.01092 · 2019-07-03

## TL;DR

This paper develops a multiscale model of heterotypic cancer invasion within a fibrous extracellular matrix, integrating tissue-scale dynamics with cell-scale molecular processes to better understand tumor spread.

## Contribution

It introduces a novel multiscale framework that incorporates fiber network dynamics and enzyme-driven invasion in heterotypic tumors, extending previous models.

## Key findings

- Fiber network influences invasion patterns
- Heterotypic interactions affect invasion speed
- Model provides insights into tumor-matrix interactions

## Abstract

Local cancer cell invasion is a complex process involving many cellular and tissue interactions and is an important prerequisite for metastatic spread, the main cause of cancer related deaths. Occurring over many different temporal and spatial scales, the first stage of local invasion is the secretion of matrix-degrading enzymes (MDEs) and the resulting degradation of the extra-cellular matrix (ECM). This process creates space in which the cells can invade and thus enlarge the tumour. As a tumour increases in malignancy, the cancer cells adopt the ability to mutate into secondary cell subpopulations giving rise to a heterogeneous tumour. This new cell subpopulation often carries higher invasive qualities and permits a quicker spread of the tumour. Building upon the recent multiscale modelling framework for cancer invasion within a fibrous ECM introduced in Shuttleworth and Trucu (2019), in this paper we consider the process of local invasion by a heterotypic tumour consisting of two cancer cell populations mixed with a two-phase ECM. To that end, we address the double feedback link between the tissue-scale cancer dynamics and the cell-scale molecular processes through the development of a two-part modelling framework that crucially incorporates the multiscale dynamic redistribution of oriented fibres occurring within a two-phase extra-cellular matrix and combines this with the multiscale leading edge dynamics exploring key matrix-degrading enzymes molecular processes along the tumour interface that drive the movement of the cancer boundary. The modelling framework will be accompanied by computational results that explore the effects of the underlying fibre network on the overall pattern of cancer invasion.

## Full text

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## Figures

75 figures with captions in the complete paper: https://tomesphere.com/paper/1907.01092/full.md

## References

51 references — full list in the complete paper: https://tomesphere.com/paper/1907.01092/full.md

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Source: https://tomesphere.com/paper/1907.01092