The purpose of this study was to find some solutions to the problem of tendon cell proliferation control. Under the condition of in vitro culture, several materials including IGF-1 receptor antibody and mRNA antisense oligonucleotide were added to the culture medium to block the IGF-1-Receptor system. The effect of the material on the tendon cell proliferation was judged by cell count after incubation of 48 hours. The results showed that both IGF-1 Receptor antibody (IGF-1R alpha) and IGF-1 Receptor mRNA antisense oligonucleotide had negative effect on tendon cell proliferation (P lt; 0.01 and P lt; 0.05). These findings lead us to think that the above two materials could be used in the experiment of tendon adhesion preventing and living ready-made tendon producing.
In order to study the biological characteristics of tenocyte and fibroblast, the former was obtained from rabbit’s tendon, and the latter from rabbits’s skin. Both cells were cultured according Heuderson’s method. The cell morphology, strapping and expanding time, and the type of collagen fiber synthesized in culture were observed. The results showed that the strapping and expanding time of fibroblast was faster than that of tenocyte. The cellular arrangement of fibroblast was irregular, but that in tenocyte was regular. Type I and III collagen of fibers were found in cultured fibroblost while only type I collagen fibers were found in culture of tenocyte. The tenocyte and fibroblast could be identified individually by strapping and expanding time, arrangement of cells and type of collagen fiber synthesized.
To study the effect of autogeneic PRP on prol iferation and osteogenetic differentiation of human adipose-derived stem cells (ADSCs) in vitro. Methods ADSCs were isolated from adipose tissue obtained from donor undergoing l iposuction and were cultured, and growth condition of the cells was observed by inverted microscope. ADSCs at passage 3 were cultured in adipogenic or chondrogenic medium and underwent identification, immunofluorescence staining observations for CD29 and CD44 were performed. ADSCs at passage 3 were divided into 2 groups: PRP group cultured by osteogenic induction culture medium containing 10 mL/L PRP, and control group cultured by osteogenic induction culture medium without PRP. Then growth condition of the cells was observed by inverted microscope. MTT method was used to observe cell prol iferation activity 1, 2, 3, 4 and 5 days after culture. ALP activity detection was conducted 7, 14, 21 and 28 days after culture. ALP staining was performed on PRP group 7 and 14 days after culture. Al izarin red staining was performed on PRP group 14 days after culture to detect the formation of calcium nodule. Results Under the inverted microscope, most ADSCs at passage 3 were spindle-shaped and the doubl ing time was about 35 hours. Adipogenic and chondrogenic differentiation were confirmed, and the cells were positive for CD29 and CD44 immunofluorescence staining. MTT method revealed the absorbance value of PRP group at 1, 2, 3, 4 and 5 days was 0.137 ± 0.015, 0.219 ± 0.023, 0.367 ± 0.031, 0.586 ± 0.039 and 0.948 ± 0.046, respectively, and in the control group, it was 0.081 ± 0.009, 0.115 ± 0.012, 0.162 ± 0.017, 0.242 ± 0.025 and 0.356 ± 0.032, respectively, suggesting there were significant differences between two groups (P lt; 0.01). At 7 days after osteogenic induction, PRP group was positive for ALP staining, grey-black cell plasm and black precipitate were evident; the positive cells increased
ObjectiveTo observe the protective effect of etomidate (ET) on cultured retinal ganglion cells (RGC) with mechanical injury in vitro. MethodsNew Sprague-Dawley rat RGC was cultured in vitro and identified by double immunofluorescent labeling of Thy1.1 and microtubule associated protein 2. The cultured primary cells were randomly divided into control group, RGC scratch group, ET low dose group (1 μmol/L), ET medium dose group (5 μmol/L) and ET high dose group (10 μmol/L). The RGC mechanical injury model was established by using iris knife to culture cells in RGC scratch group and ET group with different concentration. Seven days after modeling, the RGC survival rate of each group was detected by cell count Kit 8 proliferation assay. The apoptosis rate of RGC was detected by Annexin Ⅴ/propyl iodide double staining. Single factor analysis of variance was used to compare the groups. The pairwise comparison between groups was tested by the least significant difference method. ResultsThe survival rates of RGC in RGC scratch group, ET low dose group, ET medium dose group and ET high dose group were (72.60±2.97)%, (73.73±1.14)%, (79.19±1.79)% and (83.88±0.94)%, respectively. The RGC apoptosis rates of control group, RGC scratch group, ET low dose group, ET medium dose group and ET high dose group were (5.08±0.17)%, (18.67±1.24)%, (17.96±0.74)%, (15.11± 0.56)% and (11.67±1.32)%, respectively. Comparison of RGC survival rate between groups: compared with RGC scratch group, the cell survival rate of ET low-dose group, ET medium-dose group and ET high-dose group was increased, and the difference between RGC scratch group and ET low-dose group was not statistically significant (P=0.728); the differences between RGC scratch group, ET medium dose group and ET high dose group were statistically significant (P<0.001); the difference between ET medium dose group and ET high dose group was statistically significant (P=0.002). Comparison of apoptosis rate of RGC among groups: the apoptosis rate of RGC scratch group was significantly higher than that of control group, the difference was statistically significant (P<0.001). Compared with RGC scratch group, the apoptosis rate of ET low-dose group, ET medium-dose group and ET high-dose group was decreased, and there was no statistical significance between RGC scratch group and ET low-dose group (P=0.869). The differences of apoptosis rate between RGC scratch group, ET medium dose group and ET high dose group were statistically significant (P<0.05). The difference of apoptosis rate between ET medium dose group and ET high dose group was statistically significant (P=0.007). ConclusionET has neuroprotective effect on RGC cultured in vitro with mechanical injury, and the protective effect increases with the increase of ET dose in a certain range.
