Towards systems tissue engineering: elucidating the dynamics, spatial coordination, and individual cells driving emergent behaviors

TL;DR

This paper discusses systems tissue engineering, which uses advanced biological and imaging techniques to understand how complex tissue behaviors emerge, aiming to improve biomaterial design for tissue development and disease modeling.

Contribution

It introduces the concept of systems tissue engineering, integrating systems biology tools to elucidate molecular and cellular mechanisms driving tissue emergence.

Findings

Identification of molecular drivers of emergent tissue behavior

Insights into single cell heterogeneity and rare cell functions

Understanding spatial cell distribution in tissue development

Abstract

Biomaterial systems have allowed for the in vitro production of complex, emergent tissue behaviors that were not possible with conventional 2D culture systems allowing for analysis of the normal development as well as disease processes. We propose that the path towards developing the design parameters for biomaterial systems lies with identifying the molecular drivers of emergent behavior through leveraging technological advances in systems biology, including single cell omics, genetic engineering, and high content imaging. This research focus, which we term systems tissue engineering, can uniquely interrogate the mechanisms by which complex tissue behaviors emerge with the potential to capture the contribution of i) dynamic regulation of tissue development and dysregulation, ii) single cell heterogeneity and the function of rare cell types, and iii) the spatial distribution and structure of individual cells and cell types within a tissue. Collectively, systems tissue engineering can facilitate the identification of biomaterial design parameters that will accelerate basic science discovery and translation.