# Modeling mammary organogenesis from biological first principles: Cells   and their physical constraints

**Authors:** Ma\"el Mont\'evil, Lucia Speroni, Carlos Sonnenschein, Ana M. Soto

arXiv: 1702.03337 · 2017-09-15

## TL;DR

This paper develops a biologically grounded mathematical model of mammary gland development, integrating experimental 3D culture data with principles of cell behavior and physical constraints to better understand organogenesis.

## Contribution

It introduces a novel modeling approach based on biological principles, combining experimental data with a theory of organism organization to study tissue formation.

## Key findings

- The model captures the circular interactions between cells and collagen fibers.
- It demonstrates how physical constraints influence tissue patterning.
- The approach offers a new framework for understanding organ development.

## Abstract

In multicellular organisms, relations among parts and between parts and the whole are contextual and interdependent. These organisms and their cells are ontogenetically linked: an organism starts as a cell that divides producing non-identical cells, which organize in tri-dimensional patterns. These association patterns and cells types change as tissues and organs are formed. This contextuality and circularity makes it difficult to establish detailed cause and effect relationships. Here we propose an approach to overcome these intrinsic difficulties by combining the use of two models; 1) an experimental one that employs 3D culture technology to obtain the structures of the mammary gland, namely, ducts and acini, and 2) a mathematical model based on biological principles. The typical approach for mathematical modeling in biology is to apply mathematical tools and concepts developed originally in physics or computer sciences. Instead, we propose to construct a mathematical model based on proper biological principles. Specifically, we use principles identified as fundamental for the elaboration of a theory of organisms, namely i) the default state of cell proliferation with variation and motility and ii) the principle of organization by closure of constraints. This model has a biological component, the cells, and a physical component, a matrix which contains collagen fibers. Cells display agency and move and proliferate unless constrained; they exert mechanical forces that i) act on collagen fibers and ii) on other cells. As fibers organize, they constrain the cells on their ability to move and to proliferate. The model exhibits a circularity that can be interpreted in terms of closure of constraints...

## Full text

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## Figures

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Source: https://tomesphere.com/paper/1702.03337