Objective To research the gene expression of transforming growth factor β1 (TGF-β1) in zone Ⅱ flexor tendon wound healing of rabbit. Methods Sixty New Zealand white rabbits forepaws(left side) underwent complete transection and the middle digit flexor digitorum profundus tendon in zone Ⅱ were repairedby Kessler methods as the experimental group. The normal right forepaws served as the control group. The tendons and tendon sheaths were harvested at 1, 7, 14, 21, 28and 56 days after repair(n=10). The expression patterns ofTGF-β1 wereanalyzed by in situ hybridization and immunohistochemistry staining methods. Results The in situ hybridization examination revealed thatTGF-β1 mRNA expression upregulated at 1 day, reached the peak levels at 1421 days and remained high levels up to 56 days in the experimental group. The expression ofTGF-β1 mRNA in control group was lowerthan that in the experimental group, showing statistically significant difference (Plt;0.05). The results of immunohistochemical staining was similar to that of in situ hybridization. Conclusion The normal tendon and tendon sheath cells are capable ofTGF-β1 production. The cytokine is activated in tendon wound condition. The upregulation of this cytokine in both tendon and tendon sheath cells are coincidence with both extrinsic and intrinsic mechanisms for tendonrepair.
Objective To explore the regulator factor of osteogenes is induced by the fibroblast in vitro so as to provide enough seeding cells for the bon e tissue engineering. Methods The fibroblasts were isolated and purified from granu lation of New Zealand rabbits, and they were incubated in the media offibronectin (FN) 10, 20, 40, 60 and 80 μg/ml, respectively, in the experimenta l grou ps 1- 5,but there was no FN in the control group. The markers for osteogenic features were investigated by fibroblast morphogenesis,calcium nodules formationratios,labeling of tetracycline fluorescence, labeling of 3H-TdR, determination of o steocaline, and labeling of 3H-proline within 2 weeks. Results The morphologic al changes of the fibroblasts were manifested as transference from a long spindle to a round or multiple form, shifted nucleus increased in number, confluenced and formed multilayered structure. There was a piling-up of calcium crystals that were gradually merged into foggy substances. The foggy substances increased and formed nodules. The calcium nodules formation ratios were as follows: 15.35%± 3.45%in the control group, and 53.73%± 9.49%, 75.21%± 9.80%, 98.34%± 15.2 0%, 61.83%± 10.04%, and 45.11%± 8.70% in the experimental groups 1.5 ,respectively. There was a significant difference between the control group and the 5 experimental groups at 14 days (Plt;0.05), and a significant differenc e be tween the experimental group 3 and the other experimental groups at 14 days (Plt;0.05). The histochemical study on the nodules with the specific labeling of tet racycline fluorescence indicated that the nodules were composed of new bones. Conclusion Fibronectin can stimulate the fibroblast to prolifer ate, secrete osteocaline, and synthesize collagen fibrils. Fibronectin, in an optimal dose of 40 -60 μg/ml, is capable of inducing the fibroblast to form the bone.
