Objective To investigate the effect of Adenovirus-mediated averse vascular endothelial growth factor165(Ad-aVEGF165)on the growth of human melanoma cells(A375) in vivo and in vitro.Methods In vitro,the 100 multiplicity of infection of Aadenovirus-mediated green fluorescent protein(Ad-GFP)and Ad-aVEGF165 were transfected into human endothelium cell of vessel 304(ECV 304) and A 375. ECV 304 cells were divided into 3 groups: A 375 group, AdGFP group and AdaVEGF 165group. A375cells were also divided into 3 groups:1640 group, Ad-GFP group and AdaVEGF165 group. Their effects were analyzed by proliferation assay, cell cycle, and VEGF expression. In vivo,A375cells were injected into the axilla of the nude mouse. When the tumor formed, they were transplanted into another 15 mice. After treatment, the tumor was excised for naked eye observation, HE observation and microvascular density(MVD) counting. Results The cell supernatant fluid of A 375 group and AdGFP group could stimulate ECV304 cell growth,butthat of AdaVEGF165 group could inhibit the growth of ECV304 cell.All the A375cells in 3 groups had the proliferation trend, showing no statistically significant difference(Pgt;0.05). ECV 304 cell proliferation index(PI) in Ad-aVEGF165group reduced(Plt;0.05). There was no statistically significant difference(Pgt;0.05) in the PI of A 375 cell. The A 375cell integral optical densities were 234.41±13.8 in 1640 group, 222.73±3.67 in AdGFP group and 180.84±6.34 in Ad-aVEGF165group. The tumor volume in Ad-aVEGF165 group was smaller than that in Ad-GFP group and PBS group at 2 weeks after operation, the trend became much obvious with the time delay. AdaVEGF165 brought to much tissue necrosis under HE stain. The MVD of PBS group, Ad-GFP group and Ad-aVEGF165group were 65 10/view,52±11/view and 30±6/view, respectively. Conclusion In Vitro, Ad-VEGF 165gene could inhibited ECV304 cells’ growth by weakening VEGF expression of A 375cells. In vivo, Ad-aVEGF 165could inhibit the growth of human melanoma from blockinmicrovascular.
OBJECTIVE To review the fundamental research and the experimental study of vascular endothelial growth factor (VEGF). METHODS The laboratory information and experimental study of VEGF were extensively reviewed. RESULTS VEGF, as a mitogen specifically for endothelial cells, could bly stimulate angiogenesis as well as vascular permeability, especially in hypoxia state. Experimentally, survival area and viability of flaps could be increased significantly when exogenous VEGF was applied in the form of protein or cDNA. CONCLUSION VEGF provides a new way for therapeutic angiogenesis in reparative and reconstructive surgery.
Objective To establish the three diamension-model and to observe the contribution of endothelial progenitor cell (EPC) in the angiogenesis and its biological features. MethodsEPC was obtained from the rats’ peripheral blood. Its cultivation and amplification in vitro were observed, and the function of the cultural EPC in vitro was detected. The three diamension-model was established and analyzed. ResultsEPC was obtained from the peripheral blood successfully. The proliferation of the EPC which induced with VEGF(experimental group) was better than that without VEGF (control group) at every different phase (P<0.01). It was found that EPC grew into collagen-material from up and down in the three diamension-model, and its pullulation and infiltration into the collagen were seen on day 1 after cultivation. With the time flying, there were branch-like constructions which were vertical to the undersurface of collagen and interlaced to net each other. It showed that in experimental group the EPC grew fast, its infiltration and pullulation also were fast, the branch-like construction was thick. But in control group, the EPC grew slowly, infiltration and pullulation were slow, the branch-like construction was tiny and the depth of infiltration into collagen was superficial. The number of new vessels in experimental group was larger than that in the control group at every different phase (P<0.01). ConclusionRat tail collagen can induce EPC involved in immigration, proliferation and pullulation in angiogenesis. The three-diamension model of EPC can be used to angiogenesis research. VEGF can mobilize and induce EPC to promote the angiogenesis.
