Objective To monitor the stem cell migration into the bone defect following an injection of the labeled mesenchymal stem cells (MSCs) by the enha nced green fluorescent protein (EGFP)technology and to provide insights into an application of MSCs for the fracture healing. Methods Isolated MSCs from the rabbit femur marrow were culture-expanded and were labeled by the transfection with the recombinant retrovirus containing the EGFP gene. Then, some labeled MSCs were cultured under the osteogenic differentiation condition and the phenotype was examined. After the fracture of their bilateral ulna, 18 rabbits were divide d into two groups. The labeled MSCs were injected into the aural vein at 1×107 cells/kg in the experimental group and the unmarked MSCs were injected in the control group 24 hours before surgery, and 1 and 24 hours after surgery, res pectively. Necropsies were performed 2 days after surgery in the two groups. The sections from the left defects were observed under the fluorescence microscope and the others were analyzed by the bright-field microscopy after the HE staining. Results The EGFP did not affect the MSCs viability. After the labeled cells were incubated in the osteogenic medium alkaline phosphatase, the calcium nodule s were observed. All the rabbits survived. The tissue of haematoma was observed in the bone defects and the fluorescent cells were found in the experimental gr oup, but no fluorescent cells existed in the control group. Conclusion The EG FP labeled MSCs can undergo osteogenic differentiation in vitro and can mig rate into bone defects after their being injected into the peripheral vein.
Objective To explore the in vitrodifferentiation of the rat mesenchymal stem cells (MSCs ) into the skeletal muscle cells induced by the myoblast differentiation factor (MyoD) and 5-azacytidine. Methods The MSCs were taken from the rat bone marrow and the suspension of MSCs was made and cultured in the homeothermia incubator which contained 5% CO2at 37℃. The cells were observed under the inverted phase contrast microscope daily. The cells spreading all the bottom of the culture bottle were defined as onepassage. The differentiation of the 3rd passage of MSCs was induced by the combination of 5-azacytidine, MyoD, transforming growth factor β1, and the insulin like growth factor 1. Nine days after the induction, the induced MSCs were collected, which were analyzed with the MTT chromatometry, theflow cytometry, and the immunohistochemistry. Results The primarily cultured MSCs grew as a colony on the walls of the culture bottle; after the culture for 5-7 days, the cells were shaped like the fibroblasts, the big flat polygonal cells, the medium sized polygonal cells, and the small triangle cells; after the culture for 12 days, the cells were found to be fused, spreadingall over the bottle bottom, but MSCs were unchanged too much in shape. After the induction by 5-azacytidine, some of the cells died, and the cells grew slowly. However, after the culture for 7 days, the cells grew remarkably, the cell volume increased gradually in a form of ellipse, fusiform or irregularity. After theculture for 14 days, the proliferated fusiform cells began to increase in a great amount. After the culture for 18-22 days, the myotubes increased in number and volume, with the nucleus increased in number, and the newly formed myotubes and the fusiform myoblst grew parallelly and separately. The immunohistochemistry for MSCs revealed that CD44 was positive in reaction, with the cytoplasm ina form of brown granules. And the nucleus had an obvious border,and CD34 was negative. The induced MSCs were found to be positive for desmin and specific myoglobulin of the skeletal muscle. The flow cytometry showed that most of the MSCs and the induced MSCs were in the stages of G0/G1,accounting for 79.4% and 62.9%,respectively; however, the cells in the stages of G2/S accounted for 20.6% and 36.1%. The growth curve was drawn based on MTT,which showed that MSCs weregreater in the growth speed than the induced MSCs. The two kinds of cells did not reach the platform stage,having a tendency to continuously proliferate.ConclusionIn vitro,the rat MSCs can be differentiated into the skeletal muscle cells with an induction by MyoD and 5-azacytidine, with a positive reaction for the desmin and the myoglobulin of the skeletal muscle. After the induction, the proliferation stage of MSCs can be increased, with a higher degree of the differentiation into the skeletal muscle.
