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find Author "YANG Shuifa" 2 results
  • Effects of adipose-derived stem cell released exosomes on proliferation, migration, and tube-like differentiation of human umbilical vein endothelial cells

    Objective To explore the effects of adipose-derived stem cell released exosomes (ADSC-Exos) on the proliferation, migration, and tube-like differentiation of human umbilical vein endothelial cells (HUVECs). Methods Adipose tissue voluntarily donated by liposuction patients was obtained. The ADSCs were harvested by enzyme digestion and identified by flow cytometry and adipogenic induction. The ADSC-Exos were extracted from the supernatant of the 3rd generation ADSCs and the morphology was observed by transmission electron microscopy. The surface proteins (Alix and CD63) were detected by Western blot. The nanoparticle tracking analyzer NanoSight was used to analyze the size distribution of ADSC-Exos. After co-culture of PKH26 fluorescently labeled ADSC-Exos with HUVECs, confocal microscopy had been used to observe whether ADSC-Exos could absorbed by HUVECs. ADSC-Exos and HUVECs were co-cultured for 1, 2, 3, 4, and 5 days. The effect of ADSC-Exos on the proliferation of HUVECs was detected by cell counting kit 8 (CCK-8) assay. The expression of VEGF protein in the supernatant of HUVECs with or without ADSC-Exos had been detected by ELISA after 12 hours. Transwell migration assay was used to detect the effect of ADSC-Exos on the migration ability of HUVECs. The effect of ADSC-Exos on the tubular structure formation of HUVECs was observed by Matrigel experiments in vitro. The formation of subcutaneous tubular structure in vivo was observed in BALB/c male nude mice via the injection of HUVECs and Matrigel with or without ADSC-Exos. After 2 weeks, the neovascularization in Matrigel was measured and mean blood vessel density (MVD) was calculated. The above experiments were all controlled by the same amount of PBS. Results After identification, the cultured cells were consistent with the characteristics of ADSCs. ADSC-Exos were circular or elliptical membranous vesicle with uniform morphology under transmission electron microscopy, and expresses the signature proteins Alix and CD63 with particle size ranging from 30 to 200 nm. Confocal microscopy results showed that ADSC-Exos could be absorbed by HUVECs. The CCK-8 analysis showed that the cell proliferation of the experimental group was better than that of the control group at each time point (P<0.05). The result of Transwell showed that the trans-membrane migration cells in the experimental group were significantly more than that in the control group (t=9.534, P=0.000). In vitro, Matrigel tube-forming experiment showed that the number of tube-like structures in the experimental group was significantly higher than that of the control group (t=15.910, P=0.000). In vivo, the MVD of the experimental group was significantly higher than that of the control group (t=16.710, P=0.000). The ELISA assay showed that the expression of VEGF protein in the supernatant of the experimental group was significantly higher than that of the control group (t=21.470, P=0.000). Conclusion ADSC-Exos can promote proliferation, migration, and tube-like structure formation of HUVECs, suggesting that ADSC-Exos can promote angiogenesisin vitro and in vivo.

    Release date:2018-10-09 10:34 Export PDF Favorites Scan
  • Construction of injectable tissue engineered adipose tissue with fibrin glue scaffold and human adipose-derived stem cells transfected by lentivirus vector expressing hepatocyte growth factor

    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.

    Release date:2017-09-07 10:34 Export PDF Favorites Scan
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