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Non-destructive mechanical assessment for optimization of 3D bioprinted soft tissue scaffolds

Brent Godau, Evan Stefanek, Sadaf Samimi Gharaie, Meitham Amereh, Erik Pagan, Zohreh Marvdashti, Eryn Libert-Scott, Samad Ahadian, Mohsen Akbari

2022iScience25 citationsDOIOpen Access PDF

Abstract

Characterizing the mechanical properties of engineered tissue constructs provides powerful insight into the function of engineered tissues for their desired application. Current methods of mechanical characterization of soft hydrogels used in tissue engineering are often destructive and ignore the effect of 3D bioprinting on the overall mechanical properties of a whole tissue construct. This work reports on using a non-destructive method of viscoelastic analysis to demonstrate the influence of bioprinting strategy on mechanical properties of hydrogel tissue scaffolds. Structure-function relationships are developed for common 3D bioprinting parameters such as printed fiber size, printed scaffold pattern, and bioink formulation. Further studies include mechanical properties analysis during degradation, real-time monitoring of crosslinking, mechanical characterization of multi-material scaffolds, and monitoring the effect of encapsulated cell growth on the mechanical strength of 3D bioprinted scaffolds. We envision this method of characterization opening a new wave of understanding and strategy in tissue engineering.

Topics & Concepts

ScaffoldTissue engineeringSelf-healing hydrogels3D bioprintingCharacterization (materials science)Materials scienceMechanical strengthBiomedical engineeringViscoelasticityNanotechnologyComposite materialEngineeringPolymer chemistry3D Printing in Biomedical ResearchAdditive Manufacturing and 3D Printing TechnologiesBone Tissue Engineering Materials
Non-destructive mechanical assessment for optimization of 3D bioprinted soft tissue scaffolds | Litcius