OBJECTIVE: From the point of view of material science, the methods of tissue repair and defect reconstruct were discussed, including mesenchymal stem cells (MSCs), growth factors, gene therapy and tissue engineered tissue. METHODS: The advances in tissue engineering technologies were introduced based on the recent literature. RESULTS: Tissue engineering should solve the design and preparation of molecular scaffold, tissue vascularization and dynamic culture of cell on the scaffolds in vitro. CONCLUSION: Biomaterials play an important role in the tissue engineering. They can be used as the matrices of MSCs, the delivery carrier of growth factor, the culture scaffold of cell in bioreactors and delivery carrier of gene encoding growth factors.
Objective To study the culture and purification of the fetal mouse liver mesenchymal stem cells(MSCs) in vitro and to investigate their differentiation potential and the composite ability with true bone ceramic(TBC). Methods The single cell suspension of MSCs was primarily cultured and passaged, which was prepared from the fetal mouse liver; the flow cytometry was applied to detectCD29, CD34, CD44 and CD45. The osteogenic differentiation was induced in chemical inducing system; the osteogenic induction potency was tested. The purified fetal mouse liver MSCs were compounded with TBC covered with collagen type Ⅰ in vitro and the cell attachment and proliferation to the TBC were observed. Results The primary MSCs of fetal mouse liver were easy to culture in vitro. They proliferated well and were easy to subcultured. The proliferation ability of primary and passaged MSCs was similar. Flow cytometric analysis showed the positive results for CD29, CD44 and the negative results for CD34, CD45. After 7 days of induction, the MSCs expressed collagen type I and alkaline phosphatase(ALP) highly. After 14 days of induction, the fixed quantity of ALP increased significantly. After 28 days of induction, calcium accumulation was observed by Von Kossa’s staining. Many liver MSCs attached to the surface of TBC. Conclusion The MSCs of the fetalmouse liver can be obtained, subcultured and purified easily. After culturing in chemical inducing system, the MSCs of fetal mouse liver can be successfully induced to osteoblast-like cells, attach to the surface of TBC and proliferate well.
Objective To fabricate a novel gelatinchondroitin sulfate-sodium hyaluronate tri-copolymer scaffold and to confirm the feasibility of serving as ascaffold for cartilage tissue engineering. Methods Different scaffolds was prepared with gelatin-chondroitin sulfatesodium hyaluronate tri-copolymer by varying the freezing temperatures (-20℃,-80℃ and liquid nitrogen). Pore size, porosity, inter pores and density were observed with light microscopy and scanning electron microscopy (SEM). The load-stiffness curves were compared between different scaffolds and normal cartilage. The number of MSCs attaching to different scaffolds and the function of cells were also detected with MTT colorimetric microassay. Results The pore size was 300±45, 230±30 and 45±10 μm; the porosity was 81%, 79% and 56%; the density was 9.41±0.25, 11.50±0.36 and 29.50±0.61 μg/mm3 respectively in different scaffolds fabricated at -20℃,-80℃ and liquid nitrogen; the latter two scaffolds had nearly the same mechanical property with normal cartilage; the cell adhesion rates were 85.0%, 87.5% and 56.3% respectively in different scaffolds and the scaffolds can mildly promote the proliferation of MSCs. Conclusion Gelatin-chondroitin sulfatesodium hyaluronate tricopolymer scaffold fabricated at -80℃ had proper pore size, porosity and mechanical property. It is a novel potential scaffold for cartilage tissue engineering.
Objective To explore the in vitrodifferentiation of the rat mesenchymal stem cells (MSCs ) into the skeletal muscle cells induced by the myoblast differentiation factor (MyoD) and 5-azacytidine. Methods The MSCs were taken from the rat bone marrow and the suspension of MSCs was made and cultured in the homeothermia incubator which contained 5% CO2at 37℃. The cells were observed under the inverted phase contrast microscope daily. The cells spreading all the bottom of the culture bottle were defined as onepassage. The differentiation of the 3rd passage of MSCs was induced by the combination of 5-azacytidine, MyoD, transforming growth factor β1, and the insulin like growth factor 1. Nine days after the induction, the induced MSCs were collected, which were analyzed with the MTT chromatometry, theflow cytometry, and the immunohistochemistry. Results The primarily cultured MSCs grew as a colony on the walls of the culture bottle; after the culture for 5-7 days, the cells were shaped like the fibroblasts, the big flat polygonal cells, the medium sized polygonal cells, and the small triangle cells; after the culture for 12 days, the cells were found to be fused, spreadingall over the bottle bottom, but MSCs were unchanged too much in shape. After the induction by 5-azacytidine, some of the cells died, and the cells grew slowly. However, after the culture for 7 days, the cells grew remarkably, the cell volume increased gradually in a form of ellipse, fusiform or irregularity. After theculture for 14 days, the proliferated fusiform cells began to increase in a great amount. After the culture for 18-22 days, the myotubes increased in number and volume, with the nucleus increased in number, and the newly formed myotubes and the fusiform myoblst grew parallelly and separately. The immunohistochemistry for MSCs revealed that CD44 was positive in reaction, with the cytoplasm ina form of brown granules. And the nucleus had an obvious border,and CD34 was negative. The induced MSCs were found to be positive for desmin and specific myoglobulin of the skeletal muscle. The flow cytometry showed that most of the MSCs and the induced MSCs were in the stages of G0/G1,accounting for 79.4% and 62.9%,respectively; however, the cells in the stages of G2/S accounted for 20.6% and 36.1%. The growth curve was drawn based on MTT,which showed that MSCs weregreater in the growth speed than the induced MSCs. The two kinds of cells did not reach the platform stage,having a tendency to continuously proliferate.ConclusionIn vitro,the rat MSCs can be differentiated into the skeletal muscle cells with an induction by MyoD and 5-azacytidine, with a positive reaction for the desmin and the myoglobulin of the skeletal muscle. After the induction, the proliferation stage of MSCs can be increased, with a higher degree of the differentiation into the skeletal muscle.