Abstract: Objective To study the pathophysiological mechanism of the morphological change of immature pulmonary vessels in the piglet model of congenital heart defect with decreased pulmonary blood flow established with balloon atrial septostomy and pulmonary artery banding. Methods Twenty piglets at an age of one to two months were divided into three groups with random number table. For the control group (group C,n=6), small incisions were carried out on the right chest to produce a transient reduction in the pulmonary blood; for the lowmedium pulmonary artery stenosis group (group T1, n=7), the balloon dilator was delivered through the surface of the right atrium and septostomy and pulmonary artery banding were performed, and the systolic transpulmonary artery banding pressure (Trans-PABP) was controlled to be 20.30 mm Hg; For the severe pulmonary artery stenosis group (group T2, n=7), the same surgical procedures with group T1 were performed while TransPABP was controlled to be more [CM(159mm]than 3050 mm Hg.At 2 months after surgery respectively,a lung tissue of 1.0 cm×0.8 cm×0.8 cm from the lateral segment of the right middle lobe was taken out to be observed under optic microscope. The morphological change of the distal arterioles was detected. Furthermore, the content of vascular endothelial growth factor (VEGF) and matrix metalloproteinase2( MMP2) were also examined by the method of enzymelinked immunosorbent assay (ELISA). Results The model was successfully established in all the survival piglets of the group T1 and group T2. Two months after operation, the inner diameter of the pulmonary arterioles in group T1 was significantly higher than that in group C (82.89±10.72 μm vs.74.12±9.28 μm;t=-5.892, Plt;0.05), so as group T2 (85.47±5.25 μm vs.74.12±9.28 μm;t=-6.325, Plt;0.05); the number of arterioles per square centimeter (NAPSC) of group T1 was significantly lower than that of the group C (229.70±88.00 entries/cm 2 vs. 431.50±40.60 entries/cm2; t=39.526, Plt;0.05), so as group T2 (210.00±40.30 entries/cm2 vs. 431.50±40.60 entries/cm2; t=67.858, Plt;0.05). Two months after operation, the lung expression of MMP -2 and VEGF in group T1 was significantly lower than that in group C (58.30±19.60 ng/ml vs. 81.20±16.70 ng/ml, t=14.261, Plt;0.05; 17.80±3.00 pg/ml vs. 21.40±3.80 pg/ml, t=8.482, P<0.05), so does group T2 (42.10±15.20 ng/ml vs. 81.20±16.70 ng/ml, t=27.318, P<0.05; 12.30±3.20 pg/ml vs. 21.40±3.80 pg/ml, t=15.139, P<0.05). Conclusion Structural remodeling of pulmonary extracellular matrix is an important feature of the piglet model of congenital heart defect with decreased pulmonary blood flow. The arterioles show significant hypoplasia or degradation. Change in the structural proteins and cytokines during the reduction of blood in the lung is the key to structural remodeling.
Objective To investigate the role of vascular endothelial growth factor ( VEGF) in the pathogenesis of emphysema and its relationship with tumor necrosis factor alpha ( TNF-α) . Methods 48 rats were randomly divided into four groups, ie. a normal control group, an emphysema group, a rhTNFR∶Fc intervention group, and a sham intervention group. The rats in the emphysema group, the rhTNFR: Fc intervention group, and the shamintervention group were exposed to cigarette smoking for 80 days. After 30 days of exposure, rhTNFR: Fc hypodermic injection was administered in the rhTNFR: Fc intervention group while placebo was injected in the sham intervention group as control. Lung tissue sections were stained by hematoxylin and eosin. Mean linear intercept ( MLI) and mean alveolar numbers ( MAN) were measured to estimate the extent of emphysema. The level of TNF-αin serumand BALF, and the level of VEGF in BALF were measured with ELISA. Results In the emphysema group, MLI was higher and MAN was lower than those in the normal control group. Moreover, the levels of TNF-αin serum and BALF were higher, and thelevel of VEGF in BALF was lower significantly ( P lt;0. 05) . After the intervention with rhTNFR∶Fc, MAN increased and the serum TNF-αdecreased significantly compared with the emphysema group ( P lt; 0. 05) .However there were no significant differences in MLI, VEGF, and TNF-α in BALF ( P gt; 0. 05 ) . No correlation was found between the level of TNF-αand VEGF in BALF in the emphysema group. Conclusion VEGF and TNF-αare related to the pathogenesis of emphysema of smoking rats, and may contribute to the development of emphysema in different pathways.
