Objective To investigate the effect of simvastatin on inducing endothel ial progenitor cells (EPCs) homing and promoting bone defect repair, and to explore the mechanism of local implanting simvastatin in promoting bone formation. Methods Simvastatin (50 mg) compounded with polylactic acid (PLA, 200 mg) or only PLA (200 mg) was dissolved in acetone (1 mL) to prepare implanted materials (Simvastatin-PLA material, PLA material). EPCs were harvested from bone marrow of 2 male rabbits and cultured with M199; after identified by immunohistochemistry, the cell suspension of EPCs at the 3rd generation (2 × 106 cells/mL) was prepared and transplanted into 12 female rabbits through auricular veins(2 mL). After 3 days, the models of cranial defect with 15 cm diameter were made in the 12 female rabbits. And the defects were repaired with Simvastatin-PLA materials (experimental group, n=6) and PLA materials (control group, n=6), respectively. The bone repair was observed after 8 weeks of operation by gross appearance, X-ray film, and histology; gelatin-ink perfusion and HE staining were used to show the new vessels formation in the defect. Fluorescence in situ hybridization (FISH) was performed to show the EPCs homing at the defect site. Results All experimental animals of 2 groups survived to the end of the experiment. After 8 weeks in experimental group, new bone formation was observed in the bone defect by gross and histology, and an irregular, hyperdense shadow by X-ray film; no similar changes were observed in control group. FISH showed that the male EPC containing Y chromosome was found in the wall of new vessels in the defect of experimental group, while no male EPC containing Y chromosome was found in control group. The percentage of new bone formation in defect area was 91.63% ± 4.07% in experimental group and 59.45% ± 5.43% in control group, showing significant difference (P lt; 0.05). Conclusion Simvastatin can promote bone defect repair, and its mechanism is probably associated with inducing EPCs homing and enhancing vasculogenesis.
ObjectiveTo investigate the ability of autologous peripheral blood endothelial progenitor cells (EPCs) in promoting neovascularization of tissue engineered bone and osteogenesis of bone marrow mesenchymal stem cells (BMSCs). MethodThe peripheral blood EPCs and BMSCs from No. 1-9 New Zealand rabbits were isolated, cultured, and identified. According to the cell types, the third generation of cells were divided into 3 groups:EPCs (group A), BMSCs (group B), and co-cultured cells of EPCs and BMSCs (group C, EPCs:BMSCs=1:2) . Then cells were seeded on the partially deproteinised bone (PDPB) packaged with fibronectin to construct tissue engineered bone. After 4 days, autologous heterotopic transplantation of tissue engineered bone was performed in the rabbit's muscles bag of groups A, B, and C (the right arm, left arm, right lower limb respectively, 2 pieces each part). At 2, 4, and 8 weeks after transplantation, the growth of tissue engineered bone was observed, and the rate of bone ingrowth was calculated by HE staining; the expressions of CD34, CD105, and zonula occludens protein 1(ZO-1) were compared by immunohistochemical staining at each time point in tissue engineered bone among 3 groups. ResultsThe EPCs and BMSCs were isolated and identified successfully; immunofluorescent staining showed that EPCs were positive for CD34, CD133, and von Willebrand factor (vWF), and BMSCs were positive for CD29 and CD90 and were negative for CD34. The tissue engineered bone constructed in 3 groups was transplanted successfully. At 2, 4, and 8 weeks after autologous heterotopic transplantation, the general observations showed that the soft tissue around the tissue engineered bone increased and thickened gradually in each group with time passing; the boundary between bone and soft tissue was not clear; the pore space of tissue engineered bone gradually was filled, especially in group C, the circuitous vascular network could be seen in the tissue engineered bone. HE staining showed capillaries and collagen fibers increased gradually, tissue engineered bone ingrowth rate was significantly higher in group C than groups A and B at 4 and 8 weeks (P<0.05) , and group B was significantly higher than group A (P<0.05) . Immunohistochemical staining showed that the expressions of CD34, CD105, and ZO-1 in tissue engineered bone of 3 groups all increased with the extension of time, showing significant differences between groups at each time point (P<0.05) . At 2 weeks after transplantation, the expression of CD105 in group C was significantly higher than that in groups A and B (P<0.05) ; at 4 and 8 weeks, CD34, CD105, and ZO-1 expressions showed significant differences between 2 groups (P<0.05) ; the expression was the highest in group C, and was the lowest in group B. ConclusionsAutologous peripheral blood EPCs and BMSCs have synergistic effect, and can promote neovascularization and osteogenesis of tissue engineered bone in vivo.
