Objective To investigate the effect of simvastatin on inducing endothel ial progenitor cells (EPCs) homing and promoting bone defect repair, and to explore the mechanism of local implanting simvastatin in promoting bone formation. Methods Simvastatin (50 mg) compounded with polylactic acid (PLA, 200 mg) or only PLA (200 mg) was dissolved in acetone (1 mL) to prepare implanted materials (Simvastatin-PLA material, PLA material). EPCs were harvested from bone marrow of 2 male rabbits and cultured with M199; after identified by immunohistochemistry, the cell suspension of EPCs at the 3rd generation (2 × 106 cells/mL) was prepared and transplanted into 12 female rabbits through auricular veins(2 mL). After 3 days, the models of cranial defect with 15 cm diameter were made in the 12 female rabbits. And the defects were repaired with Simvastatin-PLA materials (experimental group, n=6) and PLA materials (control group, n=6), respectively. The bone repair was observed after 8 weeks of operation by gross appearance, X-ray film, and histology; gelatin-ink perfusion and HE staining were used to show the new vessels formation in the defect. Fluorescence in situ hybridization (FISH) was performed to show the EPCs homing at the defect site. Results All experimental animals of 2 groups survived to the end of the experiment. After 8 weeks in experimental group, new bone formation was observed in the bone defect by gross and histology, and an irregular, hyperdense shadow by X-ray film; no similar changes were observed in control group. FISH showed that the male EPC containing Y chromosome was found in the wall of new vessels in the defect of experimental group, while no male EPC containing Y chromosome was found in control group. The percentage of new bone formation in defect area was 91.63% ± 4.07% in experimental group and 59.45% ± 5.43% in control group, showing significant difference (P lt; 0.05). Conclusion Simvastatin can promote bone defect repair, and its mechanism is probably associated with inducing EPCs homing and enhancing vasculogenesis.
Objective
To construct recombinant lentiviral vectors of porcine bone morphogenetic protein 2 (BMP-2) gene and to detect BMP-2 gene activity and bone marrow mesenchymal stem cells (BMSCs) osteogenetic differentiation so as to lay a foundation of the further study of osteochondral tissue engineering.
Methods
BMSCs were isolated from bone marrow of 2-month-old Bama miniature porcines (weighing, 15 kg), and the 2nd generation of BMSCs were harvested for experiments. The porcine BMP-2 gene lentiviral vector was constructed by recombinant DNA technology and was used to transfect BMSCs at multiplicity of infection (MOI) of 10, 25, 50, 100, and 200, then the optimal value of MOI was determined by fluorescent microscope and inverted phase contrast microscope. BMSCs transfected by BMP-2 recombinant lentiviral vectors served as experimental group (BMP-2 vector group); BMSCs transfected by empty vector (empty vector group), and non-transfected BMSCs (non-transfection group) were used as control groups. RT-PCR, immunohistochemistry staining, and Western blot were performed to detect the expressions of BMP-2 mRNA and protein. Then the BMSCs osteogenesis was detected by alkaline phosphatase (ALP) staining, ALP activities, and Alizarin red staining.
Results
The recombinant lentiviral vectors of porcine BMP-2 gene was successfully constructed and identified by RT-PCR and gene sequencing, and BMSCs were successfully transfected by BMP-2 recombinant lentiviral vectors. Green fluorescent protein could be seen in the transfected BMSCs, especially at MOI of 100 with best expression. The immunohistochemistry staining and Western blot showed that BMSCs transfected by BMP-2 recombinant lentiviral vectors could express BMP-2 protein continuously and stably at a high level. After cultivation of 2 weeks, the expression of ALP and the form of calcium nodules were observed.
Conclusion
The porcine BMP- 2 gene lentiviral vector is successfully constructed and transfected into the BMSCs, which can express BMP-2 gene and protein continuously and stably at a high level and induce BMSCs differentiation into osteoblasts.
