Objective To investigate the feasibility of cartilaginous implantscontaining bone marrow stromal cells(MSCs) derived from chondrocytes in biological resurfacing procedures for repairing articular cartilage defect. Methods MSCs derived from chondrocytes were obtained with high initial cell density subculture. An implant was constructed by dispersing the chondrocytes in a acid soluble type Ⅰ collagen gel(5×106cells/ml, final cell concentration). A fullthickness defect 3 mm×5 mm was created in the trochlear groove of femur in 36 rabbits. A piece of cotton soaked in 0.5% trypsin was laid into the defect for 5 minutes, then the defect was filled with MSC/collagen gel implant on one side(n=36), filledwith a plain collagen gel on the other side(n=18),and left empty as controls on the other side(n=18). The animals were sacrificed at 4, 8, 12, 24, 32,and 48 weeks. The repaired tissue was examined and evaluated with Pineda gradingscale. Results In MSCs group, the implanted cells resembled well differentiated chondrocytes and were surrounded by metachromatic matrix and the reparative tissue resembled hyaline cartilage after 4 weeks; bone was formed at the base of the defects, the thickness of new cartilage was larger than tht of normal one after 8 weeks; the thickness was reduced proximally, approximating to that of normal cartilage, and chondrocyte columns was formed and subchondral bone and tidemark reappeared after 12 weeks; the thickness of the new tissue was about 55% of the normal tissue, with smooth surface and there were hypertrophic chondrocytes near the tidemark after 24 weeks; no hypertrophic chondrocytes were observed, indicating cessation of endochondral ossification after 32 weeks; the tissue architecture was the same as that at 32 weeks, hyaline-like cartilage persisting, with subchondral bone and tidemark in continuity after 48 weeks. The four layer cell orientation was not as clear as that of normal cartilage. The defects were partially filled with fibrous tissue in controls. At 32 weeks, erosive cartilage, naked subchondralbone and proliferative synovial membrane indicated the presence of osteoarthrosis. There were no statistical difference according to Pineda tissue scales in the specimens from the MSCs group between 24, 32, and 48 weeks, but there was significant difference between 4 weeks and 24, 32 and 48 weeks (Plt;0.05). The joint function recovered after 2 weeks in MSCs group, while it deteriorated progressively incontrols. Conclusion MSCs derived from chondrocytes improve repair of largefullthickness defect in articular cartilage. The reparative hyaline-like cartilage is stable differentiation after 24 weeks, maintains good joint function after 48 weeks.
Objective To determine whether fibroblasts can be used to promote endochondral bone formation in vivo by transfer of human bone morphogenetic protein-2(hBMP-2) into fibroblasts. Methods pcDNA3-hBMP-2 was constructed by use of gene clone and recombined technique.NIH3T3 fibroblasts were transfected with pcDNA3hBMP-2. The positive cell clones were selected with G418. In NIH3T3 fibroblaststransferred with pcDNA3-hBMP-2, the expression of hBMP-2 was determined by in situ hybridization and immunohistochemical analysis; alkaline phosphatase activity was measured. hBMP-2producing fibroblasts were implanted into nude mouse muscle to observe endochondral bone formation in vivo. Results pcDNA3-hBMP-2 was successfully constructed. In NIH3T3 fibroblasts transfected with -pcDNA3-hBMP-2,the BMP-2 expression was stable; alkaline phophatase activity was much higher than that in nontransfectedNIH3T3 cells. Endochondral bone formation invivo was observed at the site of implantation 4 weeks later.Conclusion Fibroblasts transfected by hBMP-2 gene can be used to promote endochondral bone formation in vivo.