ObjectiveTo research the magnetic labeled endothelial progenitor cells(EPCs) transplanted into the rat of venous thrombosis model through the tail vein and track transplanted stem cells in vivo, provide an effective monitoring technology for promoting organization and recanalization of deep venous thrombosis. MethodsBone marrowderived EPCs were extracted, purified, and identified, then labeled with the new SPIO particles. At the same time, the inferior vena cava thrombus models in rats were made, which were randomly divided into four groups:SPIO group (EPCs labeled with SPIO transplantation), Dil group (EPCs labeled with Dil transplantation), control group (simple EPCs transplantation), and blank control group (1 mL medium transplantation). After transplantation, the MRI, HE staining, and immunohistochemical staining were performed and the capillary density was counted under high-power microscope. ResultsThe MRI showed that EPCs labeled with SPIO had migrated to the inferior vena cava thrombus and the mass of high signal shade was seen, with the extension of time, the signal strengthened gradually. On day 14-21, the signal became the strongest, then decreased gradually. The immunohistochemical staining and HE staining showed that there were a mass of the new capillary in the specimens of thrombus of the SPIO group, Dil group, and control group, the difference was not statistically significant among these three groups(P > 0.05), but which was significant difference as compared with blank control group (P < 0.05). ConclusionCompared with EPCs labeled with Dil, it
Abstract: Objective To investigate and improve the method of isolation, induction and culture, amplification in vitro of human endothelial progenitor cells (EPCs) in human bone marrow, thus establish a foundation for EPCs to participate in basic research and clinical application. Methods WHuman bone marrow mononuclear cells (hBMMNCs) were isolated by density gradient centrifugation and cultured in the 6plateds coating human fibronections(HFN group), coating gelatinum (coating gelatinum group) and coating nothing (coating nothing group) respectively. After culturing for 4-7d endothelial cell basal medium-2(EBM-2) cell colonyforming units (CFUs) appeared, then select EPCsliked CFUs for cultivation which was named the pick method, CD34+ KDR+ and CD133+ KDR+ double positive cells were detected in flow cytometry, and CD133, CD34, CD31, vWF and KDR expression were detected with cell immunochemical test. Results hBMMNCs were isolated from human bone marrow more effectively with OptiprepTM cell separating medium, and induced and obtained more EPCs, and cultured and amplificated in vitro. Flow cytometer showed CD133+ KDR+ double positive cells reaching up to 70.4%±5.4%, CD34+ KDR+ double positive cells reaching up to 69.1%±8.7%. EPCs grew vigorously in coating HFN group and coating gelatinum group, both HFN and gelatinum promote EPCs adherence and growth, but there were no statistically difference in two groups (Pgt;0.05).Surface mark of adherent cells cultured 7d such as CD133, CD31, vWF and KDR showed positive, and cells cultured 14d such as CD34 showed positive. Conclusion The method of picking CFUs can obtain more EPCs from human bone marrow with success and can amplificate EPCs in vitro, thus introducing another simple and effective method to purify EPCs, further widening range and increasing method to purify EPCs.
