The biological pacemaker has become a new strategy in the treatment of severe bradycardias, in which a kind of ideal pacemaker cells is a pivotal factor. Here we reviewed the progress in the differentiation of bone-marrow mesenchymal stem cells and adipose-derived stem cells into pacemaker-like cells by means of gene transfer, chemical molecules, co-culture with other cells and specific culture media, and we also analyzed the potential issues to be solved when they are used as seeding cells of biological pacemaker.
ObjectiveTo prepare human acellular adipose tissue matrix and to evaluate the cellular compatibility so as to explore a suitable bio-derived scaffold for adipose tissue engineering. MethodsThe adipose tissue was harvested from abdominal skin graft of breast cancer patients undergoing radical mastectomy or modified radical mastectomy, and then was treated with a series of decellularization processes including repeated freeze-thaw, enzyme digestion, and organic solvent extraction. The matrix was examined by histology, immunohistochemistry, DAPI fluorescence staining, and scanning electron microscopy to observe the the removal of cells and to analyze its composition of collagen type IV, laminin, and fibronectin, and microstructure. The 3rd passage human adipose-derived stem cells (hADSCs) were co-cultured with acellular adipose tissue matrix and different concentrations of extracted liquid (100%, 75%, 50%, and 25%). The cytotoxic effects of the matrix were tested by MTT. The biocompatibility of the matrix was detected by live/dead staining and scanning electron microscopy observation. ResultsThe acellular adipose tissue matrix basically maintains intrinsical morphology. The matrix after acellular treatment consisted of extracellular matrix without any cell components, but there were abundant collagen type I; neither DNA nor lipid residual was detected. Moreover, the collagen was the main component of the matrix which was rich in laminin and fibronectin. At 1, 3, and 5 days after co-cultured with hADSCs, the cytotoxic effect of matrix was grade 0-1. The matrix displayed good cell compatibility and proliferation. ConclusionThe acellular adipose tissue matrix prepared by repeated freeze-thaw, enzyme digestion, and organic solvent extraction method remains abundant extracellular matrix and has good cellular compatibility, so it is expected to be an ideal bio-derived scaffold for adipose tissue engineering.
ObjectiveTo investigate the microRNA (miRNA) expression profile during chondrogenic differentiation of human adipose-derived stem cells (hADSCs), and assess the roles of involved miRNAs during chondrogenesis. MethodshADSCs were harvested and cultured from donors who underwent elective liposuction or other abdominal surgery. When the cells were passaged to P3, chondrogenic induction medium was used for chondrogenic differentiation. The morphology of the cells was observed by inverted phase contrast microscopy. Alcian blue staining was carried out at 21 days after induction to access the chondrogenic status. The expressions of chondrogenic proteins were detected by ELISA at 0, 7, 14, and 21 days. The miRNA expression profiles at pre- and post-chondrogenic induction were obtained by microarray assay, and differentially expressed miRNAs were verified by real-time quantitative PCR (qRT-PCR). The targets of the miRNAs were predicted by online software programs. ResultshADSCs were cultured successfully and induced with chondrogenic medium. At 21 days after chondrogenic induction, the cells were stained positively for alcian blue staining. At 7, 14, and 21 days after chondrogenic induction, the levels of collogen type Ⅱ, Col2a1, aggrecan, Col10a1, and chondroitin sulfate in induced hADSCs were significantly higher than those in noninduced hADSCs (P<0.05). Eleven differentially expressed miRNAs were found, including seven up-regulated and four down-regulated. Predicted target genes of the differentially expressed miRNAs were based on the overlap from three public prediction algorithms, with the known functions of regulating chondrogenic differentiation of stem cells, selfrenewal, signal transduction, intracellular signaling cascade, and cell cycle control. ConclusionA group of miRNAs and their target genes are identified, which may play important roles in regulating chondrogenic differentiation of hADSCs. These results will facilitate the initial understanding of the molecular mechanism of chondrogenic differentiation in hADSCs and subsequently control hADSCs differentiation, and provide high performance seed cells for cartilage tissue engineering.
