3D printing electrospinning fiber-reinforced decellularized extracellular matrix for cartilage regeneration

Cartilage decellularized matrix (CDM) is considered a promising biomaterial for fabricating cartilage tissue engineering scaffolds. An ideal CDM-based scaffold should possess customizable 3D shape for complex tissue regeneration and proper pore size for cell infiltration, as well as provide mechanical support for cell growth. 3D printing is an efficiently technique for preparing customizable 3D scaffolds, however, fabricating CDM-based 3D-printed scaffolds with customizable shapes, proper pore structure and satisfactory mechanical properties remains a challenge. In the current study, to achieve customizable CDM-based 3D scaffolds, CDM was successfully processed into inks suitable for 3D printing. Further, the poor mechanics of CDM-based scaffolds were significantly improved by adding electrospinning fiber into the CDM-based inks for 3D printing. Importantly, the 3D-printed electrospinning fiber-reinforced CDM-based scaffold presented good biocompatibility and can enhance repair articular cartilage defects in rabbits. The current study provides a novel strategy for printing electrospinning fiber-reinforced CDM-based scaffolds for tissue regeneration.