3D bioprinting of multicellular scaffolds for osteochondral regeneration

Abstract

Regeneration of osteochondral tissue is of great potentialities in repairing severe osteochondral defects. However, anisotropic physiological characteristics and tissue linage difference make the regeneration of osteochondral tissue remain a huge challenge. Herein, a multicellular system based on a bilayered co-culture scaffold mimicking osteochondral tissues was successfully developed for an alternative of osteochondral regeneration via a 3D bioprinting strategy. The dual function of integrally repairing both cartilage and bone could be achieved by designing multiple-cells distribution and a cell-induced bioink containing bioceramic particles. As an important bioactive agent, the Li-Mg-Si bioceramics-containing bioink exhibited the function of simultaneously stimulating multiple cells for differentiation towards specific directions. The 3D bioprinted co-culture scaffolds showed the capacity for osteochondral tissue regeneration by inducing osteogenic and chondrogenic differentiation in vitro and accelerating the repair of severe osteochondral defects in vivo. This study offers a potential strategy for complex tissue reconstruction through bioprinting multiple tissue cells in combination of bioceramics-stimulating bioinks.