Objective To investigate the effect of the injectable osteoinductive material with fibrin sealant(FS) as a carrier compounded with bone morphogenetic protein (BMP) on the proliferation and differentiation of marrow stromal cells (MSCs) towards osteoblasts and to provide the experimental foundation for the clinical application. Methods MSCs were extracted and cultured from bone marrow of the 3-day-old rabbit, and the third generation culturedMSCs were studied. The experiment included the experimental group(FS,including 1 μg/ml rhBMP-2), FS control group(FS)and blank control group (no material).The proliferation rate, the adhesive rate, the expression of the collagen Ⅰ and alkaline phosphatase, cell growth condition in the material and the ultrastructure of MSCs were investigated by electron microscopy, histochemistry and cell culture. Results The proliferation rate and the adhesive rate of MSCs in experimental group was significantly higher than those in blank control group ,but lower than those in FS control group (P<0.05). The expression level of thecollagen Ⅰ and alkaline phosphatase in the experimental group was significantlyhigher than those in all control groups(Marrow stromal cells Fibrin sealant Bone morphogenetic protein Cell culture Rabbits0.05). Scanning electron microscope showed that the surface of material was rough and had many pores and that celland material mixed. Transmission electron microscope showed that MSCs of the experimental group were mostly of the phenotype of osteoblasts with relatively lowproliferation activity and high differentiation degree toward osteoblasts and with plenty of extracellular matrix and collagen fibers. MSCs of FS control group had low differentiation degree toward osteoblasts with few extracellular matrix and collagen fibers and high proliferation activity. MSCs of blank control group had low differentiation degree toward osteoblasts with few extracellularmatrix and collagen fibers, and low proliferation activity. Conclusion The injectable osteoinductive material with fibrin sealant as a carrier compounded with BMP could significantly accelerate the differentiation of MSCs towards osteoblasts. But it could not significantly accelerate the proliferation activity of MSCs.
OBJECTIVE: To investigate the ability of repairing bone defect with the compound of coralline hydroxyapatite porous (CHAP), fibrin sealant(FS) and staphylococcus aureus injection (SAI), and the feasibility to use the compounds as bone substitute material. METHODS: The animal model of bone defect was made on the bilateral radius of 54 New Zealand white rabbits, which were randomly divided into the experimental group(the defect was repaired with CHAP-FS-SAI), control group(with autograft) and blank control group(the defect was left unrepaired) with 18 rabbits in each group. The ability of bone defect repair was evaluated by gross observation, histopathological study, X-ray and biomechanical analysis 2, 4, 8 and 12 weeks after repair. RESULTS: (1) In the 2nd week, tight fibro-connection could be found between the implant and fracture site and there were many fibroblasts and capillary proliferation with many chondrocytes around CHAP in the experimental group, while only a few callus formed, and chondrocytes, osteoblast and osteoclast existed in the control group. (2) In experimental group and control group, a large quantity of callus was found 4 and 8 weeks; ossification of chondrocytes with weave bone formation were found 4 weeks and many osteocytes and weave bones and laminar bones were found 8 weeks. (3) In the 12th week, the complete ossification of implant with well bone remodeling, a large number of mature osteocytes and laminar were found in experimental group and control group, and CHAP still existed in the experimental group; the defect area filled with fibro-scar tissue and only many fibroblasts could be seen in blank control group. (4) X-ray findings were the following: In experimental and control groups, callus formation could be seen 2 weeks postoperatively, more callus formed 4 weeks, the bone defect area disappeared and CHAP scattered in the callus 8 weeks; the fracture line disappeared and medullary cavity became united (in control group); and in the 12th week, the cortex became continuous, the medullary cavity became united, and remodeling completed, while bone defect was not still united in blank control group. The maximal torque and torsional stiffness in the experimental group is higher than those in the control group 2 weeks (P lt; 0.05), but there was no significant difference (P gt; 0.05) between the two groups 4, 8, 12 weeks after repair. CONCLUSION: The compound of CHAP-FS-SAI has good biological compatibility, and it can be used for one kind of bone substitute material to repair the bone defect.