支气管哮喘是由嗜酸粒细胞、 肥大细胞和T淋巴细胞等多种细胞和细胞组分参与的气道慢性炎症性疾患,主要病理特点为上皮层大量的嗜酸粒细胞浸润及以上皮下纤维化、平滑肌增生、胶原蛋白沉积为主的气道重塑。哮喘的发病机制较为复杂,而炎症因子表达异常在哮喘的发病中发挥主要作用[1-3]。哮喘是一种全球范围内的常见病、多发病,我国约有1000万以上哮喘患者,而目前对于哮喘尚缺乏有效的根治方法。 间充质干细胞(mesenchymal stem cells,MSC)是具有强大的增殖能力和多向分化潜能的成体干细胞,同时具有免疫调节作用,它能通过免疫调节作用改善多种免疫相关性疾病的病情,而既往MSC在呼吸系统疾病中的研究主要集中在急性肺损伤,在哮喘当中的研究甚少。对于哮喘这一类以炎症因子表达异常为主的变态反应性疾病,MSC是否可以用于哮喘的治疗,值得我们进一步探讨。
Congestive heart failure is a complication of myocardial infarction threatening human health. Although the pharmacotherapy is effective, it is still a worldwide challenge to thoroughly repair the injured myocardium induced by myocardial infarction. It has been demonstrated that mesenchymal stem cells (MSCs) can repair infarcted myocardium. Much evidence shows that MSCs can generate new myocardial cells in both human and animals' hearts. This review aims at discussing the therapeutic progress of the congestive heart failure treated with MSCs.
Objective To investigate effect of bone marrow mesenchymal stem cells (BMSCs) via portal vein injection on transforming growth factor-β receptor 1 (TGF-βR1) and TGF-βR2 in rats with acute liver failure (ALF). Methods Sixty male SD rats were randomly divided into a normal control group, ALF model group, and BMSCs treatment group, with 20 rats in each group. The rats of normal control group were directly sacrificed without other treatment. The ALF models were made in the rats of BMSCs treatment group and ALF model group, then were treated with BMSCs and equal volume of normal saline respectively. On day 7 after treatment, the 1-week survival situation of rats was observed, the pathological change was observed by HE staining, the apoptosis of liver cells was detected by TUNEL method, and the TGF-βR1 and TGF-βR2 proteins expressions were detected by Western blot method. Results ① The 1-week survival rate of the BMSCs treatment group was significantly higher than that of the ALF model group (P<0.05). ② In the ALF model group, the liver cells were diffuse necrosis, the lobular structure was indistinct, and a large number of bridging necrosis. In the BMSCs treatment group, the infiltrations of inflammatory cells were decreased, and the structure of hepatic lobules gradually recovered, and the normal hepatocytes were seen around it. ③ The apoptosis indexes of the BMSCs treatment group and the ALF model group were significantly higher than those in the normal control group (P<0.05), which in the BMSCs treatment group was significantly lower than that of the ALF model group (P<0.05). ④ The TGF-βR1 and TGF-βR2 proteins expressions in the liver tissues of the ALF model group were significantly higher than those of the normal control group (P<0.05), which of the BMSCs treatment group were significantly lower than those of the ALF model group (P<0.05). Conclusion BMSCs could inhibit apoptosis of hepatocytes in ALF. Its mechanism might be related to expressions of TGF-βR1 and TGF-βR1 proteins, but its specific regulatory pathway needs to be further studied.
Objective To explore the role and possible mechanisms of bone marrow mesenchymal stem cell (BMSC) in the lipopolysaccharide (LPS)-induced inflammatory response involving alveolar macrophages through the inflammatory pathways. Methods ptges and ptges shRNA were transfected into BMSC by lentivirus, and stable ptges overexpression BMSC (BMSC-PGE2(+)) and PTGEs silencing BMSC (BMSC-PGE2(-)) were established. Macrophages were divided into control group, LPS group, LPS+BMSC group, LPS+BMSC-PGE2(+) group and LPS+BMSC-PGE2(-) group. The expression levels of nucleotide-bound oligomerized domain-like receptor 3 (NLRP3), precursor cysteinyl aspartate specific proteinase 1 (pro-caspase-1), caspase-1 and pro-IL-1β proteins were detected by Western blot. The mRNA expression levels of NLRP3 and caspase-1 were determined by RT-PCR. The expression levels of tumor necrosis factor-α (TNF-α), interleukin-1β (IL-1β), IL-10, IL-18 and prostaglandin E2 (PGE2) in cell supernatant were detected by ELISA. Results The intervention of LPS significantly increased the expression of NLRP3, pro-caspase-1, caspase-1 and pro-IL-1β in macrophages. After co-culture with BMSC, the expression of each protein decreased significantly. After the overexpression of PGE2, the difference of protein expression further decreased. The expression of NLRP3 and caspase-1 mRNA in LPS group increased significantly, but decreased significantly after co-culture with BMSC. Overexpression of PGE2 could increase this difference, but there was no significant change in PGE2 silent group. The results of ELISA showed that the contents of TNF-α, IL-1β and IL-18 in cell supernatant were the highest in LPS group. Adding BMSC and overexpressing PGE2 could decrease the related inflammatory factors. The levels of IL-10 and PGE2 in LPS group were higher than those in control group, and further increased in LPS+BMSC group and LPS+BMSC-PGE2(+) group with significant differences. Conclusions When inflammation is induced by LPS, BMSC can significantly mitigate the inflammatory response within macrophages. This process is likely mediated through the overexpression of PGE2, which inhibits the NLRP3-mediated pyroptosis pathway.
