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Direct Integration of 3D Printing and Cryogel Scaffolds for Bone Tissue Engineering

Levi M. Olevsky, Amritha Anup, M Jacques, Nadia Keokominh, Eric P. Holmgren, Katherine R. Hixon

2023Bioengineering12 citationsDOIOpen Access PDF

Abstract

Cryogels, known for their biocompatibility and porous structure, lack mechanical strength, while 3D-printed scaffolds have excellent mechanical properties but limited porosity resolution. By combining a 3D-printed plastic gyroid lattice scaffold with a chitosan-gelatin cryogel scaffold, a scaffold can be created that balances the advantages of both fabrication methods. This study compared the pore diameter, swelling potential, mechanical characteristics, and cellular infiltration capability of combined scaffolds and control cryogels. The incorporation of the 3D-printed lattice demonstrated patient-specific geometry capabilities and significantly improved mechanical strength compared to the control cryogel. The combined scaffolds exhibited similar porosity and relative swelling ratio to the control cryogels. However, they had reduced elasticity, reduced absolute swelling capacity, and are potentially cytotoxic, which may affect their performance. This paper presents a novel approach to combine two scaffold types to retain the advantages of each scaffold type while mitigating their shortcomings.

Topics & Concepts

ScaffoldMaterials scienceBiocompatibilityPorositySwellingBiomedical engineeringTissue engineeringGyroid3D bioprintingGelatinChitosan3d printedComposite materialChemical engineeringChemistryPolymerCopolymerEngineeringMetallurgyMedicineBiochemistryBone Tissue Engineering Materials3D Printing in Biomedical ResearchDental Implant Techniques and Outcomes
Direct Integration of 3D Printing and Cryogel Scaffolds for Bone Tissue Engineering | Litcius