In this paper,the changes of activities of enzymes relating toenergy metabolism in rabbit's retina during acute ocular hypertension were observed.The activities of succinate dehydrogenase and adenosine triphosphatase were foud to be reduced,while the activities of the lactatic dehydrognease and glucose-6-phosphatase increased.The results reveal the disturbance of metabolism of energy in retina undergone acute ocular hypertension,and suggest that this might be the underlying factors relating to the defects of the functions and structures of the retina. (Chin J Ocul Fundus Dis,1993,9:141-144)
ObjectiveTo observe the morphological characteristic by implanting domestic porous tantalum in rabbit patellar tendon and to evaluate biocompatibility features so as to provide experimental basis for porous tantalum used as interface fixation between tendon and bone. MethodsA total of 48 adult New Zealand white rabbits, male or female, weighing 2.5-3.0 kg, were selected. Porous tantalum flake (5 mm×5 mm×2 mm) was implanted in the left patellar tendon (experimental group) and the same size porous titanium flake in the right patellar tendon (control group). The animals were sacrificed at 2, 4, 8, and 12 weeks after implantation, then the specimens were harvested for gross observation, HE staining, scanning electron microscope (SEM) observation, and hard slices observation. ResultsNo animal died after operation. Porous tantalum was bonded closely with host tendon and no inflammatory reaction was found. Loose and thick fibrous capsule was observed at the beginning and became density and thinner in the end by microscope, showing significant difference between different time points in 2 groups (P<0.05), but no significant difference was found between 2 groups at different time points (P>0.05). The SEM observation showed that fibrous tissue attached to the surface and inner walls of porous tantalum at early stage, and extended on the material to reach confluence at late period, but the experimental group was more than the control group. Hard slices observation showed that the collagen fibrils were seen on porous tantalum interface with host tendon, and blood vessels grew into the pores. The control group and the experimental group showed no significant difference. ConclusionThe domestic porous tantalum has good biocompatibility. Connection and integration can be established between tendon and porous tantalum, and therefore it could be used in reconstruction of tendon-bone fixation device.
Fluorescein angiography(FA)was performed in 31 pigmented rebbits.The angiograms were evaluated as prints and as negative film under a light microscope.The patterns of retinal pigment epithelial(RPE)cells were studied by scaning electron microscopy and fluorescein light one,compared with other rabbits belonging to the same species.In 58 eyes,we observed the hexagonal pattern of RPE cell.It showed central hypofluorescent area surrounded by hyperfluorescent rim,which was easily seen away from the medullary rays by three or more disc diameters and became larger in the periphery than that in the posterior pole.There were no finding in four lightly pigmented eyes. (Chin J Ocul Fundus Dis,1994,10:226-228)
Objective To evaluate the feasibility and validity of chondrogenic differentiation of marrow clot after microfracture of bone marrow stimulation combined with bone marrow mesenchymal stem cells (BMSCs)-derived extracellular matrix (ECM) scaffold in vitro. Methods BMSCs were obtained and isolated from 20 New Zealand white rabbits (5-6 months old). The 3rd passage cells were cultured and induced to osteoblasts, chondrocytes, and adipocytes in vitro, respectively. ECM scaffold was manufactured using the 3rd passage cells via a freeze-dying method. Microstructure was observed by scanning electron microscope (SEM). A full-thickness cartilage defect (6 mm in diameter) was established and 5 microholes (1 mm in diameter and 3 mm in depth) were created with a syringe needle in the trochlear groove of the femur of rabbits to get the marrow clots. Another 20 rabbits which were not punctured were randomly divided into groups A (n=10) and B (n=10): culture of the marrow clot alone (group A) and culture of the marrow clot with transforming growth factor β3 (TGF-β3) (group B). Twenty rabbits which were punctured were randomly divided into groups C (n=10) and D (n=10): culture of the ECM scaffold and marrow clot composite (group C) and culture of the ECM scaffold and marrow clot composite with TGF-β3 (group D). The cultured tissues were observed and evaluated by gross morphology, histology, immunohistochemistry, and biochemical composition at 1, 2, 4, and 8 weeks after culture. Results Cells were successfully induced into osteoblasts, chondrocytes, and adipocytes in vitro. Highly porous microstructure of the ECM scaffold was observed by SEM. The cultured tissue gradually reduced in size with time and disappeared at 8 weeks in group A. Soft and loose structure developed in group C during culturing. Chondroid tissue with smooth surface developed in groups B and D with time. The cultured tissue size of groups C and D were significantly larger than that of group B at 4 and 8 weeks (P lt; 0.05); group D was significantly larger than group C in size (P lt; 0.05). Few cells were seen, and no glycosaminoglycan (GAG) and collagen type II accumulated in groups A and C; many cartilage lacunas containing cells were observed and more GAG and collagen type II were synthesized in groups B and D. The contents of GAG and collagen increased gradually with time in groups B and D, especially in group D, and significant difference was found between groups B and D at 4 and 8 weeks (P lt; 0.05). Conclusion The BMSCs-derived ECM scaffold combined with the marrow clot after microfracture of bone marrow stimulation is effective in TGF-β3-induced chondrogenic differentiation in vitro.
