Objective To observe the biological characters of chondrocytes in articular loose body and to find out seeding cells for cartilage tissue engineering. Methods Samples from 5 loose body cartilages, 2 normal articular cartilages and 6 osteoarthritis articular cartilages were collected. Part of each sample’s cartilage was histologically studied to observe the chondrocytes distribution the morphologic changes by toluidine-blue staining, chondrocytes’ apoptosis by terminal deoxynucleotidyl transferase mediated deoxyuridine triphosphate-biotin nick end-labeling (TUNEL). The rest of each cartilage was digested and isolated by 0.25% trypsin and 0.2% collagenase Ⅱ, and then were cultivated in 10%DMEM. Their morphologic changes were observed 24h later.Comparison was made btween three cartilages. Results Compared with normal cartilage and osteoarthritis articular cartilage, the cells density was higher, their lacunars were larger, cells distribution was irregular, and apoptosis was more apparent in loose body cartilage. Conclusion The characters of chondrocytes from loose body is more like fibroblasts so they can not serve as seeding cells directly for cartilage tissue engineering.
Objective To investigate an important role of the stem cells in reconstructing the tissues and organs. Methods Based on our own researches and combined with the review of the literature at home andabroad, the latest development of the cell therapy with the stem cells and the application of the seed cells in the tissue engineering were analyzed. Results As the stem cells are the origin of the human tissues and organs and have a higher self-renewal ability and extensive characteristics of proliferation in vitro, their imbedding and multi-differential potentialities were illustrated. Both the embryonic stem cells and the adult stem cells had a wide prospect as ideal seed cells for reparation and reconstruction of the impaired human tissues and organs. Conclusion The stem cells can play animportant role in repairing and reconstructing the injured tissues and organs and they have a promising prospect in clinical application. The further research and wide application of the stems cells will significantly improve the therapeutic effects on the injured tissues and organs.
Objective To study the effect of hypoxia on the prol iferation of hBMSCs and human placental decidua basal is-MSCs (hPDB-MSCs), and to provide the theoretical basis for discovering the new seed cells source for tissue engineering. Methods Density gradient centrifugation method was adopted to isolate and culture hBMSCs and hPDB-MSCs,flow cytometry (FCM) was appl ied to detect cell surface marker. After establ ishing the experimental model of CoC12 chemical hypoxia, MTT method was appl ied to evaluate the prol iferation of hBMSCs and hPDB-MSCs at different time points (6, 12, 24, 48, 72, 96 hours) with various CoC12 concentration (0, 50, 75, 100, 125, 150, 175, 200 μmol/L). Results FCM analysis revealed that hPDB-MSCs and hBMSCs expressed CD9, CD29, CD44, CD105, CD106 and human leucocyte antigen ABC (HLA-ABC), but both were absent for CD34, CD40L and HLA-DR. Compared with hBMSCs, hPDB-MSCs expressed stage-specific embryonic antigen 1 (SSEA-1), SSEA-3, SSEA-4, TRA-1-60 and TRA-1-81 better. The prol iferations of hPDB-MSCs and hBMSCs were inhibited within the first 12 hours under hypoxia condition, but promoted after 12 hours of hypoxia. Compared with the control group, the hBMSCs were remarkably prol iferated 24 hours after hypoxia with CoC12 concentration of 150 µmol/L (P lt; 0.05), while hPDB-MSCs were significantly prol iferated 12 hours after hypoxia with CoC12 concentration of 75 µmol/L (P lt; 0.05). Conclusion Compared with hBMSCs, hPDB-MSCs express more specific surface antigens of embryonic stem cells and are more sensitive to the prol iferation effects of chemical hypoxia, indicating it may be a new seed cells source for tissue engineering.
Objective To elucidate the latest research progress and application of tissue engineered meniscus. Methods The literature concerning the advance in tissue engineered meniscus was extensively reviewed, then closely-related issues including seed cells, scaffolds, and bioreactors were analyzed. Results With more and more attention being paid to meniscus tissue engineering, different approaches and strategies for seed cells, scaffolds, and bioreactors have contributed to the generation of meniscal constructs, which are capable of restoring meniscal lesions to some extent, but translating successes in basic science research to clinical application is still limited. Conclusion More research for the optimal combination of the appropriate cell source, the scaffold type, and the proper physical and chemical factors for the stimulation of cells differentiation into tissue with optimal phenotypes in tissue engineered meniscus is still in needed, but the overall future looks promising.