ObjectiveTo comprehensively analyze the recent advancements in the field of mesenchymal stem cells (MSCs) aging,and summary its achievements and its difficulty at the present. MethodsThe literature about MSCs aging was reviewed and analyzed. ResultsInducible telomerase reactivation of MSCs is successful to extend the life span of senescent cells,but it also has potential safety hazard.The age range presented in the research of age-related cell senescence is inconsistent,resulting in different outcomes.Many ways to improve cell in vitro culture conditions will help delay aging.Recent research indicates that oxidative stress theory is seemed to not completely explain cell aging. ConclusionFurther research of MSCs aging mechanism will help the tissue engineering transform to clinical application.
Objective To investigate the effects of the recombinanthuman bone morphogenetic protein 2 (rhBMP-2) and/or the osteogenic agents on proliferation and expression of the osteoblast phenotype differentiation of the SD rat mesenchymal stem cells(MSCs). Methods The rat MSCs were cultured in vitro and were randomly divided into the experimental groups(Groups A-I) and the control group. In the experimental group, MSCs were induced by rhBMP2 in different doses (10, 50, 100 and 200 μg/L) in Groups BE, the osteogenic agent alone (Group A) and by the combined use of rhBMP-2 [in different doses (10,50, 100 and 200 μg/L)] and the osteogenic agent in Groups F-I. The MTT colorimetric assay was used to evaluate the proliferation, and the activities of alkaline phosphatase (ALP) and osteocalcin (OC) were observed at 3, 6, 9, 12 days, respectively. Results The inverted phase contrast microscopy showed that MSCs by primary culture for 12 hours were adhibited, with a fusiform shape at 48 hours. At 4 days they were polygonal or atractoid, and were spread gyrately or radiately at 6 days. At 10 days, they were spread at the bottom of the bottle.The statistical analysis showed that the expression of the osteoblast phenotype differentiation of MSCs could be induced in the experimental groups. The proliferation of MSCs could be enhanced in a dosedependent manner in GroupsB-E. The expression of the osteoblast phenotype differentiation, which was tested by the activities of ALP and OC, was significantly higher in Groups F-I than in Groups A-E. Conclusion The combined use of rhBMP-2 and the osteogenic agents can enhance the MSC proliferation and induce an expressionand maintenance of the osteoblast phenotype differentiation of the rat MSCs.
Objective To explore an experimental method of transfecting the marrow stromal stem cells (MSCs) with the reconstructed PGL3-t ransforming growth factor-β1 (TGF-β1) gene and to evaluate the feasibility of selfinduction of MSCs to the chondrocytes in vitro so as to provide a scientific and experimental basis for a further “gene enhanced tissue engineering” research. Methods The rabbit MSCs was transfected with the reconstructed PGL3-TGF-β1gene by the Liposo mesMethod, the growth of the cells were observed, and the growth curve was drawn. The living activity of the transfected cells in the experimental group was evalua ted by MTT, and the result was significantly different when compared with that in the control group. By the immunohistochemistry method (SABC), the antigens of TGF-β1 and collagen Ⅱ were examined at 2 and 7 days of the cell culture afte r transfe ction with PGL3-TGF-β1gene. The pictures of the immunohistochemistry slice were analyzed with the analysis instrument, and the statistical analysis was perfor med with the software of the SPSS 11.0, compared with the control group and the blank group. Results Transfection of the cultured rabbit MSCs in vitro with the reconstructed PGL3-TGF-β1gene by the Liposomes Method achie ved a success, with a detection of the Luceraferase activity. The result was significantly different from that in the control group (Plt;0.01). Tested by MTT, the living acti vity of the transfected cells was proved to be significantly decreased (Plt;0.01 vs. the control group). By the immunohistochemistry method (SABC) to study TGF-β1 positive particles were detected in the experimental group,but there were no positive particles in the control and the blank groups. There was a significant difference between the two groups of the experiment and the control group based on the analysis of the ttest (Plt;0.01). By the immunohistochemistry me thod (SABC) to study collagen Ⅱ, there were more positive particles in the transfected cells in t he experimental group than in the control and the blank groups, and there was a significant difference between the experimental group and the two other groups based on the t-test (Plt;0.01). Conclusion Transfection of the rabbit MSCs with the reconstructed PGL3-TGF-β1 gene by the Liposomes Method is successful. There may be some damage to the cells when transfection is performed. The transfecte d BMS cells with PGL3-TGF-β1 gene can express and excrete TGF-β1when cultured in vitro. The transfected MSCs that secret TGF-β1 can be self-induced into the chondrocytes after being infected for 7 days when cultured in vitro.