Objective To assess the effect of pregnant rat adipose-derived stem cells (ADSCs) on repair of acute liver injury. Methods ADSCs were isolated from 18-week pregnant Sprague Dawley rats and were identified by flow cytometry. Twenty Sprague Dawley rats were randomly divided into groups A, B, C, and D (n=5); rats in group A were not treated as normal controls; rats in groups B, C, and D were injected intraperitoneally with CCl4 to establish the acute liver injury model. At 2 hours after modeling, DPBS, 0.1 mL normal rat ADSCs (2×106cells/mL), and pregnant rat ADSCs (2×106cells/mL) were injected into the spleen in groups A, C, and D respectively; rats in group B was not treated. After 7 days, total bilirubin (TBIL), alanine aminotransferase (ALT), aspartic acid transaminase (AST), albumin (ALB), and total protein (TP) in serum were measured. The liver tissue sections were stained with HE. The expressions of Ki67, alpha-fetoprotein (AFP), and ALB were measured by immunohistochemistry. Results The serum levels of TBIL, ALT, and AST in group B were significantly higher than those in groups A, C, and D (P<0.05), but ALB and TP were significantly lower than those in groups A, C, and D (P<0.05). The levels of TBIL, ALT, and AST were significantly higher in groups C and D than group A, and in group C than group D (P<0.05). There was no significant difference in serum levels of ALB among groups A, C, and D (P>0.05). The serum level of TP in groups C and D was significantly lower than that in group A (P<0.05), but no significant difference was found between group C and group D (P>0.05). HE staining showed that the liver tissue of group A had clear structure; the cells arranged neatly with uniform size. The hepatocytes in group B showed obvious edema, disorderly arrangement, dot necrosis in liver lobules, and diffuse infiltration of inflammatory cells. In groups C and D, the inflammation and hepatocellular necrosis were obviously reduced when compared with group B, and the number of vacuoles caused by dilation of mitochondria and rough endoplasmic reticulum was decreased; especially in group D, improvement of liver injury was more effective. The Ki67 positive cell rate was significantly higher in groups C and D than groups A and B (P<0.05), in group B than group A (P<0.05), and in group D than group C (P<0.05). There was no expression of AFP in groups A and B, but positive expression was observed in groups C and D, and AFP positive cell rate of group D was significantly higher than that of group C (t=3.006,P=0.017). ALB expression was significantly higher in groups C and D than groups A and B (P<0.05), and in group D than group C (P<0.05). Conclusion Pregnant rat ADSCs could promote repair of liver injury induced by CCl4.
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 review the research progress of miRNA regulation in the differentiation of adipose-derived stem cells (ADSCs). Methods The recent literature associated with miRNAs and differentiation of ADSCs was reviewed. The regulatory mechanism was analyzed in detail and summarized. Results The results indicate that the expression of miRNAs changes during differentiation of ADSCs. In addition, miRNAs regulate the differentiation of ADSCs into adipocytes, osteoblasts, chondrocytes, neurons, and hepatocytes by regulating the signaling pathways involved in cell differentiation. Conclusion Through controlling the differentiation of ADSCs by miRNAs, the suitable seed cell for tissue engineering can be established. The review will provide a theoretical basis for molecular targeted therapy and stem cell therapy in clinic.
ObjectiveTo explore the effect of vascular endothelial growth factor 165 (VEGF165)-loaded porous poly (ε-caprolactone) (PCL) scaffolds on the osteogenic differentiation of adipose-derived stem cells (ADSCs).MethodsThe VEGF165-loaded porous PCL scaffolds (written, Sf-g/VEGF) were fabricated through a combination of solvent casting/salt leaching and a thermal-induced phase separation technique and then observed under scanning electron microscope (SEM). The release kinetics was determined by ELISA kit. The ADSCs were isolated from inguinal fat pads of 15 Sprague Dawley rats and cultured. The passage 3-4 ADSCs were seeded into the scaffolds, and then cultured in vitro for 7 days. The passage 3-4 ADSCs were seeded into the porous PCL scaffolds (written, Sf-g) as control. The alizarin red S (ARS) staining, ARS activity assay, and real-time quantitative PCR (RT-PCR) were performed to measure the osteogenic differentiation of ADSCs in vitro. Six Sprague Dawley rats were recruited to prepare the bilateral calvarial bone defects models (n=12). The 12 calvarial bone defects were randomly divided into 3 group (n=4). The defects of negative control group were not treated; the defects of Sf-g group and Sf-g/VEGF group were repaired with ADSCs-Sf-g scaffold complex and ADSCs-Sf-g scaffold complex, respectively. At 8 weeks after transplantation, the Micro-CT and HE staining were conducted to evaluate the osteogenic effects in vivo.ResultsThe morphology of the Sf-g/VEGF scaffolds were porous and well-connected, and the cumulative release rate was approximately 80% in 120 hours. The ARS staining showed that the ARS activity of Sf-g/VEGF group were stronger than that of Sf-g group (t=10.761, P=0.000). The mRNA expressions of osteogenic specific markers [special AT-rich sequence protein 2 (Satb2), alkaline phosphatase (ALP), osteocalcin (OCN), and osteopontin (OPN)] were significantly higher in Sf-g/VEGF group than in Sf-g group (P<0.05). The results of Micro-CT and HE staining also confirmed the promotion effect of Sf-g/VEGF scaffolds. All defects of 2 groups were partially repaired by new bone tissue, especially in Sf-g/VEGF group. The volume and area of new bone tissue were significantly higher in Sf-g/VEGF group than in Sf-g group (P<0.05).ConclusionThe VEGF165-loaded scaffolds can significantly improve the osteogenic differentiation of ADSCs both in vitro and in vivo.
