Objective To study the biological activities ofthe nerve regeneration conditioned fluid (NRCF), especially to further separateand identify the protein bands of the relative molecular mass of (232-440)×103. Methods The silicone nerve regeneration chambers were implanted between the cut ends of the sciatic nerve in 6 New Zealand white rabbits (weight, 1.8-2.5 kg). The proteins in NRCF were separated by the native-polycrylamide gel electrophoresis (Native-PAGE), the protein bands of the relative molecular mass of (232-440)×103 were analyzed by the Shotgun technique, liquid chromatography, and mass spectrometry. Results The Native-PAGE result showed that there was 1 protein band of the relative molecular mass over 669×103, (232-440)×103 and (140-232)×103,respectively, and 6 bands of the relative molecular mass of (67-140)×103.Besides, 54 proteins were identified with at least 2 distinct peptides in 1 protein band of the relative molecular mass of (232-440)×103, including 4 unnamed protein products, mainly at the isoelectric points of 5.5-8.0 and of the relative molecular mass of (10-40)×103. Based on their functions in the protein database, allthe identified proteins in this study were classified into the following 5 groups: conjugated protein (43%), transport protein (30%), enzyme (6%), signal transducer (4%), and molecular function-unknown protein (17%). At the subcellular localization of the identified proteins, there was mainly a secreted protein (63%), and the remaining proteins were localized in the membrane and cytoplasm. Conclusion Native-PAGE and the Shotgun technique can effectively separate and identify proteins from NRCF, and can identify the components of the protein band of the relative molecular mass of (232-440)×103 and provide basicinformation on the unnamed protein products in NRCF.
Objective To investigate the outcome of repairing the peripheral nerve defects with the tissue engineered nerve constructed by Schwann cells and fibrin glue. Methods Wallerian degenerated sciatic nerve were harvested from the 4-week-old New Zealand rabbits for culture of Schwann cells. The Schwann cells were then separated, amplified and purified, and then were identified by the S-100 protein immunochemical staining. The cultured Schwann cells (1×106/ml) were mixed with fibrin glue to form the Schwann cell-fibrin glue compound, which was observed by the inverted phase contrastmicroscope. The compound filled some silicone tubes (Group A) and biomembrane (Group B) to fabricate the tissue engineered nerves with a purpose of repairing the 10-mm defects in the New Zealand rabbit tibia nerves. The autologous nerve grafting was performed in Group C. The electrophysiological examination and the histomorphological analysis were performed at 10 weeks after the transplantation. Results All the rabbits survived through the experiment. In Group A, all the rabbits developed an ulcer in the soles of their left feet at 3-4weeks after the transplantation, while less ulceration developed in Groups B and C. At 10 weeks after the transplantation, the electrophysiological examination was performed, the elective stimulation failed to pass through the nerve grafts, and no composed muscular action potential was found in all the rabbits in Group A; the elective stimulation could pass through all the nerve grafts in Groups B and C, and could evoke the composed muscular action potential; the composed muscular action potential and the nerve conduct velocity in the two groups were 4.21±0.82 mV and 3.40±5.40 m/s vs. 4.80±1.15 mV and 36.55±6.43 m/s(Pgt;0.05). In Group A, no regrown axon was found in the nerve grafts, but neuromawas found to have formed in the both ends of the silicon tube. In Groups B and C, there was no obvious neuroma formation but regrown axons could be found to have regenerated. The histomorphological analysis on the regrown axons showed thatthere was no statistically significant difference between Groups B and C. Conclusion The tissue engineered nerve fabricated with Schwann cells, fibrin glue, and biomembrane can promote the nerve regeneration, and its reparative effect is similar to that of the autologous nerves; therefore, the future of its clinical practice is brilliant.