ObjectiveTo review the research progress of the tissue engineering technique in the esophageal defect repair and reconstruction. MethodsThe recently published clinical and experimental literature at home and abroad on the scaffold materials and the seeding cells used in the tissue engineered esophageal reconstruction was consulted and summarized. ResultsA large number of basic researches and clinical applications show that the effect of the tissue engineered esophagus is close to the autologous structure and function of the esophagus and it could be used for the repair of the esophageal defect. However, those techniques have a long distance from the clinical application and need an acknowledged rule of technology. ConclusionTissue engineering technique could provide an innovative theory for the esophageal defect reconstruction, but its clinical application need further research.
Objective To review the latest progress of seeding cells for articular cartilage tissue engineering. Methods The recent original l iteratures on seeding cells for articular cartilage tissue engineering were extensively reviewed. Results The chondrocytes derived from BMSCs’ differentiation would be a main source of seeding cells articular cartilage for tissue engineering. Three-dimensional scaffolds and cultivation surroundings played important roles in the field of articular cartilage tissue engineering. Conclusion The util ization of cytokine and transgenic technology as well as improvements of three-dimensional scaffolds and cultivation surroundings will promote the development of articular cartilage tissue engineering.
Objective To sum up the research advances of the seed cell and the culture system using in tissue engineering cartilage. Methods The recent original articles about the seed cell and the culture system in tissue engineering cartilage were extensively reviewed. Results At present, autologous or homologous cells is still major seed cell and the three dimensional culture system is also major system for tissue engineering cartilage. Conclusion The source of seed cell for tissue engineering cartilage. Conclusion The source of seed cell for tissue engineering cartilage should be further explored, and the culture system need to be improved and developed.
Objective To investigate the research development of the liver stem cell(LSC) and to predict its future application. Methods Based on our own researches and combined with the review of the related literature at home and abroad, we analyzed and evaluated the latest development of the research on the LSC. Results We knew the differentiation and proliferation of the LSC towards some kinds of specified cells were affected by many factors; and the researches on the LSC in regard to its activation, isolating culture, bolting, and evaluation still needed further improvements. Conclusion With the development of the research, the liver stem cell can become a new seed cell to cure some liver diseases.
Objective To introduce the cells and cell-transplantation methods for periodontal tissue engineering. Methods Recent l iterature about appl ication of cell-based therapy in periodontal tissue engineering was extensively reviewed, the cells and cell-transplantation methods were investigated. Results Mesenchymal stem cells were important cell resourcesfor periodontal tissue engineering, among which peridontal l igament stem cells were preferred. Bone marrow mesenchymal stem cells had several disadvantages in cl inical appl ication, and adipose-derived stem cells might be a promising alternative; different transplantation methods could all promote periodontal regeneration to some extent. Single-cell suspension injection could only promote a l ittle gingival regeneration, and tissue engineered scaffolds still needed some improvement to be used in periodontal regeneration, while cell sheet technique, with great cell loading abil ity and no need of scaffolds, could promote regeneration of cementum, periodontal l igament, and alveolar bone under different conditions. Conclusion Multipotent stem cells are fit to be used in periodontal tissue engineering; improvement of cell-transplantation methods will further promote periodontal regeneration.
ObjectiveTo summarize the research progress of tissue-engineered bile duct in recent years. MethodsThe related literatures about the tissue-engineered bile duct were reviewed. ResultsIn recent years, the research of tissue-engineered bile duct has made a breakthrough in scaffold materials, seed cells, growth factors etc. However, the tissue-engineered bile duct is still in the research stage of animal experiments, which can not be directly applied to clinical practice. ConclusionsThe research of tissue-engineered bile duct becomes popular at present. With the rapid development of materials science and cell biology, the basic research and clinical application of tissue-engineered duct will be more in-depth research and extension, which might bring new ideas and therapeutic measures for patients with biliary defect or stenosis.