Objective To study the culture and purification of the fetal mouse liver mesenchymal stem cells(MSCs) in vitro and to investigate their differentiation potential and the composite ability with true bone ceramic(TBC). Methods The single cell suspension of MSCs was primarily cultured and passaged, which was prepared from the fetal mouse liver; the flow cytometry was applied to detectCD29, CD34, CD44 and CD45. The osteogenic differentiation was induced in chemical inducing system; the osteogenic induction potency was tested. The purified fetal mouse liver MSCs were compounded with TBC covered with collagen type Ⅰ in vitro and the cell attachment and proliferation to the TBC were observed. Results The primary MSCs of fetal mouse liver were easy to culture in vitro. They proliferated well and were easy to subcultured. The proliferation ability of primary and passaged MSCs was similar. Flow cytometric analysis showed the positive results for CD29, CD44 and the negative results for CD34, CD45. After 7 days of induction, the MSCs expressed collagen type I and alkaline phosphatase(ALP) highly. After 14 days of induction, the fixed quantity of ALP increased significantly. After 28 days of induction, calcium accumulation was observed by Von Kossa’s staining. Many liver MSCs attached to the surface of TBC. Conclusion The MSCs of the fetalmouse liver can be obtained, subcultured and purified easily. After culturing in chemical inducing system, the MSCs of fetal mouse liver can be successfully induced to osteoblast-like cells, attach to the surface of TBC and proliferate well.
Spinal cord injury (SCI) is a complex pathological process. Based on the encouraging results of preclinical experiments, some stem cell therapies have been translated into clinical practice. Mesenchymal stem cells (MSCs) have become one of the most important seed cells in the treatment of SCI due to their abundant sources, strong proliferation ability and low immunogenicity. However, the survival rate of MSCs transplanted to spinal cord injury is rather low, which hinders its further clinical application. In recent years, hydrogel materials have been widely used in tissue engineering because of their good biocompatibility and biodegradability. The treatment strategy of hydrogel combined with MSCs has made some progress in SCI repair. This review discusses the significance and the existing problems of MSCs in the repair of SCI. It also describes the research progress of hydrogel combined with MSCs in repairing SCI, and prospects its application in clinical research, aiming at providing reference and new ideas for future SCI treatment.
Objective To investigate the method and conditions of isolation,proliferation of multipotent mesenchymal stem cells(MSCs)from human umbilical cord blood in vitro, and to induce osteogenic and adipogenic differentiation directly for identification. Methods Human umbilical cord blood was collected in asepsis condition, isolated by density gradient centrifugation,or sedimented red cell with methylcellulose, and then the same centrifugation was done, or obtained by negative immunodepletion of CD34+. These isolated mononuclear cells were used to carry on plastic adherent culture. To obtain single cellderived colonies, these cells were proliferated clonally in medium which consists of L-DMEM orMesencultTM medium and 10% fetal calf serum(FCS) respectively, then their differentiation potentiality to osteoblasts and lipoblasts was tested. Results The mononuclear cells isolated by sedimented and centrifugated way cultured in MesencultTM medium and 10%FCS were most available. These adhesive cells could become obviously short rodshape or shuttle-shape cells after 5-7 days.The colonies form well in 3rdpassage cells. The mononuclear cells obtained by onlycentrifugalized in density gradient were hard to form colony, isolated by immunomagnetic beads were hard to culture. The surface antigens of these colonies cells presented CD29, CD59, CD71 but not CD34,CD45 and HLADR etc. The colony cells differentiating into osteoblasts that produce mineralized matrices, stained by alizarin red, and differentiating into adipocytes that accumulate lipid vacuoles, stained by oil red. Conclusion MSCs can be isolated from human umbilical cord blood and proliferate it in vitro. The way that mononuclear cells are sedimented red cell by methylcellulose and cultured by MesencultTM medium and 10% FCS is the valid method of isolation. Proliferation colonies cells present matrix cell immunophenotypes, and candifferentiate into osteoblasts and adipocytes.