Objective To explore the histological changes of bio-derived bone prepared by different methods after implantation, and to provide the scaffold material from xenogeneic animal for tissue engineering. Methods Theextremities of porcine femur were cut into 0.5 cm×0.5 cm×0.5 cm. Then they were divided into 5 groups according to different preparation methods: group A was fresh bone just repeatedly rinsed by saline; group B was degreased; group C was degreased and decalcificated; group D was degreased, acellular and decalcificated; group E wasdegreased and acellular. All the materials were implantated into femoral muscle pouch of rabbit after 25 kGy irradiation sterilization. The cell counting ofinflammatory cells and osteoclasts, HE and Masson staining, material degradation, collagen and new bone formation were observed at 2, 6, and 12 weeks postoperatively. Results The residue level of trace element in biomaterials prepared by different methods is in line with the standards. All the animals survived well. There were no tissue necrosis, fluid accumulation or inflammation at all implantation sites at each time point. The inflammatory cells counting was most in group A, and there was significant difference compared with other groups(P<0.05). There was no significant difference in osteoclasts counting among all groups. For the index of HE and Masson staining, collagen and new bone formation, groups C and D were best, group E was better, and groups A and B were worse. Conclusion The degreased, acellular and decalcificated porcine bone is better in degradation,bone formation, and lower inflammatory reaction, it can be used better scaffold material for tissue engineered bone.
Objective To study the mechanism of restenosis of the vein graft and the effect of the grafting injury to the vein graft. Methods One side of the 36 healthy rabbits was randomly chosen as the V-A group, and on the side a 1.5cmlong femoral vein was obtained, and an 0.5-cm-long segment of the obtained femoral vein was separated as the control group. The remaining 1-cm-long femoral vein was inverted and was autogenously implanted into the femoral artery on the same side of the rabbit. The other side of the rabbits was chosen as the V-V group, and on this side a 1-cm-long femoral vein was obtained ex vivo and then was sutured in situ. The vein grafts on both sides were harvested 4 weeks after operation. The specimens from the harvested vein grafts were stained with HE and theelastic fiber Victoria blue for an observation on the histological changes in the walls of the vein grafts, and the specimens were also stained by the immunohistochemistry of the proliferating cell nuclear antigen (PCNA) for an observation on the wall cell proliferation of the vein grafts. The changes in the ultrastructure of the proliferated wall cells of the vein grafts were observed under electron microscope. The two sides of the rabbits were compared. Results The smooth muscle cells of the media developed hyperplasia, but theintima and the media remained unchanged in their thickness (3.50±0.41 μm, 12.23±1.59 μm) in the V-V group, with no difference when compared with the control group (3.40±0.37 μm, 12.14±1.62 μm); however, when compared with the V-A group (25.60±3.21 μm, 21.30±2.47 μm),there was a significant difference in the thickness (Plt;0.01). There were no cells positive for PCNA by the immunohistochemistry examination in the control group. The cells positive for PCNA were found in the intima and the media in both the V-V group and the V-A group; however, the percentageof the cells positive for PCNA in the intima and the media was significantly greater in the V-A group than in the V-V group (16.4%±1.9% and 36.5%±3.7% vs 5.9%±1.3% and 23.4%±3.4%, Plt;0.01). In the V-V group, the endothelial cell could be observed under transmis-sion electron microscope, which was flat and had a processlike villus at its free end, and the endothelial cells were closely arranged andhad hyperplasia of the smooth muscle cells in the media. But in the V-A group,the endothelial cells had an obvious hyperplasia with an irregular shape and a widened space between the cells, and in the intima a great amount of the smooth muscle cells could be observed, which had a broken basement membrane. The smooth muscle cells also had an obvious hyperplasia in the media. The shape and alignment of the endothelial cells in the control group were similar to those in the V-V group, but the hyperplasia of the smooth muscle cells was not observed in the media. Conclusion The grafting injury can cause hyperplasia ofthe vascular wall cells, and if the hemodynamics is changed simultaneously, more serious hyperplasia and cell migration can be observed from the media to the intima, resultingin restenosis of the blood vessels. So, if we can reduce the grafting injury and improve the microcirculation of the vein graft, we may find out the methods ofpreventing restenosis of the vein graft. The animal model of the V-V graftcan help to understand the mechanism of restenosis of the vein graft.
