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 study the short and medium term effect of myocardial contractile force by implantation of endothelial progenitor cells (EPCs) in the myocardial infarction model. Methods Hundred and twenty SD rats were equally and randomly divided into experimental group and control group (60 rats in each group). Acute myocardial infarction model was created by ligation of LAD. Autologous EPCs were purified from peripheral blood then implanted into the acute myocardial infarct site via topical injection. IMDM were used in control group. Specimens and muscle strip were harvested at 3, 6 weeks, 6, 8 and 12 months after EPCs implantation for contractile force study and to detect the expression of vascular endothelial growth factor(VEGF), basic fibroblast growth factor (bFGF) and Ⅷ factor by immunohistology and video image digital analysis system. Results The expression of VEGF, bFGF and the microvessel counts in experimental group were much higher than those of control group(P〈 0.01) at 3, 6 weeks and 6 months after transplantation. The contractile force in experimental group was better than that in control group(P〈0.01) at the same time. But from 8 months after implantation, the contractile force and so on were not up in the experimental group. Conclusion EPCs, after being implanted into infarct myocardium, shows the ability of improvement of the contractile performance in infarcted myocardium by means of angiogenesis and vasculogenesis and the medium term results are persistent.
Objective To compare canine decel luarized venous valve stent combining endothel ial progenitor cells (EPC) with native venous valve in terms of venous valve closure mechanism in normal physiological conditions. Methods Thirty-six male hybrid dogs weighing 15-18 kg were used. The left femoral vein with valve from 12 dogs was harvested to prepare decelluarized valved venous stent combined with EPC. The rest 24 dogs were randomly divided into the experimental group and the control group (n=12 per group). In the experimental group, EPC obtained from the bone marrowthrough in vitro ampl ification were cultured, the cells at passage 3 (5 × 106 cells/mL) were seeded on the stent, and the general and HE staining observations were performed before and after the seeding of the cells. In the experimental group, allogenic decelluarized valved venous stent combined with EPC was transplanted to the left femoral vein region, while in the control group, the autogenous vein venous valve was implanted in situ. Color Doppler Ultrasound exam was performed 4 weeks after transplantation to compare the direction and velocity of blood flow in the distal and proximal end of the valve, and the changes of vein diameter in the valve sinus before and after the closure of venous valve when the dogs changed from supine position to reverse trendelenburg position. Results General and HE staining observations before and after cell seeding: the decelluarized valved venous stent maintained its fiber and collagen structure, and the EPC were planted on the decelluarized stent successfully through bioreactor. During the period from the reverse trendelenburg position to the starting point for the closure of the valve, the reverse flow of blood occurred in the experimental group with the velocity of (1.4 ± 0.3) cm/s; while in the control group, there was no reverse flow of blood, but the peak flow rate was decreased from (21.3 ± 2.1) cm/s to (18.2 ± 3.3) cm/s. In the control group, the active period of valve, the starting point for the closure of the valve, and the time between the beginning of closure and the complete closure was (918 ± 46), (712 ± 48), and (154 ± 29) ms, respectively; while in the experimental group, it was (989 ± 53), (785 ± 43), and (223 ± 29) ms, respectively. There was significant difference between two groups (P lt; 0.05).After the complete closure of valve, no reverse flow of blood occurred in two groups. The vein diameter in the valve sinus of the experimental and the control group after the valve closure was increased by 116.8% ± 2.0% and 118.5% ± 2.2%, respectively, when compared with the value before valve closure (P gt; 0.05). Conclusion Canine decelluarized venous valve stent combined with EPC is remarkably different from natural venous valve in terms of the valve closure mechanism in physiological condition. The former rel ies on the reverse flow of blood and the latter is related to the decreased velocity of blood flow and the increased pressure of vein in the venous sinus segment.
Objective To measure the level of circulating endothelial progenitor cells ( EPCs) in peripheral blood of patients with acute exacerbation of chronic obstructive pulmonary disease ( AECOPD) , and to explore the relationship between EPCs and severity markers of the disease and cardiovascular adverse outcome predictors.Methods Forty patients with COPD were recruited, including 27 at acute exacerbation phase and 13 with stable COPD from December 2010 to December 2011. Sixteen healthy nonsmokers were included as controls. Circulating EPCs were isolated by Ficoll density-gradient centrifugation and purified by Magnetic Activated Cell Sorting system. High-sensitivity C-reactive protein ( hsCRP) was estimated by using a latex immunoturbidimetric assay kit, and matrix metalloproteinase-9 ( MMP-9) was measured by enzymelinked immunosorbent assay ( ELISA) . Arterial blood gas analysis and echocardiograph were performed in the AECOPD patients. The correlations between circulating EPCs, lung function, and cardiovascular markers were investigated. Results Circulating EPCs were significantly lower in AECOPD and stable COPD patients compared with the healthy controls [ ( 5.1 ±2.6) ×103 /mL and ( 6.0 ±3.2) ×103 /mL vs. ( 9.0 ±4.3) × 103 /mL, Plt;0. 05] . EPCs had a weak correlation with hsCRP ( P = 0. 033) , but not with MMP-9. In the AECOPD patients, EPC counts were significantly inversely correlated with PASP ( pulmonary artery systolic pressure) and NT-proBNP ( amino-terminal pro-brain natriuretic peptide) levels, and positively with left ventricular ejection fraction. No correlations were found between EPCs and lung function, blood gas, hospital stays or smoking index. Conclusions Circulating EPCs were significantly lower in AECOPD patients compared with healthy controls, in which systemic inflammation might be involved. Decreased EPCs were correlated with cardiac dysfunction in patients with AECOPD, which may account for the increased cardiovascular risk in this population.