Objective To investigate the possibility of enhancing the inducing rate of adipose-derived stem cells (ASCs) into epidermal cells in the medium containing all-trans retinoic acid (ATRA) by supplementing with HaCaT condition medium. Methods ASCs were isolated and identified by detecting the expression of CD34, CD45, CD73, CD90, and CD105 with flow cytometry and differentiating into adipose and osteoblast lineage in the induction medium. The air-liquid interface cell culture model was established with the Transwell Room. The induction medium A contained ATRA, epidermal growth factor (EGF), and keratinocyte growth factor (KGF), while the induction medium B contained ATRA, EGF, KGF, and HaCaT condition medium. Experiment was divided into three groups cultured for 12 days: induction medium A (group A), induction medium B (group B), basic medium (group C). The epidermal cell surface markers: cytokeratin (CK) 14, 15, 16, 19 (Pan-CK) were detected by flow cytometry and CK14 were identified by immunofluorescence stain. Results After induction for 12 days, flow cytometry showed that the positive rate of Pan-CK in group B [(22.0±3.5)%] was higher than that in group A [(11.9±2.7)%], which were both higher than that in group C [(1.1±0.3)%], and the differences were statistical significantly (P<0.01). Immunofluorescence stain showed that the positive rate of CK14 in group B was higher than that in group A [(19.5±7.0)%vs. (10.8±5.7)%, P<0.01], and the expression of CK14 was negative in group C. Conclusion HaCaT condition medium can enhance the ability of ASCs differentiation into epidermal cells in the culture medium containing ATRA.
ObjectiveTo investigate the effect of human adipose-derived stem cells (hADSCs) on pressure ulcers in mouse.MethodsThe subcutaneous adipose tissue from voluntary donation was harvested. Then the hADSCs were isolated and cultured by mechanical isolation combined with typeⅠcollagenase digestion. The 3rd generation cells were identified by osteogenic, adipogenic, chondrogenic differentiations and flow cytometry. The platelet rich plasma (PRP) from peripheral blood donated by healthy volunteers was prepared by centrifugation. The pressure ulcer model was established in 45 C57BL/6 mice by two magnets pressurized the back skin, and randomly divided into 3 groups (n=15). The wounds were injected with 100 μL of hADSCs (1×106 cells) transfected with a green fluorescent protein (GFP)-carrying virus, 100 μL human PRP, and 100 μL PBS in hADSCs group, PRP group, and control group, respectively. The wound healing was observed after injection. The wound healing rate was calculated on the 5th, 9th, and 13th days. On the 5th, 11th, and 21st day, the specimens were stained with HE staing, Masson staining, and CD31 and S100 immunohistochemical staining to observe the vascular and nerve regeneration of the wound. In hADSCs group, fluorescence tracer method was used to observe the colonization and survival of the cells on the 11th day.ResultsThe cultured cells were identified as hADSCs by induced differentiation and flow cytometry. The platelet counting was significantly higher in PRP group than in normal peripheral blood group (t=5.781, P=0.029). General observation showed that the wound healing in hADSCs group was superior to those in PRP group and control group after injection. On the 5th, 9th, and 13th days, the wound healing rate in hADSCs group was significantly higher than those in PRP group and control group (P<0.05). Histological observation showed that compared with PRP group and control group, inflammatory cell infiltration and inflammatory reaction were significantly reduced in hADSCs group, collagen deposition was significantly increased, and skin appendage regeneration was seen on the 21st day; at each time point, the expression of collagen was significantly higher in hADSCs group than in PRP group and control group (P<0.05). Immunohistochemical staining showed that the number of neovascularization and the percentage of S100-positive cells in hADSCs group were significantly better than those in PRP group and control group on the 5th, 9th, and 13th days (P<0.05). Fluorescent tracer method showed that the hADSCs could colonize the wound and survive during 11 days after injection.ConclusionLocal transplantation of hADSCs can accelerate healing of pressure ulcer wounds in mice and improve healing quality by promoting revascularization and nerve regeneration.
