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.
Objective To investigate the effects of adipose-derived stem cells (ADSCs) and endothelial cells (ECs) on the survival and neovascularization of fat tissue transplants. Methods The ADSCs were isolated by collagenase digestion from the adipose tissues voluntarily donated by the patients undergoing mastectomy, and subcultured. The passage 3 ADSCs were used for subsequent experiments. The residual fat tissues were used to prepare fat particles (FPs). The human umbilical vein endothelial cells (HUVECs) were used as ECs for subsequent experiments. Eighty healthy male nude mice, aged 4-6 weeks, were randomly divided into 4 groups (n=20). The mice were received subcutaneous injection at the dorsum of 1 mL FPs+0.3 mL normal saline (NS) in control group, 1 mL FPs+2×106 ECs+0.3 mL NS in ECs group, 1 mL FPs+2×106 ADSCs+0.3 mL NS in ADSCs group, and 1 mL FPs+1×106 ECs+1×106 ADSCs+0.3 NS in ADSCs+ECs group. General observations of the injection sites were performed, and the survival of the mice was recorded. At 2, 4, 8, and 12 weeks after injection, grafted fat tissues were firstly assessed by ultrasonography, then they were collected for volume measurement (water displacement method) and histology observation (HE staining and immunofluorescence staining). Results All mice survived until the end of experiment. At each time point, no significant difference was noted between groups in ultrasonography assay. There was no significant blood flow signal in the grafted fat tissues, or cysts, calcification, solid occupying in recipient area. Generally, the volume of grafted fat tissues decreased with time in all groups. Specifically, the volumes of grafted fat tissues were larger in ADSCs group and ADSCs+ECs group than that in control group and ECs group (P<0.05) at each time point, and in ADSCs group than in ADSCs+ECs group (P<0.05) at 8 and 12 weeks. HE staining showed that all groups had similar tendencies in general histology changes, and remodeling in ADSCs group was the fastest than in the other groups. By immunofluorescence staining for neovascularization, the new vessels in all groups were increasing with time. The vessel densities were higher in ECs group, ADSCs group, and ADSCs+ECs group than in control group (P<0.05) at each time point, in ADSCs group than in ECs group and ADSCs+ECs group (P<0.05) at 4 weeks, in ADSCs group and ADSCs+ECs group than in ECs group (P<0.05) at 8 and 12 weeks. Conclusion ADSCs can significantly increase the survival of transplanted fat tissue, which may be related to promoting the neovascularization.
ObjectiveTo investigate the effect of circulating estrogen level on the outcome of free fat grafting in nude mice.MethodsEighteen female nude mice aged 6-8 weeks (weighing, 20-25 g) were randomly divided into 3 groups (n=6). The nude mice in the ovariectomized group were treated with ovariectomy. The nude mice in the high estrogen group and the normal estrogen group only made the same incision to enter the peritoneum without ovariectomy. The nude mice in the high estrogen group were given the estradiol (0.2 mg/g) every 3 days for 30 days. The other two groups were given the same amount of PBS every 3 days. At 30 days after operation, the tail vein blood of nude mice in 3 groups were detected by estradiol ELISA kit, and the free fat (0.3 mL) donated by the females was injected into the sub-scalp of nude mice. After 8 weeks of fat grafting, the samples were taken for gross observation and weighing, and the prepared slices were stained with HE staining, CD31-perilipin fluorescence staining, immunohistochemical staining of uncoupling protein 1 (UCP1), and immunofluorescence staining of estrogen receptor α. The diameter of adipocytes and vascular density of adipose tissue were measured. The mRNA expressions of UCP1 and estrogen receptor α were detected by realtime fluorescence quantitative PCR (qRT-PCR).ResultsAll nude mice survived during experiment. ELISA test showed that the concentration of estradiol significantly decreased in the ovariectomized group and increased in the high estrogen group compared with the normal estrogen group (P<0.05). At 8 weeks after fat grafting, the graft volume from large to small was ovariectomized group, normal estrogen group, and high estrogen group. There was significant difference in wet weight between the ovariectomized group and high estrogen group (P<0.05). Section staining showed that compared with the normal estrogen group, the adipocytes in the ovariectomized group were larger, the expression of peri-lipoprotein was weaker, the vascular density decreased, and the expressions of UCP1 was negative, and the estrogen receptor α positive cells reduced. The above observation results in the high estrogen group were contrary to those in the ovariectomized group. There were significant differences in the diameter of adipocytes, the vascular density of adipose tissue, the number of the estrogen receptor α positive cells between groups (P<0.05). The results of qRT-PCR showed that the mRNA expressions of UCP1 and estrogen receptor α significantly increased in the high estrogen group and decreased in the ovariectomized group compared with the normal estrogen group, and the differences were significant (P<0.05).ConclusionThe level of circulating estrogen has a significant effect on the outcome of free fat grafting in nude mice. Low estrogen level leads to hypertrophy of graft adipocytes, while high estrogen level leads to the production of a large amount of beige fat and high vascular density in fat grafts, which may be related to the activation of estrogen receptor α on adipocytes.