Objective To investigate the effect of repairing bone defect with tissue engineered bone seeded with the autologous red bone marrow (ARBM) and wrapped by the pedicled fascial flap and provide experimental foundation for cl inicalappl ication. Methods Thirty-two New Zealand white rabbits (male and/or female) aged 4-5 months old and weighing2.0-2.5 kg were used to make the experimental model of bilateral 2 cm defect of the long bone and the periosteum in the radius. The tissue engineered bone was prepared by seeding the ARBM obtained from the rabbits on the osteoinductive absorbing material containing BMP. The left side of the experimental model underwent the implantation of autologous tissue engineered bone serving as the control group (group A). While the right side was designed as the experimental group (group B), one 5 cm × 3 cm fascial flap pedicled on the nameless blood vessel along with its capillary network adjacent to the bone defect was prepared using microsurgical technology, and the autologous tissue engineered bone wrapped by the fascial flap was used to fill the bone defect. At 4, 8, 12, and 16 weeks after operation, X-ray exam, absorbance (A) value test, gross morphology and histology observation, morphology quantitative analysis of bone in the reparative area, vascular image analysis on the boundary area were conducted. Results X-ray films, gross morphology observation, and histology observation: group B was superior to group A in terms of the growth of blood vessel into the implant, the quantity and the speed of the bone trabecula and the cartilage tissue formation, the development of mature bone structure, the remolding of shaft structure, the reopen of marrow cavity, and the absorbance and degradation of the implant. A value: there was significant difference between two groups 8, 12, and 16 weeks after operation (P lt; 0.05), and there were significant differences among those three time points in groups A and B (P lt; 0.05). For the ratio of neonatal trabecula area to the total reparative area, there were significant differences between two groups 4, 8, 12, and 16 weeks after operation (P lt; 0.05), and there were significant differences among those four time points in group B (P lt; 0.05).For the vascular regenerative area in per unit area of the junctional zone, group B was superior to group A 4, 8, 12, and 16 weeks after operation (P lt; 0.05). Conclusion Tissue engineered bone, seeded with the ARBM and wrapped by the pedicled fascial flap, has a sound reparative effect on bone defect due to its dual role of constructing vascularization and inducing membrane guided tissue regeneration.
Objective To evaluate the effect of WO-1 on repair of the bone defect in the New Zealand rabbit radius by an oral or local administration. Methods Bone defects were surgically created in the bilateral radii of 36 Zealand rabbits (1.6-2.0 kg), which were randomly divided into3 groups. In Group A, the defective areas were given WO-1 0.1 ml (50 mg/ml) by the local injections; in Group B, the rabbits were given WO-1 5 mg each day by the oral administration. Group C was used as a control group. Among each of the 3 groups, 4 rabbits were randomly selected and were sacrificed at 20, 30 and 60 days after operation, respectively. Then, the serological, X-ray and histological examinations were performed. Results The serum alkaline phosphatase and bone glaprotein levels were significantly higher at 20 and 30 days after operation in Groups A and B than in Group C, but significantly lower at 60 days after operation in Groups A and B than in Group C(Plt;0.01). The X-ray and histological examinations at 20, 30 and 60 days after operation revealed that the callus formation and remodeling were earlier in Groups A and B thanin Group C, and the remodeling was earlier and better in Group A than in Group B. Conclusion WO-1 can promote the repair of the radial defect in a rabbit; however, further studies on the doseeffect relationship, administration time, and administration route are still needed.