ObjectiveTo investigate the early effects of acellular xenogeneic nerve combined with adipose-derived stem cells (ADSCs) and platelet rich plasma (PRP) in repairing facial nerve injury in rabbits.MethodsThe bilateral sciatic nerves of 15 3-month-old male Sprague-Dawley rats were harvested and decellularized as xenografts. The allogeneic ADSCs were extracted from the neck and back fat pad of healthy adult New Zealand rabbits with a method of digestion by collagenase type Ⅰ and the autologous PRP was prepared by two step centrifugation. The 3rd generation ADSCs with good growth were labelled with CM-Dil living cell stain, and the labelling and fluorescence attenuation of the cells were observed by fluorescence microscope. Another 32 New Zealand rabbits were randomly divided into 4 groups and established the left facial nerve defect in length of 1 cm (n=8). The nerve defects of groups A, B, C, and D were repaired with CM-Dil-ADSCs composite xenogeneic nerve+autologous PRP, CM-Dil-ADSCs composite xenogeneic nerve, xenogeneic nerve, and autologous nerve, respectively. At 1 and 8 weeks after operation, the angle between the upper lip and the median line of the face (angle θ) was measured. At 4 and 8 weeks after operation, the nerve conduction velocity was recorded by electrophysiological examination. At 8 weeks after operation, the CM-Dil-ADSCs at the distal and proximal ends of regenerative nerve graft segment in groups A and B were observed by fluorescence microscopy; after toluidine blue staining, the number of myelinated nerve fibers in regenerated nerve was calculated; the structure of regenerated nerve fibers was observed by transmission electron microscope.ResultsADSCs labelled by CM-Dil showed that the labelling rate of cells was more than 90% under fluorescence microscope, and the labelled cells proliferated well, and the fluorescence attenuated slightly after passage. All the animals survived after operation, the incision healed well and no infection occurred. At 1 week after operation, all the animals in each group had different degrees of dysfunction. The angle θ of the left side in groups A, B, C, and D were (53.4±2.5), (54.0±2.6), (53.7±2.4), and (53.0±2.1)°, respectively; showing significant differences when compared with the healthy sides (P<0.05). At 8 weeks after operation, the angle θ of the left side in groups A, B, C, and D were (61.9±4.7), (56.8±4.2), (54.6±3.8), and (63.8±5.8)°, respectively; showing significant differences when compared with the healthy sides and with the values at 1 week (P<0.05). Gross observation showed that the integrity and continuity of regenerated nerve in 4 groups were good, and no neuroma and obvious enlargement was found. At 4 and 8 weeks after operation, the electrophysiological examination results showed that the nerve conduction velocity was significantly faster in groups A and D than in groups B and C (P<0.05), and in group B than in group C (P<0.05); no significant difference was found between groups A and D (P>0.05). At 8 weeks after operation, the fluorescence microscopy observation showed a large number of CM-Dil-ADSCs passing through the distal and proximal transplants in group A, and relatively few cells passing in group B. Toluidine blue staining showed that the density of myelinated nerve fibers in groups A and D were significantly higher than those in groups B and C (P<0.05), and in group B than in group C (P<0.05); no significant difference was found between groups A and D (P>0.05). Transmission electron microscope observation showed that the myelinated nerve sheath in group D was large in diameter and thickness in wall. The morphology of myelin sheath in group A was irregular and smaller than that in group D, and there was no significant difference between groups B and C.ConclusionADSCs can survive as a seed cell in vivo, and can be differentiated into Schwann-like cells under PRP induction. It can achieve better results when combined with acellular xenogeneic nerve to repair peripheral nerve injury in rabbits.