A Hierarchical Hydrogel Impregnation Strategy Enables Brittle‐Failure‐Free 3D‐Printed Bioceramic Scaffolds

Author:

Dong Xinyu1ORCID,Liu Quyang1ORCID,Gan Soo Wah2,Zhuo Hao1,Li Tian1,Zhao Yijing1,Zhai Wei12ORCID

Affiliation:

1. Department of Mechanical Engineering National University of Singapore Singapore 117575 Singapore

2. NUS Centre for Additive Manufacturing National University of Singapore Singapore 117581 Singapore

Abstract

Abstract3D‐printed bioceramic scaffolds offer great potential for bone tissue engineering (BTE) but their inherent brittleness and reduced mechanical properties at high porosities can easily result in catastrophic fractures. Herein, this study presents a hierarchical hydrogel impregnation strategy, incorporating poly(vinyl alcohol) (PVA) hydrogel into the macro‐ and micropores of bioceramic scaffolds and synergistically reinforcing it via freeze‐casting assisted solution substitution (FASS) in a tannic acid (TA)–glycerol solution. By effectively mitigating catastrophic brittle failures, the hydrogel‐impregnated scaffolds showcase three‐ and 100‐fold enhancement in mechanical energy absorption under compression (5.05 MJ m−3) and three‐point bending (3.82 MJ m−3), respectively. The reinforcement mechanisms are further investigated by experimental and simulation analyses, revealing a multi‐scale synergy of fracture and fragmentation resistance through macro and micro‐scale fiber bridging, and nano and molecular‐scale hydrogel reinforcement. Also, the scaffolds acquire additional antibacterial and drug‐loading capabilities from the hydrogel phase while maintaining favorable cell biocompatibility. Therefore, this study demonstrates a facile yet effective approach for preparing brittle‐failure‐free bioceramic scaffolds with enhanced biological functionalities, showcasing immense potential for BTE applications.

Funder

Ministry of Education - Singapore

Publisher

Wiley

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