ObjectiveTo study the effect and feasibility of poly-lactide-co-glycolide (PLGA) loaded with recombinant human bone morphogenetic protein 2 (rhBMP-2) on repairing articular cartilage defect in rabbits. Methods PLGA was made into cylinders which were 4 mm in diameter and 3 mm in thickness. rhBMP-2 was fully homogenated before used. PLGA combined with 0.5 mg rhBMP-2 under the condition of vacuum(700 mmHg),and then lyophilized, packed ,sterilized with ethylene oxide and reserved. Defects of 4 mm in diameter and reaching medullary cavity were made in femoral condyles of 72 two-month-old New Zealand white rabbits. The 36 right defects were repaired with PLGA-rhBMP-2 composites as the experimental group, the 36 left defects with PLGA only as PLGA group, the other 36 left defects were left untreated as control group, and the other 36 right defects with PLGA-MSCs composites as cell group. At 4, 8, 12, 24, 36 and 48 weeks after operation, macroscopical and microscopical observations were made, and the histological grade wasdone.Results After 4 weeks of operation: In the experimental group and cell group, defects were filled with white translucent tissue which appeared smooth and soft; the matrix around chondrocytes was weakly metachromatic, the newly formed cartilage tissue was thicker than normal cartilage tissue; there was no formed tissue in the PLGA group and the blank control group. After 8 weeks of operation: In the experimental group and cell group, the new tissue was white, translucent, tenacious and smooth. The boundary with normal cartilage became vague. New cartilage cells distributed evenly. The cells of the surface layerparalleled, but the deeper layer lost directivity. The matrix dyed weakly. The new cartilage gradually became thinner, but it still thicker than the normal cartilage ones. The PLGA degraded besides some drops.In the blank control group and PLGA group, a little white membrane formed at the bottom of the defect. After 1224 weeks of operation: In the experimental group and cell group, defects were filled with new tissues which were white, translucent, tenacious and smooth. The boundary disappeared.The thickness of the new cartilage was similar to that of the normal ones. The cells of the surface layer paralleled to each other,but the cells of the deeper layer tended to arrange vertically. The matrix around chondrocytes was metachromatic,but the color was lighter than that of the normal cartilage. Bone under the cartilage and the tide mark recovered. The new cartilage linked with nomal cartilage finely.In the blank control group and PLGA group, there was a little fibrous tissue at the bottom of the defect withe obvious boundary. After 36 weeks and 48 weeks of operation:in the experimental group and the cell group, the new cartilage was slightly white,continuous and less smooth. The boundary disappeared. There was no proliferated synovial membrane.The thickenss of the new cartilage was thinner than that of the normal ones. The matrix around chondrocytes was weakly metachromatic. In the blank control group and PLGA group, the defect still existed, but became smaller.At the bottom of the defect, fibrous tissues formed. Some cartilage denudated and became less smooth.Some bone under cartilage exposed,and the synovial membrane became thick. The histologic grade of the repair tissue at 12 weeks and 24 weeks of operation in experimental group and cell group was significantly different from that at 4, 8 and 48 weeks of operation(Plt;0.01). There was also significant difference in the experimental group and cell group compared with the blank control group and PLGA group at each time after operation(Plt;0.01). But there was no significant difference between the experimental group and the cell group. Conclusion In the course of degradation。。。。。。.
Objective To review the current concepts of gene therapy approachesmediated by adenovirus vectors for bone trauma and bone disease. Methods The recent literature concerned gene therapy mediated by adenovirus vectors was reviewed, which provides new insights into the treatments of bone trauma and bone disease. Results Adenovirus vectors was efficient, achieved high expression after transduction, and could transfer genes to both replicating and nonreplicating cells, such as osteoblasts, osteoclasts, fibroblasts, chondrocytes, bone marrow stromal cells, etc. Gene therapy mediated by adenovirus vectors achieved affirmative results in enhancing bone union and in curing bone diseases, such as osteoporosis and rheumatoid arthritis. Conclusion Gene therapy mediatedby adenovirus offers an exciting avenue for treatment of bone trauma and bone diseases.
Objective To study the influence of the immersed time by hydrogen dioxide on the characteristics of bovine cancellous bone granules in various periods. Methods Ten 24-month-old Qinchuan bovine, male or female, weighing 150-170 g, were selected. Cancellous bone granules from metaphysic of bovine long bone were cut into cubes of 5 mm × 5 mm ×5 mm and immersed by 8.8 mol/L hydrogen dioxide for 0, 12, 24, 36, 48, 60 and 72 hours separately. Determination of ash, scanning electron microscope, X-ray energy spectrum and micro CT were used to investigate the changes of composition, structure and qual ity of bone. Results With the immersed time increasing, the contents of organics in the bone cancellous were reduced gradually, and obviously decreased during the periods of 0 to 24 hours and 60 to 72 hours (P lt; 0.05). The contents of calcium and phosphorus decreased gradually, they could not be detected almost after 60 days (P lt; 0.05). Bone mineral density and bone mineral content were decreased obviously after 60 hours (P lt; 0.05). The bone trabecula became sl immer and trabecular spacing became larger. Conclusion Hydrogen dioxide can be used to remove the antigen in xenogeneic bone; however as the time increasing (more than 60 hours) the composition and structure will be damaged. Thus it is important to control the immersed time for maintaining the biological characteristics of xenogeneic bone substitute as well as el iminating antigen by hydrogen dioxide.