ObjectiveTo review the research progress of the co-culture system for constructing vascularized tissue engineered bone. MethodsThe recent literature concerning the co-culture system for constructing vascularized tissue engineered bone was reviewed, including the selection of osteogenic and endothelial lineages, the design and surface modification of scaffolds, the models and dimensions of the co-culture system, the mechanism, the culture conditions, and their application progress. ResultsThe construction of vascularized tissue engineered bone is the prerequisite for their survival and further clinical application in vivo. Mesenchymal stem cells (owning the excellent osteogenic potential) and endothelial progenitor cells (capable of directional differentiation into endothelial cell) are considered as attractive cell types for the co-culture system to construct vascularized tissue engineered bone. The culture conditions need to be further optimized. Furthermore, how to achieve the clinical goals of minimal invasion and autologous transplantation also need to be further studied. ConclusionThe strategy of the co-culture system for constructing vascularized tissue engineered bone would have a very broad prospects for clinical application in future.
ObjectiveTo review the research progress of neural regulation mechanism of vasculogenesis. MethodsThe relevant literature on neural regulation mechanism of vasculogenesis was extensively reviewed. ResultsNeural regulation of vasculogenesis depends on synergistic effect among various cells of neurovascular unit, and co-participation of multiple cytokines, and it is closely related to a variety of repair mechanism, such as nerve regeneration and synaptic plasticity, but the specific mechanism need to be further investigated. ConclusionThe research of the neural regulation mechanism of vasculogenesis will contribute to further understanding repair mechanism of nerves and vessels injuries.
ObjectiveTo review the current progresses in purification strategies, biological characters, and functions of endothelial progenitor cells (EPCs) derived extracellular vesicles (EVs) (EPC-EVs). MethodsRecent relevant publications on the EPC-EVs were extensively reviewed, analyzed, and summarized. ResultsEPC-EVs are usually isolated by differential centrifugation and exhibit a homogenous pattern of spheroid particles with a diameter ranging from 60 to 160 nm under transmission electron microscopy. EPC-EVs are positive for cell-surface markers of EPCs (CD31, CD34, and CD133), and negative for markers of platelets (P-selectin and CD42b) and monocytes (CD14). Recent studies have shown the effectiveness of EPC-EVs in ischemic injuries, anti-Thy1 glomerulonephritis, and cardiomyocyte hypertrophy, and also shown their predictive role in cardio-cerebral-vascular diseases. ConclusionAn alluring prospect exists on the EPC-EVs-related research. Further studies are required to decipher the composition of EPC-EVs and their precise role in pathophysiological processes, and to investigate the molecular mechanisms for their targeting and function.
ObjectiveTo compare the biological features of early and late endothelial progenitor cells (EPCs) by isolating and culturing early and late EPCs from the human peripheral blood so as to find some unique properties of EPCs and to propose a suitable strategy for EPCs identification. MethodsMononuclear cells were isolated from the human peripheral blood using density gradient centrifugation. Then, the cells were inoculated in human fibronectin-coated culture flasks and cultured in endothelial cell basal medium 2. After 4-7 days and 2-3 weeks culture, early and late EPCs were obtained respectively. The morphology, proliferation potential, surface markers, cytokine secretion, angiogenic ability, and nitric oxide (NO) release were compared between 2 types of EPCs. Meanwhile, the human aortic endothelial cells (HAECs) were used as positive control. ResultsThe morphology of early and late EPCs was different:early EPCs formed a cell cluster with a spindle shape after 4-7 days of culture, and late EPCs showed a cobblestone appearance. Late EPCs were characterized by high proliferation potential and were able to form capillary tubes on Matrigel, but early EPCs did not have this feature. Both types EPCs could ingest acetylated low density lipoprotein and combine with ulex europaeus Ⅰ. Flow cytometry analysis showed that early EPCs did not express CD34 and CD133, but expressed the CD14 and CD45 of the hematopoietic stem cell markers;however, late EPCs expressed CD31 and CD34 of the endothelial cell markers, but did not express CD14, CD45, and CD133. By RT-PCR analysis, the expressions of vascular endothelial growth receptor 2 and vascular endothelial cadherin in early EPCs were significantly lower than those in the late EPCs and HAECs (P<0.05), but no significant difference was found in the expression of von Willebrand factor and endothelial nitric oxide synthase (eNOS) between 2 type EPCs (P>0.05). The concentrations of vascular endothelial growth factor, granulocyte colony-stimulating factor, and interleukin 8 were significantly higher in the supernatant of early EPCs than late EPCs (P<0.05). Western blot assay indicated eNOS expressed in both types EPCs, while the expression of eNOS in late EPCs was significantly higher than early EPCs at 5 weeks (P<0.05). Both cell types could produce similar amount of NO (P>0.05). ConclusionThe expression of eNOS and the production of NO could be used as common biological features to identify EPCs, and the strategy of a combination of multiple methods for EPCs identification is more feasible.
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.
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.