Objective To investigate the influence of the exogenouscollagen on the function of cells in construction of artificial biotendon.Methods Three materials including human hair, carbon fiber(CF) and polyglycolic acid (PGA) were combined with exogenous collagen and co-cultured with standard transferred human embryonic tenocytes at a concentration of 3×106/mm3 in vitro. The cell number and morphology were observed under inverted microscope and scanning electron microscope after 2 hours, 3 days and 5 days.Results In the artificial biotendon combined with collagen, the cells concentrated around the materials and the cells adhering to the materials turned into round after 2 hours. After 3 days, the adhering cells increased. After 5 days, the shape of the cells changed from round to spindle.ConclusionExogenous collagen will facilitate the cells to adhere onto materials and proliferate.
Objective To explore an effective method of culturing the canine bladder smooth muscle cells, observe the morphological characteristics of the bladder smooth muscle cells growing on acellular small intestinal submucosa(SIS) and offer an experimental basis for reconstruction of the bladder smooth muscle structure by the tissue engineering techniques. Methods The enzymetreatment method and the explant method were respectively used to isolate and harvest the canine bladder smooth muscle cells, and then a primary culture of these cells was performed. The canine bladder smooth musclecells were seeded on the SIS scaffold, and the composite of the bladder smooth muscle cells and the SIS scaffold were co cultured for a further observation. At 5,7 and 9 days of the co culture, the specimens were taken; the bladder smooth muscle cells growing on the SIS scaffold were observed by the hematoxylin staining, the HE staining, and the scanning electron microscopy. The composite of the bladder smooth muscle cells on the SIS scaffold was used as the experimental group, and the bladder smooth muscle cells with no SIS were used as the control group. In each group, 9 holes were chosen for the seeded bladder smooth muscle cells, and then the cells were collected at 3, 5 and 7 days for the cell counting after the enzyme treatment. Morphological characteristics of the cells were observed under the phase contrast microscope and the transmission electron microscope. Expression of the cell specific marker protein was assessed by the immunohistochemical examinaiton. The proliferation of the cells was assessed by the cell counting after the seeding on the SIS scaffold. Results The primary bladder smooth muscle cells that had been harvested by the enzyme treatment method were rapidly proliferated, and the cells had good morphological characteristics. After the primary culture in vitrofor 5 days, the bladder smooth muscle cells grew in confluence. When the bladder smooth muscle cells were seeded by the explant method, a small amount of the spindleshaped bladder smooth muscle cells emigrated from the explant at 3 days. The cells were characterized by the welldeveloped actin filaments inthe cytoplasm and the dense patches in the cell membrane under the transmissionelectron microscope. The immunohistochemical staining showed the canine bladdersmooth muscle cells with positive reacting α actin antibodies. The bladder smooth muscle cells adhered to the surface of the SIS scaffold, growing and proliferating there. After the culture in vitro for 5 days, the smooth muscle cells covered all the surface of the scaffold, showing a singlelayer cellular structure. The cell counts at 3, 5 and 7 days in the experimental group were(16.85±0.79)×105,(39.74±2.16)×105 and (37.15±2.02)×105, respectively. Thecell counts in the control group were(19.43±0.54)×105,(34.50±1.85)×105 and (33.07±1.31)×105, respectively. There was a significant difference between the two groups at 5 days (P<0.05). ConclusionWith the enzyme treatment method, the primarily cultured canine bladder smooth muscle cells can produce a great amount of good and active cells in vitro. The acellular SIS can offer an excellent bio scaffold to support the bladder smooth muscle cells to adhere and grow, which has provided the technical foundation for a further experiment on the tissue engineered bladder reconstruction.