ObjectiveTo observe the ability of osteogenesis in vivo using the injected absorbable polyamine acid/calcium sulfate (PAA/CS) composites and assess their ability to repair bone defects.
MethodWe selected 48 New Zealand white rabbits, and half of them were male with a weight between 2.0 and 2.5 kg. Bone defect models were made at the rabbit femoral condyle using electric drill, and the rabbits were divided into two groups. One group accepted implantation of the material at the defect, while nothing was done for the control group. After four, eight, twelve and sixteen weeks, the animals were killed. The line X-ray and hard tissue slices histological examination (HE, MASSON staining) were observed to assess the situation of degradation, absorption and bone formation of the material.
ResultsFour weeks after operation, bone defect of the experimental group had no obvious callus growth on X-ray imaging. Histology showed that the material began to degrade and new immature trabecular bone grew. The bone defect of the experimental group had a small amount of callus growth on X-ray imaging after eight weeks. And histology showed that the material continued to degrade and new immature trabecular bone grew continually. There was an obvious callus growth after twelve weeks, and the bone defect area had smaller residual low-density shadow on X-ray imaging. Histology showed that most of the materials degraded and parts of woven bone grew into lamellar bone. After sixteen weeks, the composites were absorbed completely, replaced by new bone tissues, and the new bone was gradually changed from woven bone into mature plate of bone. There was no significant change in bone defect in the control group within twelve weeks, and part of bone defect hole became smaller, and partial edge repair could be detected.
ConclusionsThe PAA/CS composites can be completely degraded and absorbed, with a certain activity of bone formation, expected to be used as bone repair materials.
Osteoblasts were cultured and isolated from a piece of tibial pettiosteum of four New-Zealandrabbits. After subeultured,these cells Were incubatd in vitro with tritiated thvmidine for 36 hoursand then these labeled cells were implanted in the subeutaneous layer of the defects of the auriclarcartilage and the radial bone, After 2 weeks and 4 weeks respectively, these rabbits were killed andthe spoimens were obtained from the site where the cells had been transplanted. The transformation of these cells was observed by autoradiographic method. The results indicated that nearly all of the cultured cells were labeled. After 2 weeks, it was observed that many labeled osteoblasts were in different stages of differentiation, some were beried by extracellular matrix and resembled osteocyte, thers were differentiated into chondrocyte-like cell. In addition, some labeled osteoblasts were congregated in the form of multinucleated osteoclast. After 4 weeks , in the subcutaneous layer the labeled osteoblasts were changed to osteoid tissue and in the defect of the auricular crtilage these cells transformed into chondritic tissue; moreover, those labeled osteoblsts which had been implanted into the radial defect had differentiated into typical bone tissue. The results of this research indicated that the osteoblasts isolated from the periosteum if reimplanted to the same donor might be possible to repair the bone and cartilage defects.
Objective To explore the in vitro osteogenesis of the chitosan-gelatin scaffold compounded with recombinant human bone morphogenetic protein 2 (rhBMP-2). Methods Recombinant human BMP-2 was compounded with chitosan-gelatin scaffolds by freezedrying. 2T3 mouse osteoblasts and C2C12 mouse myoblasts were cultured and seeded onto the complexes at thedensity of 2×104/ml respectively. The complexes were divided into two groups. Group A: 2T3 osteoblasts seeded, consisted of 14 rhBMP-2 modified complexes. Each time three scaffolds were taken on the 3rd, 7th, 14th, and 21st day of the culturing, then the expression of osteocalcin gene (as the marker of bone formation) in adherent cells was detected by semiquantitative RT-PCR with housekeeping gene β-tubulin as internalstandard. The other 2 rhBMP-2 modified complexes were stopped being cultured on 14th day after cell seeding, and the calcification of the complexes was detected by Alizarian Red S staining. Five scaffolds without rhBMP-2 modification as the control group A, they were stopped being cultured on 14th day after cell seeding. Of the 5 scaffolds, 3 were subjected tothe detection of osteocalcin gene expression and 2 were subjected to the detection of calcification. Group B: C2C12 myoblasts seeded, had equal composition andwas treated with the same as group A. Besides these 2 groups, another 2 rhBMP2 modified complexes with 2T3 osteoblasts seeding were cultured for 3 days and then scanned by electron microscope (SEM) as to detect the compatibility of the cell to the complex. ResultsSEM showed that cells attached closely to the complex and grew well. In group A, the expression level(1.28±0.17)of osteocalcin gene in cells on rhBMP-2 modified complexes was higher than that (0.56±0.09) of the control group A, being statistically -significantly different(P<0.05) control. C2C12 myoblasts which did not express osteocalcin normally could also express osteocalcin after being stimulated by rhBMP-2 for at least 7 days. Alizarian Red S staining showed that there was more calcification on rhBMP-2 modified complexes in both groups. There were more calcification in the group compounded with rhBMP-2, when the groups were seeded with the same cells. Conclusion The complexmade of rhBMP-2 and chitosan-gelatin scaffolds has b osteogenesis ability in vitro.