Objective To construct the lentiviral vector containing homo sapiens forkhead box C2 (Foxc2) gene and to detect its expression in bone marrow mesenchymal stem cells (BMSCs) of rabbits. Methods Human Foxc2 gene coding region fragment was obtained by RT-PCR and then cloned into the plasmid of LV-green fluorescent protein (GFP) to prepare Foxc2 lentiviral plasmid. Foxc2 lentiviral plasmid, pGC-LV, pHelper1.0, and pHelper2.0 were co-transfected into 293T cells to obtain recombinant virus containing Foxc2 gene. The lentiviral titer was detected. BMSCs were isolated from bone marrow of rabbit and infected with Foxc2 recombined lentiviral, then the optimum multiplicity of infection (MOI) was determined by detecting the intensity of fluorescence expression. The expression of Foxc2 in the infected BMSCs was determined at 1, 3, and 7 days after transfection by inverted fluorescence microscope and Western blot. After osteogenic induction, Alizarin red staining was done to observe the formation of mineralized nodule. Results The Foxc2 recombinant lentiviral vector was constructed and was confirmed by restriction enzyme digestion and sequencing analysis. It could efficiently transfect 293T cells and express in 293T cells. The lentiviral titer was 2 × 108 TU/mL. The optimum MOI was 200. The inverted fluorescence microscope observation showed that the Foxc2 gene expressed in 84.5% ± 4.8% of infected BMSCs at 3 days after transfection. The expression of Foxc2 in infected BMSCs was stable and high, and increased gradually within 7 days after transfection by Western blot. At 2 weeks after osteogenic induction, Alizarin red staining showed that there were a large number of red calcified matrix deposition in the cytoplasm. Conclusion Foxc2 recombined lentivirus with high viral titer is successfully constructed and packaged, and the Foxc2 gene can be transfected into BMSCs with stable and high expression of Foxc2 in infected cells, and these cells may be applied for gene therapy of avascular necrosis of the femoral head.
Objective To study the effect of various doses of estrogen on tissue injury, blood supply and survival area of skin flap and to investigate its mechanism. Methods Thirty New Zealand white rabbits aged 3-4 months old and weighing 1.5-2.2 kg (male or female) were used. Random pattern skin flap (12 cm × 3 cm in size) taking the central l ine of the rabbit dorsum as axis and with the pedicle attached at the proximal end was prepared, and the flap pedicle division was performed 7 days after operation. The rabbits were divided randomly into three groups (n=10 rabbits per group). At 2, 4, and 6 days after operation, the proximal edge of flap in group A and B received 100 ?g/kg and 50 ?g/kg subcutaneous injection ofestradiol benzoate, respectively, while group C received no further treatment serving as control group. General condition ofthe rabbits was observed after injection, gross observation was performed 3 and 7 days after injection, survival area of the skin flap was measured 7 days after injection, contents of malondialdehyde (MDA) and nitric oxide (NO) were tested 5 days after injection, and the flaps were harvested 4 and 7 days after injection to receive histology and no significant difference was noted between group A and group B (P gt; 0.05). The NEU counts 4 days after injection were (18.20 ±6.24) cells/HP in group A, (21.27 ± 5.34) cells/HP in group B, and (28.78 ± 7.92) cells/HP in group C, and at 7 days after injection, there were (15.16 ± 7.02) cells/HP in group A, (18.12 ± 6.44) cells/HP in group B, and (29.67 ± 9.12) cells/HP in group C. The VEGF score 4 days after injection was (4.02 ± 0.48) points in group A, (4.19 ± 0.66) points in group B and (3.67 ± 0.49) points in group C, and at 7 day after injection, it was (4.96 ± 0.69) points in group A, (5.12 ± 0.77) points in group B, and (3.81 ± 0.54) points in group C. Significant difference was evident between 4 days and 7 days after injection in group A or B in terms of NEU counts and VEGF score (P lt; 0.05), and difference between 4 days and 7 days after injection in group C was not significant (P gt; 0.05), and the differences among 3 groups were significant (P lt; 0.05). Conclusion Estrogen injection can increase VEGF expression and NO content of flap, decrease MDA content and NEU infiltration of flat, and improve survival area of flap.