ObjectiveTo review the research progress of constructing injectable tissue engineered adipose tissue by adipose-derived stem cells (ADSCs). MethodsRecent literature about ADSCs composite three-dimensional scaffold to construct injectable tissue engineered adipose tissue is summarized, mainly on the characteristics of ADSCs, innovation of injectable scaffold, and methods to promote blood supply. ResultsADSCs have a sufficient amount and powerful ability such as secretion, excellent compatibility with injectable scaffold, plus with methods of promoting blood supply, which can build forms of injectable tissue engineered adipose tissue. ConclusionIn despite of many problems to be dealt with, ADSCs constructing injectable tissue engineered adipose tissue may provide a promising source for soft-tissue defect repair and plastic surgery.
Objective To construct the lentiviral vector to co-express enhanced green fluorescent protein (EGFP) gene and human insul in (insulin) gene, and to explore the condition to transfect human umbil ical cord mesenchymal stem cells (hUCMSCs) so as to lay a foundation for tissue engineered adipose reconstruction and transplantation in vivo infuture. Methods The insulin gene was cloned to lentiviral expression vector with EGFP [pLenti6.3-internal ribosome entrysite (IRES)-EGFP] by recombinant DNA technology, the positive clones were screened, and lentiviral packaged systems and target gene plasmid were co-transfected to package virus in 293T cells by lipofectin. The reporter gene expression was observed by fluorescent inverted phase contrast microscope, virus supernatant was collected, purificated and concentrated, and the titer of recombinant viruses was determinated. hUCMSCs from umbilical cord tissue of mature neonates were isolated and cultured by different multiple of infection (MOI, 0, 1, 3, 5, 7, 10, 15, and 20). By recombinant lentiviral infected hUCMSCs with reporter gene green fluorescent protein expression, the best MOI was screened; recombinant lentiviral infected hUCMSCs at the best MOI, then real-time PCR and Western blot methods were appl ied to detect insulin gene and insul in protein expression levels in cells. Results The recombinant lentiviral vector of co-expressing insulin gene and EGFP gene (pLenti6.3-insulin-IRESEGFP) was successfully constructed. Virus could be packaged, purificated and concentrated successfully. The virus titer was 1.3 × 108 TU/mL. The best MOI was 10 and the transfer efficiency was up to 90% in the same time. Real-time PCR results showed that insulin gene expression of transfected group was positive and non-transfected group was negative; Western blot detection confirmed that insul in protein expression of transfected group was positive in cells and supernatant, but that of non-transfected group was both negative. Conclusion Lentiviral vector pLenti6.3-insulin-IRES-EGFP carrying recombinant insulin gene could effectively transfect hUCMSCs and express insul in protein.
ObjectiveTo discuss the possibility of constructing injectable tissue engineered adipose tissue, and to provide a new approach for repairing soft tissue defects.MethodsHuman adipose-derived stem cells (hADSCs) were extracted from the lipid part of human liposuction aspirate by enzymatic digestion and identified by morphological observation, flow cytometry, and adipogenic induction. The hADSCs underwent transfection by lentivirus vector expressing hepatocyte growth factor and green fluorescent protein (HGF-GFP-LVs) of different multiplicity of infection (MOI, 10, 30, 50, and 100), the transfection efficiency was calculated to determine the optimum MOI. The hADSCs transfected by HGF-GFP-LVs of optimal MOI and being adipogenic inducted were combined with injectable fibrin glue scaffold, and were injected subcutaneously into the right side of the low back of 10 T-cell deficiency BALB/c female nude mice (transfected group); non-HGF-GFP-LVs transfected hADSCs (being adipogenic inducted) combined with injectable fibrin glue scaffold were injected subcutaneously into the left side of the low back (untransfected group); and injectable fibrin glue scaffold were injected subcutaneously into the middle part of the neck (blank control group); 0.4 mL at each point. Twelve weeks later the mice were killed and the implants were taken out. Gross observation, wet weight measurement, HE staining, GFP fluorescence labeling, and immunofluorescence staining were performed to assess the in vivo adipogenic ability of the seed cells and the neovascularization of the grafts.ResultsThe cultured cells were identified as hADSCs. Poor transfection efficiency was observed in MOI of 10 and 30, the transfection efficiency of MOI of 50 and 100 was more than 80%, so the optimum MOI was 50. Adipose tissue-like new-born tissues were found in the injection sites of the transfected and untransfected groups after 12 weeks of injection, and no new-born tissues was found in the blank control group. The wet-weight of new-born tissue in the transfected group [(32.30±4.06) mg] was significantly heavier than that of the untransfected group [(25.27±3.94) mg] (t=3.929, P=0.001). The mature adipose cells in the transfected group [(126.93±5.36) cells/field] were significantly more than that in the untransfected group [(71.36±4.52) cells/field] (t=30.700, P=0.000). Under fluorescence microscopy, some of the single cell adipocytes showed a network of green fluorescence, indicating the presence of GFP labeled exogenous hADSCs in the tissue. The vascular density of new-born tissue of the transfected group [(16.37±2.76)/field] was significantly higher than that of the untransfected group [(9.13±1.68)/field] (t=8.678, P=0.000).ConclusionThe hADSCs extracted from the lipid part after liposuction can be used as seed cells. After HGF-GFP-LVs transfection and adipose induction, the hADSCs combined with injectable fibrin glue scaffold can construct mature adipose tissue in vivo, which may stimulate angiogenesis, and improve retention rate of new-born tissue.