【摘要】 目的 比较密度梯度离心法及全骨髓培养法分离培养内皮祖细胞的差异。方法 取4周雄性近交系C57BL/6J小鼠骨髓,分别使用密度梯度离心法及全骨髓培养法培养,观察细胞贴壁情况和细胞形态,并行DiIacLDL及FITCUEAI双染、vWF、eNOS及细胞表面标志检测。结果 密度梯度离心法培养细胞可形成典型铺路石样改变及形成血管样结构;而全骨髓培养法贴壁细胞形态多样,较多呈长梭形铺展生长,部分细胞呈类圆形及纺锤形。比较两种方法培养细胞摄取DiIacLDL、结合FITCUEAI双阳性率以及vWF、eNOS及细胞表面标志表达阳性率,差别均有统计学意义(Plt;005)。应用密度梯度离心法,随着培养时间延长,表达CD34、CD133及FLk1细胞逐渐增多(Plt;005)。结论 密度梯度离心法及全骨髓培养法在EGM2MV培养体系下均可培养出内皮祖细胞,但密度梯度离心法较全骨髓培养法培养的内皮祖细胞纯度高。
Objective To determine the transfection efficiency of recombinant adenovirus to endothelial progenitor cells(EPCs) and provide the base of lung cancer therapy by transfecting human herpes simplex virusthymidine kinase(HSV-TK) gene to EPCs. Methods Admove recombinant adenovirus 5F35(AD5F35) which transfected with βgalactosidase(AD5F35LacZ) to the 24 well plate cultivated with EPCs and transfect the EPCs. Stain the EPCs with LacZ kit and calculate the transfection efficiency. Results The blue stain cells were cells transfected successfully with AD5F35LacZ under the optical microscope. The transfection efficiencies of adenovirus to EPCs were different under the premise of the different multiplicity of infection(MOI). In a certain range, the transfection efficiencies rise with the MOI rise. When MOI was 400,the proportion of blue stain cell is the highest, which was 98.38%±1.25%. Conclusion Recombinant adenovirus can transfect EPCs successfully. The transfection efficiencies rise with the MOI rise. When the MOI is 400,the transfection efficiency is the highest.
Objective To observe endothelial progenitor cells (EPCs) participating in the formation of neovascularization in lung adenocarcinoma. Methods EPCs were transfected by recombinant adenovirus carrying LacZ gene in optimal transfection concentration, and then EPCs were injected into animal models of lung adenocarcinoma through the tail vein; afterwards, lung tissues were taken out for pathological examination in the 6th, 7th, 8th week respectively. EPCs were observed to take part in the angiogenesis in the lung adenocarcinoma through X-gal chromogenic dye. Results The optimal multiplicity of infection (MOI) of AD5F35LacZ transfected EPCs was 400. When MOI was 400, maximum transfection efficiency was 97.13±2.08. After 2 weeks, LacZ gene-transfected EPCs began to proliferate in vitro culture, then the EPCs were transplanted into animal models of lung cancer to be involved in the neovascularization formation in the 8th week after transplantation. Conclusion EPCs are involved in the formation of tumor neovascularization after transplantation.
ObjectiveBased on the cell-extracellular matrix adhesion theory in selective cell retention (SCR) technology, demineralized bone matrix (DBM) modified by simplified polypeptide surface was designed to promote both bone regeneration and angiogenesis.MethodsFunctional peptide of α4 chains of laminin protein (LNα4), cyclic RGDfK (cRGD), and collagen-binding domain (CBD) peptides were selected. CBD-LNα4-cRGD peptide was synthesized in solid phase and modified on DBM to construct DBM/CBD-LNα4-cRGD scaffold (DBM/LN). Firstly, scanning electron microscope and laser scanning confocal microscope were used to examine the characteristics and stability of the modified scaffold. Then, the adhesion, proliferation, and tube formation properties of CBD-LNα4-cRGD peptide on endothelial progenitor cells (EPCs) were detected, respectively. Western blot method was used to verify the molecular mechanism affecting EPCs. Finally, 24 10-week-old male C57 mice were used to establish a 2-mm-length defect of femoral bone model. DBM/LN and DBM scaffolds after SCR treatment were used to repair bone defects in DBM/LN group (n=12) and DBM group (n=12), respectively. At 8 weeks after operation, the angiogenesis and bone regeneration ability of DBM/LN scaffolds were evaluated by X-ray film, Micro-CT, angiography, histology, and immunofluorescence staining [CD31, endomucin (Emcn), Ki67].ResultsMaterial related tests showed that the surface of DBM/LN scaffold was rougher than DBM scaffold, but the pore diameter did not change significantly (t=0.218, P=0.835). After SCR treatment, DBM/LN scaffold was still stable and effective. Compared with DBM scaffold, DBM/LN scaffold could adhere to more EPCs after the surface modification of CBD-LNα4-cRGD (P<0.05), and the proliferation rate and tube formation ability increased. Western blot analysis showed that the relative expressions of VEGF, phosphorylated FAK (p-FAK), and phosphorylated ERK1/2 (p-ERK1/2) proteins were higher in DBM/LN than in DBM (P<0.05). In the femoral bone defect model of mice, it was found that mice implanted with DBM/LN scaffold had stronger angiogenesis and bone regeneration capacity (P<0.05), and the number of CD31hiEmcnhi cells increased significantly (P<0.05).ConclusionDBM/LN scaffold can promote the adhesion of EPCs. Importantly, it can significantly promote the generation of H-type vessels and realize the effective coupling between angiogenesis and bone regeneration in bone defect repair.