Objective To study the feasibility of core-binding factor α1 (Cbfa1) gene modified marrow mesenchymal stem cells (MSCs) composed with porcine acellular bone extracellular matrix in repairing the radial defects. Methods Radial defects of 1.2 cm in length were created in 40 Japanese white rabbits and they were divided into four groups. In group A, MSCs isolated from homogeneous rabbits were infected with Cbfa1 recombinant adenovirus and implanted into acellular bone exteracellular matrix, and then the complexes were implanted into defects. In group B, the complexes including the MSCs without Cbfa1 gene-modified and scaffoldmaterial were implanted into defects. In group C, only the scaffold material was implanted. In group D, defects were not treated as the control. The macroscopic, X-ray and histologic analysis were performed to evaluate the repair effect at 4, 8 and 12 weeks postoperatively. The repaired radius were examined by biomechanical test at 12 weeks postoperatively. Results By gross examination,mature hard new bone formed at grafted areas at 12 weeks postoperativelyin group A, osteotomized ends connected by much callus in group B and less callus in group C at grafted areas. In contrast, bone nonunion formed in group D. X-ray and histological examination showed that the repaired results of defects in the group A were better than those in others groups evidently in extracellular matrix degradation, new bone remodeling and marrow cavity rebuilding at 4 and 8 weeks postoperatively. At 12 weeks postoperatively, the cortical bone became mature lamellar bone, new bone remolding was complete and marrow cavity was smooth in group A. Only proximal end of defects showed that marrow cavity was remolded partially in group B. The continuous callus could be observed in bone defect, and no obvious marrow cavity remolding was observed in group C. Lots of fibrous connective tissue filled in defect and bone nonunion was shown in group D. There was no significant difference in the damage compress loading of repaired radius between groups A, B and D (Pgt;0.05), but there was significant difference between groups C and D(Plt;0.01).Conclusion These results demonstrate that Cbfa1 gene modified MSCs combined with acellular bone extracellular matrix can be used to repair rabbit radial defects.
Objective To evaluate repair of critical-sized cranialdefect with tissue engineered bone fabricated by coral, bone mesenchymal stem cells(MSCs) and sustainedly released recombinant human bone morphogenetic -protein 2 (rhBMP-2) by collagen. Methods Three scaffolds of rhBMP-2+coral,collagen+rhBMP-2+coral and MSCs+collagen+rhBMP-2+coral were fabricated. Forty New Zealand rabbits were made the models of critical-sized defects and divided into5 groups according to different implants: group Ⅰ, auto-ilium; group Ⅱ,coral; group Ⅲ, rhBMP-2+coral; grop Ⅳ, collagen+rhBMP-2+coral; and group Ⅴ,MSCs+collagen+rhBMP-2+coral. Repair of bone defect was evaluated after 8 and 16 weeks of implantation by gross obeservation, X-ray,HE staining and Masson’s trichrome staining. Results Repair ofbone defect in group Ⅴ was similar to that in group Ⅰ, andwas better than that in group Ⅳ; and group Ⅲ was worse. The gross appearance showed that defect region filled with bony tissue which had similar strength to adjacent bone and formed bone union with surrounding bone. The X-ray result displayed high radiopacity(80.45%±2.52% in the 16thweek). Histological observation showed new lamellar bone tissue and with few pore blank area. However, only transpasent fibrous tissue filled the defect in group Ⅱ. Conclusion Collagen may be a suitable sustained release system for rhBMP-2. And MSCs may have important effect on enhancing repair of bone defect. Tissueengineered bone fabricated by MSCs+collagen+rhBMP-2+coral may be a useful material for bone defect repair.