Quantitative characterization of 3D bioprinted structural elements under cell generated forces

With improving biofabrication technology, 3D bioprinted constructs increasingly resemble real tissues. However, the fundamental principles describing how cell-generated forces within these constructs drive deformations, mechanical instabilities, and structural failures have not been established, eve...

Full description

Saved in:
Bibliographic Details
Published in:Nature communications 2019-07, Vol.10 (1), p.3029-9, Article 3029
Main Authors: Morley, Cameron D., Ellison, S. Tori, Bhattacharjee, Tapomoy, O’Bryan, Christopher S., Zhang, Yifan, Smith, Kourtney F., Kabb, Christopher P., Sebastian, Mathew, Moore, Ginger L., Schulze, Kyle D., Niemi, Sean, Sawyer, W. Gregory, Tran, David D., Mitchell, Duane A., Sumerlin, Brent S., Flores, Catherine T., Angelini, Thomas E.
Format: Article
Language:English
Subjects:
13/106
13/107
14/19
14/34
3-D printers
631/57
639/166/985
639/301/54/2295
Acrylic Resins - chemistry
Animals
Behavior
Biocompatible Materials
Bioengineering
Bioprinting - methods
Brain cancer
Cell culture
Cell Culture Techniques - methods
Cell Line, Tumor
Cells (biology)
Collagen
Construction
Contraction
Deformation mechanisms
Equilibrium
Extracellular Matrix
Gels - chemistry
Humanities and Social Sciences
Materials Testing
Mechanical properties
Mechanics
Methacrylates - chemistry
Mice
Microbeams
Microgels
multidisciplinary
Neurosurgery
NIH 3T3 Cells
Printing, Three-Dimensional
Science
Science (multidisciplinary)
Static stability
Structural analysis
Structural failure
Structural members
Three dimensional printing
Tissue engineering
Tissue Engineering - methods
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:With improving biofabrication technology, 3D bioprinted constructs increasingly resemble real tissues. However, the fundamental principles describing how cell-generated forces within these constructs drive deformations, mechanical instabilities, and structural failures have not been established, even for basic biofabricated building blocks. Here we investigate mechanical behaviours of 3D printed microbeams made from living cells and extracellular matrix, bioprinting these simple structural elements into a 3D culture medium made from packed microgels, creating a mechanically controlled environment that allows the beams to evolve under cell-generated forces. By varying the properties of the beams and the surrounding microgel medium, we explore the mechanical behaviours exhibited by these structures. We observe buckling, axial contraction, failure, and total static stability, and we develop mechanical models of cell-ECM microbeam mechanics. We envision these models and their generalizations to other fundamental 3D shapes to facilitate the predictable design of biofabricated structures using simple building blocks in the future. Advances in biofabrication technology enable 3D printed constructs to resemble real tissues, but it remains unclear how cell-generated forces deform these constructs. Here the authors investigate mechanical behaviours of 3D printed “microbeams” made from mixtures of living cells and extracellular matrix.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-019-10919-1