3D-Printed Bifunctional Scaffold for Treatment of Critical Bone Defects Based on Osteoimmune Microenvironment Regulation and Osteogenetic Effects

The critical-sized bone defect resulting from trauma, tumor resection, and congenital deformity fails to undergo spontaneous healing due to its substantial size, while the ensuing inflammatory process and hypoxic environment further impede the regenerative process. Therefore, it has consistently presented a significant clinical challenge. In the present study, we incorporate a glycyrrhizic acid (GA)-functionalized hydrogel onto the surface of a Hydroxyapatite (Hap)-modified Polycaprolactone (PCL) scaffold to fabricate a composite scaffold. The composed scaffold showed favorable anti-inflammatory and antioxidative capabilities by modulating macrophage polarization and scavenging reactive oxygen species (ROS); the modification of Hap enhanced its osteogenic ability. An in vivo rat skull defect model confirmed that the composed scaffold efficiently promotes bone regeneration. In general, the composed scaffold with the ability of osteoimmune microenvironment regulation can effectively repair critical-sized bone defects. This strategy provides a promising method for the reconstruction of large segmental bone defects.