A hybrid physics-based and data-driven framework for cellular biological systems: Application to the morphogenesis of organoids

iScience. 2023 Jun 19;26(7):107164. doi: 10.1016/j.isci.2023.107164. eCollection 2023 Jul 21.

Abstract

How cells orchestrate their cellular functions remains a crucial question to unravel how they organize in different patterns. We present a framework based on artificial intelligence to advance the understanding of how cell functions are coordinated spatially and temporally in biological systems. It consists of a hybrid physics-based model that integrates both mechanical interactions and cell functions with a data-driven model that regulates the cellular decision-making process through a deep learning algorithm trained on image data metrics. To illustrate our approach, we used data from 3D cultures of murine pancreatic ductal adenocarcinoma cells (PDAC) grown in Matrigel as tumor organoids. Our approach allowed us to find the underlying principles through which cells activate different cell processes to self-organize in different patterns according to the specific microenvironmental conditions. The framework proposed here expands the tools for simulating biological systems at the cellular level, providing a novel perspective to unravel morphogenetic patterns.

Keywords: Biocomputational method; Biological sciences; Biophysics; Developmental biology; Neural networks.