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3D printing of a tough double-network hydrogel and its use as a scaffold to construct a tissue-like hydrogel composite

Cong Du, Jian Hu, Xinyu Wu, Huimin Shi, Hai Yu, Jin Qian, Jun Yin, Changyou Gao, Zi Liang Wu, Qiang Zheng

2021Journal of Materials Chemistry B45 citationsDOI

Abstract

ions and sulfate groups of κ-carrageenan. The obtained hydrogels are stable in water and possess good mechanical properties, with a tensile breaking stress of 1-2 MPa, breaking strain of 100-150%, and Young's modulus of 4-10 MPa. The printed grid can hold 150 times its own weight. 3D printed constructs with a high aspect ratio and shape fidelity are obtained by optimizing the printing parameters. Furthermore, a biomimetic strategy is applied to construct a hydrogel composite by filling the printed tough hydrogel scaffold with a cell-laden fibrin hydrogel as the soft substance. Chondrocytes in the hydrogel composite maintain high viability after cyclic compression, demonstrating the load-bearing capacity of the tough scaffold and favorable microenvironment for cells provided by the embedded soft fibrin gel. We envision that this printing strategy for hydrogel constructs with high toughness and good stability, as well as the method to form tough-soft hydrogel composites, can be extended to other systems to develop structural elements and scaffolds towards applications in biomedical devices and tissue engineering.

Topics & Concepts

Self-healing hydrogelsMaterials scienceComposite numberScaffold3D printingComposite materialToughnessAqueous solutionChemical engineeringBiomedical engineeringPolymer chemistryChemistryMedicinePhysical chemistryEngineering3D Printing in Biomedical ResearchBone Tissue Engineering MaterialsAdditive Manufacturing and 3D Printing Technologies
3D printing of a tough double-network hydrogel and its use as a scaffold to construct a tissue-like hydrogel composite | Litcius