Recombinant bone matrix maintains the graft space, induces vascularized bone regeneration and preserves canine tooth extraction socket structure.

AIM: Recombinant bone matrix (RBM) is a newly conceived and engineered porous bone graft granule of average size 600 µm composed of purified recombinant collagen peptide. We sought to examine the behaviour with time of RBM that was grafted in the canine tooth extraction socket. MATERIALS AND METHODS: The canine tooth extraction socket of the hemisectioned mandibular third premolar distal root was grafted with RBM granules, whereas the opposite side extraction socket served as non-grafted control. The mandibular samples were harvested at 1, 3 and 6 months of healing and subjected to micro-CT imaging and decalcified paraffin-embedded histology. Separately, the effect of RBM was compared with that of deproteinized cancellous bovine bone (DCBB) and bovine atelocollagen plug (BACP) in the canine tooth extraction model at 3 months of healing. RESULTS: RBM maintained the grafted space in the socket and the gingival connective tissue until new bone was formed within its porous space. The regenerated bone was highly vascularized and continued to mature, while RBM was completely bioresorbed by 6 months. The buccal and lingual alveolar ridge heights of the RBM-grafted extraction socket was better preserved than those of non-grafted control sockets. The degree of socket preservation by RBM was equivalent to that by DCBB, although their healing mechanisms were different. CONCLUSIONS: This study demonstrated that RBM induced controlled active bone regeneration and preserved the extraction socket structure in a canine model. Bioresorbable RBM engineered without animal or human source materials presents a novel bone graft category with robust bone regenerative property.

Bioresorbable Bone Graft Composed of an RGD-Enriched Recombinant Human Collagen Polypeptide Induced Neovascularization and Regeneration of Mature Bone Tissue.

Bone graft materials provide a scaffold for migrating cells for bone regeneration. One of the major challenges is to support adequate neovascularization in the graft materials and bone tissue. Vascular endothelial cells have been shown to recognize the integrin-binding Arg-Gly-Asp (RGD) sequence in natural extracellular matrix (ECM) molecules. Here, we report a bone graft material composed of an RGD-enriched recombinant polypeptide based on human type I collagen alpha 1 chain (RCPhC1) and propose a category of bone graft materials called the recombinant bone matrix. RCPhC1 demonstrated significantly increased human umbilical vein endothelial cell attachment in vitro and was further processed through freeze casting and heat crosslinking processes to generate porous granular bone graft, in which RGD sequences remained canonical. When grafted in the rat model, RCPhC1 bone graft demonstrated a uniquely increased presence of CD34+ endothelial cells within the graft material. Bone tissue was found directly in contact with the pore structure of RCPhC1 bone graft, resulting in the regeneration of large bone tissue. By contrast, the combined demineralized and decellularized bone allograft containing bone collagen in the ECM did not show vascular formation within the graft material. When applied to canine tooth extraction socket, RCPhC1 bone graft rapidly induced highly vascularized regenerating tissues, which became a mature bone with the bone marrow tissue. These results indicate that RCPhC1 bone graft is a promising material and generated highly active bone tissues, which rapidly matured.