Objective To study the differenation of adult marrow mesenchymal stem cells(MSCs) into vascular endothelial cells in vitro and to explore inducing conditions. Methods MSCs were isolated from adult marrow mononuclear cells by attaching growth. MSCs were divided into 4 groups to induce: the cells seeded at a density of 5×103/cm2 in 2% and 15% FCS LDMEM respectively (group1 and group 2), at a density of 5×104/cm2 in 2% and 15% FCS LDMEM respectively (group 3 and group 4); vascular endothelial growth factor(VEGF) supplemented with Bovine pituitary extract was used to induce the cell differentiation. The differentiated cells were identified by measuring surfacemarks (CD34, VEGFR2, CD31 and vWF ) on the 14th day and 21st day and performed angiogenesis in vitroon the 21st day.The cell proliferation index(PI)of different inducing conditions were measured. Results After induced in VEGF supplemented with Bovine pituitary extract, the cells of group 3 expressed the surface marks CD34, VEGFR-2, CD31 and vWF on the 14th day, the positive rates were 8.5%, 12.0%, 40.0% and 30.0% respectively, and on the 21st day the positive ratesof CD34 and VEGFR2 increased to 15.5% and 20.0%, while the other groups did not express these marks; the induced cells of group 3 showed low proliferating state(PI was 10.4%) and formed capillary-like structure in semisolid medium. Conclusion Adult MSCs can differentiate into vascular endothelial cellsafter induced by VEGF and Bovine pituitary extract at high cell densities and low proliferatingconditions,suggesting that adult MSCs will be ideal seed cells forthe therapeutic neovascularization and tissue engineering.
目的 研究胃癌细胞SGC-7901培养上清液及转化生长因子-β1(TGF-β1)是否可促进人类腹膜间皮细胞表达βig-h3蛋白。方法 培养胃癌细胞SGC-7901,取第3天培养液上清与DMEM培养液的混合液 (1∶4)以及0、1.0、10.0和50.0ng/ml的 TGF-β1分别刺激人类腹膜间皮细胞HMrSV50、3、6、12及24h,ELISA方法检测上清液中βig-h3蛋白浓度,Western blot法检测细胞内βig-h3蛋白浓度。结果 对照组有基础量的βig-h3蛋白表达; 胃癌细胞SGC-7901培养上清液及TGF-β1均可明显增加HMrSV5细胞上清液及细胞内的βig-h3蛋白浓度(P<0.05),且TGF-β1的刺激作用呈时间及浓度依赖性。结论 胃癌细胞SGC-7901培养上清液及TGF-β1可明显刺激HMrSV5细胞表达和分泌βig-h3蛋白。
Three-dimensional (3D) cell culture model is a system that co-culture carriers with 3D structural materials and different types of cells in vitro to simulate the microenvironment in vivo. This novel cell culture model has been proved to be close to the natural system in vivo. In the process of cell attachment, migration, mitosis and apoptosis, it could produce biological reactions different from that of monolayer cell culture. Therefore, it can be used as an ideal model to evaluate the dynamic pharmacological effects of active substances and the metastasis process of cancer cells. This paper compared and analyzed the different characteristics of cell growth and development under two-dimensional (2D) and 3D model culture and introduced the establishment method of 3D cell model. The application progress of 3D cell culture technology in tumor model and intestinal absorption model was summarized. Finally, the application prospect of 3D cell model in the evaluation and screening of active substance was revealed. This review is expected to provide reference for the development and application of new 3D cell culture models.
Following the peritendon was removed by means of microsurgical technique, the tenocyte was isolated from the human embryonic tendons by digesting it with trypsin and collagenase. These cells were all stored in frozen condition until they were cultured by F12 culture fluid added with 20% FBS to the 15th generation.These cells were able to grow adhering to the wall and stop growing with contact inhibition. The time of cellsgroup duplication was 4 days, which was similar to the peak time of its mitosis. The number of its chromosome group 2n=46 was 87.5-91.0%. The optimal conditions for tendon cell culture in vitro were investigated, and it was found that after they were reaminated and subcultured the frozen storage didn’t influence their growth, morphology, genetic characteristics. In our research we detected the content generation cells and found the cultured human embryonic tenocyte had same ability never changed with the cells subcultured. We also disscussed the future of tenocyte-a biomaterial in the field of artificial implant.