Magnesium Gradient-Based Hierarchical Scaffold for Dual-Lineage Regeneration of Osteochondral Defect

Osteochondral regeneration remains a great challenge due to the limited self-healing ability and the complexity of its hierarchical structure and composition. Mg2+ and hypoxia are two effective modulators in boosting chondrogenesis. To this end, a double-layered scaffold (D) consisting of a hydrogel layer on a porous cryogel is fabricated to mimic the hierarchical structure of osteochondral tissue. An Mg2+ gradient is incorporated into the double-layered scaffold with hypoxia-mimicking deferoxamine (DFO) embedded in the hydrogel (D-Mg-DFO), which remarkably augments the dual-lineage regeneration of both cartilage and subchondral bone. The higher Mg2+ supplementation from the upper hydrogel, associated with its hypoxia-mimicking situation and small pore size, exhibits promotive effects on chondrogenic differentiation. The lower Mg2+ supplementation from the bottom cryogel, associated with its interconnected macroporous structure, achieves multiple contributions in stem cell migration from bone marrow cavity, matrix mineralization, and osteogenesis. Furthermore, rabbits' trochlea osteochondral defects are established to evaluate the regenerative outcome. Compared to control scaffolds containing only Mg2+ or DFO, the D-Mg-DFO scaffold presents the best regenerative effect under the synergistic contribution of multiple factors. Overall, this work provides a new design of scaffold toward an effective repair of cartilage defect.