Mesenchymal stem cells (MSCs) are considered as an ideal treatment for multiple diseases including ocular disease. Recent studies have demonstrated that MSCs-derived exosomes have similar functions with MSCs. Exosomes are nanovesicles surrounded by a phospholipid layer that shuttle active cargo between different cells. They are capable of passing the biological barrier and have potentials to be utilized as natural carrier for the ocular drug delivery.
Objective To observe the therapeutic effect of mensenchymal stem cells (MSCs) for experimental autoimmune uveitis (EAU). Methods MSCs were obtained from Wistar rats and selected by plastic adherence. Lewis rats were divided into treatment group and control group, six rats in each group. EAU models were induced by immunization with an emulsion (0.2 ml) containing 30 mu;g interphotoreceptor retinoid-binding protein derived peptide R16 and complete Freundprime;s adjuvant. The clinical manifestations of two groups were observed. Nine to 11 day after modeling, 1 ml MSCs suspension, which contained 5times;106 MSCs, were injected into the rats in treatment group via tail vein, and the rats in control group were given equal volume of phosphate buffer solution. Fifteen day after modeling, the eyes were collected to test the proportion of interferon gamma;, interleukin-17 and Foxp3 positive cells by flow cytometry. The clinical scores were analyzed by mixed linear model and statistical analysis of variance of repeated measurement data. The results of flow cytometry were analyzed using independent-sample t test. Results Six days after immunization, mild dilatation and congestion of iris vascular was observed. Nine days after immunization, mild muddy anterior chamber, myosis and absent pupillary reaction to light were observed. Twelve days after immunization, muddy anterior chamber, occlusion of pupil and dimmed or disappeared red reflex were observed, and then inflammation was slowly reduced. From 11 to 15 days after immunization, the clinical score of treatment group was lower than that in control group, the difference was statistically significant (t=2.42, 2.21, 4.16, 5.24, 4.03; P<0.05). The results of flow cytometry showed that MSCs treatment could decrease the proportion of CD4+T cells, Th1 cells and Th17 cells, increase the proportion of Treg cells. Conclusion MSCs treatment can ameliorate EAU, up-regulate the expression of Treg cells and down-regulate the expression of CD4+T cells, Th1 cells and Th17 cells.
Objective To observe the tissue engineered bonefabricated with the cultured mesenchymal stem cells (MSCs) by the green fluorescent protein (GFP) gene transfer. Methods The recombinant Adeno-XTM-GFP expression vector was purified after being packed and proliferated by the HEK293 cells, and then it was used to infect the rabbit’s MSCs directly afer the virus titer was assayed. The cell morphological changes were observed under the inverted phase contrast microscope, and the expression of GFP was observed under the fluorescence microscope to confirm success of the labeling of MSCs.The GPFlabeled MSCs and the pure MSCs were cultured together in the conventional osteogenic supplements for 3 weeks, and then they were seeded onto the compound scaffold of the calcium phosphate cement (CPC) and the fibrin glue (FG) to form a new kind of the tissue engineered bone. It was implanted into the donator rabbit subcutaneously to be used as the experimental group; in contrast, the pure compound scaffold of the CPC-FG without any MSCs was implanted in the same rabbit as a control. The alkline phosphatase (ALP) activity assay was performed respectively at 1, 2 and 3 weeks after operation. GFP was observed under the laserconfocal microscope at 4 weeks after operation, and the formed new bone was harvested at 4 weeks and evaluated by the Masson staining, the immunohistochemistry staining of osteocalcin (OC) and collagen typeⅠ.Results The virus titer was 3×108pfu/ml after proliferation and purification. Expresstionof GFP was confirmed 96 h after MSCs were infected by the Adeno-XTM-GFP expression vector and the infection rate was proximally 50%-70%. In contrast to MSCs, division and proliferation of the GPF-labeled MSCs were not significantly different. The ALP activity in the experimental group (12.546±1.091, 16.567±0.659, 20.443±0.706) was significantly higher than that in the control group (0.453±0.113, 0.243±0.018, 0.308±0.056), respectively at 1, 2 and 3 weeks after operation (Plt;0.05). The tissue engineered bone formed at 4 weeks. There were newly-formed trabeculae around the pore of the compound scaffold, and theimmunohistochemistry staining of OC and collagen typeⅠ were positive. The laser confocal microscope revealed that the GFP-labeled cells existed in many newlyformed tissues,and the compound scaffold of CPC-FG was partly degraded. Conclusion The engineered bone is similar to the spongy bone and the composed cells originate from the cultured MSCs, all of which can be confirmed by the GFP gene transfer technique.