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3D printing sequentially strengthening high-strength natural polymer hydrogel bilayer scaffold for cornea regeneration

Xiongfeng Nie, Yong Tang, Tengling Wu, Xinrui Zhao, Ziyang Xu, Rong Yang, Yage Sun, Bin Wu, Quanhong Han, Jingwen Hui, Wenguang Liu

2024Regenerative Biomaterials22 citationsDOIOpen Access PDF

Abstract

Abstract 3D printing of high-strength natural polymer biodegradable hydrogel scaffolds simultaneously resembling the biomechanics of corneal tissue and facilitating tissue regeneration remains a huge challenge due to the inherent brittleness of natural polymer hydrogels and the demanding requirements of printing. Herein, concentrated aqueous solutions of gelatin and carbohydrazide-modified alginate (Gel/Alg-CDH) are blended to form a natural polymer hydrogel ink, where the hydrazides in Alg-CDH are found to form strong hydrogen bonds with the gelatin. The hydrogen-bonding-strengthened Gel/Alg-CDH hydrogel demonstrates an appropriate thickened viscosity and shear thinning for extrusion printing. The strong hydrogen bonds contribute to remarkably increased mechanical properties of Gel/Alg-CDH hydrogel with a maximum elongation of over 400%. In addition, sequentially Ca2+-physical crosslinking and then moderately chemical crosslinking significantly enhance the mechanical properties of Gel/Alg-CDH hydrogels that ultimately exhibit an intriguing J-shaped stress–strain curve (tensile strength of 1.068 MPa and the toughness of 677.6 kJ/m2). The dually crosslinked Gel-Alg-CDH-Ca2+-EDC hydrogels demonstrate a high transparency, physiological swelling stability and rapid enzymatic degradability, as well as suturability. The growth factor and drug-loaded biomimetic bilayer hydrogel scaffold are customized via a multi-nozzle printing system. This bioactive bilayer hydrogel scaffold considerably promotes regeneration of corneal epithelium and stroma and inhibits cornea scarring in rabbit cornea keratoplasty.

Topics & Concepts

Self-healing hydrogelsGelatinUltimate tensile strengthScaffoldPolymerTissue engineeringMaterials scienceBilayerRegeneration (biology)Chemical engineeringBiomedical engineeringChemistryPolymer chemistryComposite materialMembraneOrganic chemistryBiologyEngineeringMedicineBiochemistryCell biologyCorneal surgery and disordersCorneal Surgery and TreatmentsOcular Surface and Contact Lens
3D printing sequentially strengthening high-strength natural polymer hydrogel bilayer scaffold for cornea regeneration | Litcius