Objective To establish a method of isolating and culturing adult human bloodderived mesenchymal stem cells(MSCs) and to investigate their osteogenic potential in vitro. Methods Thirty peripheral blood sampleswere collected from 30adult volunteers(15 ml per person).Adult human MSCs derived from peripheral blood were isolated from the lymphocyte separation fluid fraction of mononuclear cells, cultured in α-Modified Eagle’s Medium with low glucose containing 20% fetal bovine serum, and proliferated through a process of subculturing. The phenotype of MSCs was analyzed with flow cytometry. For in vitro osteogenic differentiation, MSCs from the second passage grew in the presence of osteogenic supplements (100 nmol/L dexamethasone,10 mmol/L β-glycerophosphate,50 μmol/L vitamin C, and 10 nmol/L 1,25-2-hydroxide vitamin D3). In the fifth passage cells, the activity of alkaline phosphatase, the expression level of collagen typeI, osteocalcin and osteonectin were determined. And the calcium tubercle formation would be examined after the continual one-month culture of the fifth passage. Results MSCs exsited in the pheripheral blood of adult human. And the clone forming efficiency of blood-derived MSCs was 0.27±0.22/106 mononuclear cells. The MSCs expressed CD44,CD54,CD105,and CD166,but did not CD14, CD34, CD45,and CD31.Under the function of osteogenic supplements, the MSCs were found to be higher activity of alkaline phosphatase and higher expression levels of collagen type Ⅰ, osteocalcin and osteonectin. And the calcium tubercle formation was examined throughtetracycline fluorescence labeling method. Conclusion The isolation and cultureconditions established for adult human MSCs may select a distinct population of peripheral blood-derived adherent cells. Adult human blood-derived MSCs possess osteogenic potential in vitro, and may be used as seed cells for bone tissue engineering.
Objective To evaluate the osteogenesis of three bio-bone derived materials in repairing segmental bone defects. Methods Sixty Japanese rabbits were made 10 mm radius segmental defects and divided into 5 groups(groups A, B, C ,D and E,n=12). Composite fully deproteinised bone(CFDB, group A), partially deproteinised bone(PDPB, group B), partially decalcified bone(PDCB, group C), autogenous iliac bone graft(group D) and no implant(group E) were implanted into the radius segmental bone defects of rabbits. The specimens were examined after 4, 8, 12 and 24 weeks; the osteogenesis was evaluated through X-ray radiograph and undecalcified solid tissue histological examination.Results The border between the material and host’s bone was distinct after 4 weeks and blurred after 8 weeks; the density of partial edge of the material was similar to that of radii after 12 weeks. The medullary cavity of bone reopened in group B; the density of most defect area was similar to that of the host bone and there was a few high density shadow in group C; the density of most defect area was higher than that of host bone in group A after 24 weeks. There was no significant difference in radiograph scoring between groups A, B and C after 4 weeks and 8 weeks(P>0.05); the scores of group B and C were higher than that of group A after 12 weeks(P<0.05); and the scores were arranged as follow: group Dgt;group Bgt; group Cgt;group A after24 weeks(P<0.05). Bone callusgrew toward defect area and new bone adhered to the material after 4 weeks and 8 weeks; more new bone formed, and the materials were absorbed and degraded with time. The quantity of bone formation was more in group D than in group B andin group B than in group C and in group C than in group A after 24 weeks(P<0.05).Conclusion PDPB had good osteogenesis in repairing the segmental bone defect, PDCB was inferior to it, both PDPB and PDCB are fit to repair segmental bone defect. Both of them were inferior to autogenous bone.