ObjectiveTo explore optimal conditions of isolation, culture and labeled with superparamagnetic iron oxide (SPIO) in vitro of rat bone marrow endothelial progenitor cells, and lay the foundations for the further EPCs tracer study in vivo. MethodsThe EPCs derived from rat bone marrow were isolated and cultured by using density gradient centrifugation, which were labeled with different concentrations SPIO, Prussian blue staining was used to detect the cells labeling rate, MTT assay was used to detect the cells proliferation activity, and Trypan blue staining was used to detect the cells vitality. ResultsEPCs gradually growed in monolayer arrangement about 7 d after cultured. When the concentration of SPIO was 50μg/mL, the highest labeling rate of Prussian blue staining was 90%, the growth state of labeled EPCs were good, and could normal adherent growth and passage. At this time, the cell viability and proliferation activity were the highest through trypan blue staining and MTT assay. ConclusionsEPCs can be labeled with SPIO easily and efficiently when the concentration was 50μg/mL?without interference on the viability and proliferation activity, which lay the foundations for the further EPCs tracer study in vivo.
Objective To observe the changes in the number and function of bone marrow-derived endothel ial progenitor cells (EPCs) after bone-marrow stimulation, and to investigate the possible mechanism of improving ischemicl imb disease after bone-marrow stimulation through autologue bone-marrow stem cell implantation. Methods Twelvemale Lewis rats, weighing 200-250 g, were classified into the bone marrow stimulation group (n=6) and the control group(n=6). In the stimulation group, the bone marrow of each rat was stimulated by injection of recombinant human granulocytemacrophage colony-stimulatory factor. Mononuclear cells were harvested from bone marrow and cultured in EBM-2 medium. After 7-day culture, EPCs were stained by 1, 1-dioctadecyl-3, 3, 3, 3-tetramethyl indocarbocyanine-labbled acetylated low density l ipoprotein/fluorescein isothiocyanate-ulex europaeus agglutinin 1, and the double positive cells were counted by the fluorescent microscope. The adhesive abil ity of EPCs was determined by counting the number of re-cultured EPCs. The unilateral ischemia hindl imb model was made with 12 Lewis rats. Three days later, EPCs were transplanted into the ischemic tissues. According to different sources of EPCs, the 12 rats were divided into 2 groups: the stimulation group (n=6) and the control group (n=6). At 3 weeks after EPCs transplantation, the quantity of the collateral vascular was observed by digital subtraction angiography (DSA). Results After 7-day culture, the number of EPCs in the stimulation and control groups was (145.2 ± 37.0)/HP and (95.2 ± 39.4)/HP, respectively, and there was significant difference between the two groups (P lt; 0.05). Meanwhile, the number of adhesive EPCs in the stimulation and control groups was (21.8 ± 4.3)/HP and (15.0 ± 5.2)/HP, respectively, and the difference between the two groups was significant (P lt; 0.05). At 3 weeks after the EPCs implantation, the number of the collateral vascular was significantly larger in the stimulation group (4.2 ± 1.2) compared with the control group (2.7 ± 0.8), (P lt; 0.05). Conclusion Bone marrow stimulation increases the number of EPCs and improves the function concurrently, which may be the reason why autologue bone-marrow stem cell implantation improves the curative effect of ischemic l imb diseases after bone-marrow stimulation.