Internal and external co-induction pineal 3D printed scaffolds for bone and blood vessel regeneration

Abstract

The precise structural design and reproducible manufacturing advantages of the 3D printed scaffold make it attract attention in clinical applications. However, the inability of scaffolds to achieve internal and external co-induced vascularized osteogenesis limits their application. After observing the ingenious and functionalized structural combination of "pinecone", this study prepared hydrogel microspheres encapsulating strontium ranelate (SrR)-dendrimer (PAMAM) as a functionalized "pine nuts" through microfluidic technology. The 3D-printed Polycaprolactone (PCL) scaffold was used as a framework in which hydrogel microspheres and a 3D-printed scaffold were cleverly combined. In this pinecone 3D-scaffold system, the slow release of SrR is beneficial to promote vascularization and osteogenic differentiation inside and outside the scaffold. Furthermore, the rat femoral defect model verified that the pinecone scaffold promoting the formation of internal vascular network, osteogenic differentiation and shortening the bone repair time in vivo. In summary, this pinecone degradable biomimetic composite scaffold with internal osteogenic differentiation and vascular activation functions has great potential for clinical demand in segmental bone defects.