Objective To review the research status of the neovascularization of adi pose tissue engineering in the past decade so as to provide theoretical references for the development of the rapid revascularization of tissue engineered adi pose. Methods The l iterature about the revascularization of adi pose tissue engineering was extensively reviewed andanalyzed, centering on 5 elements: specificity of histological structures and blood supply, revascularization mechanism, coculture of different seed cells, modification of scaffold, and microenvironment. Results Adi pose tissue engineering offers a new solution for soft tissue defects. However, there is still the unfulfilled need in the size of engineered adipose tissue (less than 1 mL), which was determined by the degree of neovascularization in engineered tissue. Overall, rapid neovascularization in engineering tissue is a key l ink of experimental study changing into cl inical appl ication. Conclusion Providing a sufficient supply with nutrients and oxygen by means of a sufficient and rapid neovascularization will be at the heart of any attempts to obtain bigger tissue engineered adipose to meet the demand of repairing large soft tissue defect.
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.
ObjectiveTo review the research progress of the role of seed cells and related cytokines in angiogenesis of the vascularized tissue engineered bone. MethodsThe latest literature of tissue engineered bone angiogenesis was reviewed, including the common source of seed cells, biological characteristics, transformation mechanism, related cytokines, and signaling pathways in re-vascularization. ResultsMicrosurgery technique, genetic technique, and co-culture system of vascularized tissue engineered bone have developed to a new level. Moreover, both the induction of introduced pluripotent stem cells and vascular endothelial growth factor-angiopoietins 1 transfected mesenchymal stem cells and endothelial progenitor cells have some advantages for bone regeneration and vascularization. However, all the techniques were not used in clinical practice. ConclusionUsing techniques of genetically modified seed cells, related cytokines, and scaffolds may have bright prospects for building vascularized tissue engineered bone.
ObjectiveTo study the potential protective effects of bone marrow mesenchymal stem cells (BMSCs) on chondrocytes injured by interleukin 1β (IL-1β), and the resistant capacity of chondrocytes when co-cultured indirectly with BMSCs against IL-1β. MethodsSix Sprague Dawley (SD) rats were randomly divided into experimental group (articular cartilage defects) and control group. The content and gene expression of IL-1β were detected at 6 hours after surgical intervention by quantitative real time RCR (qRT-PCR) and ELISA. BMSCs repairing function test: the 18-holes cultured chondrocytes were randomly divided into 3 groups (n=6): cells of blank group were not treated;cells of injured group and co-cultured group were intervened by IL-1β, and Transwell chamber was used to establish co-culture system of BMSCs with chondrocyte in co-cultured group. The mRNA relative expressions of cysteinyl aspartate specific proteinase 3 (Caspase 3), a disintegrin and metalloprotease with Thrombospondin motifs 4 (ADAMTS-4), and ADAMTS-5 were measured via qRT-PCR in chondrocytes, meanwhile Caspase-3 content was detected via ELISA, and the cell apoptosis rate was detected via flow cytometry. BMSCs protecting function test: the 12-holes cultured chondrocytes were randomly divided into 2 groups (n=6), Transwell chamber was used to establish co-culture system of BMSCs with chondrocyte in co-cultured group before the 2 groups were both intervened by IL-1β, then the same detected indexes were taken as the BMSCs repairing function test. ResultsAnimal in vivo studies showed that relative expression of IL-1β mRNA and IL-1β contents were significantly higher in experimental group than control group (P<0.05). BMSCs repair tests showed that mRNA relative expressions of Caspase-3, ADAMTS-4, and ADAMTS-5, Caspase-3 content, and cell apoptosis rate were significantly higher in injured group and co-cultured group than blank group, and in injured group than co-cultured group (P<0.05). BMSCs protect tests showed that mRNA relative expressions of Caspase-3, ADAMTS-4, and ADAMTS-5, Caspase-3 content, and cell apoptosis rate in co-cultured group were significantly lower than those in control group (P<0.05). ConclusionBMSCs, as seed cells for tissue engineering, have potential for applications to anti-inflammation and anti-apoptosis.