Ceramiclike xenogeneic bone (CXB) was obtained from the fresh bone of pig ribs being treated by physical and chemical methods to deprive of its organic substance. The CXB possessed the same natural porous network system as that of the human. The CXB was cultured with the bone marrow stromal cells of rabit. When the marrow cells had integrated with the CXB, thus a new material was obtained. (CXB-BM), and was implanted sacro-spinal muscle of rabbit. The specimens were observed under phase microscope, light microscope and electronic scanning microscope. The results showed that: at the 2nd week after the implantation of CBX-BM composite material there began the new bone formation, and the rate of bone formation was increased with time. There was evident new bone formation after 24 weeks. The process of the new bone formation were quite similar to the composite graft of HAP red autogenous and marrow, but the former degraded faster and formed typical cancellous structure earlier. There was no new bone formation when CXB was implanted alone in the control. Both the mechanism of osteogenetic potential and its clinical application were discussed.
Objective To investigate and compare the osteogenic potential of three kinds of calcium phosphate ceramic as carriers for recombinant human bone morphogenetic protein-2(rhBMP-2) in vivo.Methods BCPceramics (HA,TCP,HA/TCP) impregnated with rhBMP-2 (experimental groups) and without rhBMP-2(control groups) were implanted into 6 muscles pockets on the dorsum of 3month-old Wistar rabbits. The rabbits were sacrificed 2, 4 and 8 weeks after implantation and bone induction was estimated by alkaline phosphatase(ALP) activity measurement. The implants were also examined histologically and histomorphometrically by HE staining and computerized graphical analysis. Results The ALPactivity of implants withrhBMP-2 was higher than that of control groups(P<0.05), but there was no difference between 2 and 4 weeks in experimental groups. In all experimental groups,theimplants exhibited that new bone formation increased with the lapse of time. The amount of new bone formation is more in -HA/rhBMP-2 group than in the other two group in the 2nd and 4th weeks, but there was no difference between them (P>0.05).In the 8th week, the amount of bone formation was most in HA/TCP with -rhBMP-2, and was more than that in the 2nd and 4th weeks. Whereas in control groups, there was only fibrous connective tissue. Conclusion HA/TCP- is a good carriers of rhBMP-2 and can be used as bone substitutes clinically.
In order to explore further the regulatory factors to the potentiality in inducing osteogenesis by fibroblasts, the fibroblasts were isolated, and purified from human skin, and were grown in incubation in the media of EGF, IL-6, TNF-alpha and BMP2 at different concentrations for two weeks, then, the markers for osteogenic features were investigated by biochemistry, histochemistry and electron microscopic observations. It was found that the combined use of TNF-alpha and BMP2 could stimulate fibroblasts to secrete alkaline phosphatase, osteocalcin and collagen, and the morphological changes of the fibroblasts were also very striking. In the extracellular matrix, the collagen fibrils, with or without periodicity, were arranged regularly or randomly oriented, and numerous minute calcium granules were interspersed among them. The fibroblasts were interwoven one on top of another in the form of multilayer structure and on the surface, there were secreting granules and piling up of calcium crystals which coalessed steadily and increased in size in forming bony nodules. It was considered that TNF-alpha and BMP2 were capable of inducing the fibroblasts to form bone.