ObjectiveTo investigate the expression of vascular endothelial growth factor (VEGF) and proliferating cell nuclear antigen (PCNA) in colorectal cancer and its relationship with metastasis and recurrence. MethodsParaffinembedded specimens from 59 patients with colorectal cancer, 16 patients with adenomas and 12 normal colonic tissues were examined and compared by SP immunohistochemical method. ResultsThe positive rate of VEGF in colorectal cancer were significantly higher than that in adenomas (P<0.05). The positive rate of VEGF in Dukes A and B stage of colorectal cancer were significantly higher than those in Dukes C and D (P<0.05). Expression of VEGF in postoperative recurrence group was markedly higher than that in the group with no recurrence (P<0.05). Proliferative activity expression suggested that the poorer the differentiation, the more PCNA increased in case of lymphnode or hepatic metastasis. The PCNA showed marked difference between postoperative and nonpostoperative recurrences (P<0.05). Conclusion The expression of VEGF and PCNA is closely related to the invasion and metastasis of tumor during the operation. The increased VEGF and high PCNA implies that there may be some potential metastasis present.
Objective To study the expressions and clinical significance of matrix metalloproteinases-2 (MMP-2) and vascular endothelial growth factor-C (VEGF-C) in patients with papillary thyroid carcinoma (PTC). Methods SP immunohistochemical technique was used to detect the expressions of MMP-2 and VEGF-C in 78 cases of PTC and 18 cases of thyroid benign tumors.Results The positive expression rates of MMP-2 and VEGF-C in PTC (80.77%, 75.64%) were significantly higher than those of the thyroid benign tumor (11.11%, 22.22%), P<0.05. The expressions of MMP-2 and VEGF-C were correlated to the degree of infiltration and lymph node metastasis in PTC: In those which infiltrated to or over the thyroid capsular, or had clinical neck lymph node metastasis, the positive expression rates were significantly higher than those in the other cases which had confined invasion of thyroid capsular or non-clinical metastasis of neck lymph node (P<0.05). And during the follow-up of 41 patients who didn’t have clinical neck lymph node metastasis before operation, the positive expression rates of those who had clinical neck lymph node metastasis were significantly higher than those in the other patients who didn’t have neck lymph node metastasis (P<0.05). There was significantly positive correlation between the expressions of MMP-2 and VEGF-C in PTC (Gamma=0.846, P<0.05). Conclusions MMP-2 and VEGF-C may be used to distinguish malignant and benign thyroid tumor; The expressions of MMP-2 and VEGF-C are correlated with the degree of infiltration and neck lymph node metastasis in PTC; Combined detection of MMP-2 and VEGF-C will be more accurate to predict condition of lymph node metastasis.
bjective To investigate the correlation between expression of vascular endothelial growth factor(VEGF) of serum and tumor tissues and the clinical prognosis in patients with breast cancer. Methods The expressions of VEGF level of serum and tumor tissues in 44 patients with invasive duct breast cancer, 13 with benign breast diseases and 40 healthy controls. Serum VEGF level was measured by ELISA method. The protein expression of tissue VEGF, ER and C-erbB-2 were evaluated by immunohistochemistry LSAB method. Results Serum VEGF level and tissue VEGF expression in breast cancer were higher than those in benign breast diseases (P<0.001), and there was no significance in benign breast diseases and healthy controls (Pgt;0.05). VEGF expression was correlated with lymph node metastasis (P<0.01), ER and C-erbB-2 expression (P<0.05, P<0.01) and clinical stage (P<0.01). There were no statistical correlation between VEGF expression and age, tumor size (Pgt;0.05). Conclusion There is positively correlation between serum VEGF level and tissue VEGF expression, and between VEGF expression and clinic prognosis. Serum VEGF level may be one of important index of prognosis estimation in patients with breast cancer.
OBJECTIVE: To evaluate the effect of vascular endothelial growth factor(VEGF) 165 or basic fibroblast growth factor (bFGF), which was slowly-released in fibrin glue patch, on expanded prefabricated flaps in rabbits to facilitate the neoangiogenesis process. METHODS: A total of 53 rabbits were divided randomly into 6 groups. The central auricular vascular bundle of the ear was implanted into the expanded prefabricated flap as the pedicle. Fibrin glue, sandwiched between the expander and the implanted vessels, was adopted for topical delivering and slow-releasing of VEGF(625 ng) or bFGF(2880U). After 14 days, the island flap with the implanted vascular bundles as the pedicle was elevated, sutured back to its original position and then harvested more 3 days later. Neoangiogenesis was measured by digital recording of survival area, laser Doppler flowmetry, PCNA immunohistochemistry, TUNEL, ink and PbO infusions. RESULTS: When compared with the other groups, flap survival improved; neoangiogenesis of flaps increased, together with the blood flow enhanced in the groups applied growth factors. The reduced cellular apoptosis and the increased proliferation were also observed. CONCLUSION: VEGF or bFGF slowly-released by fibrin glue shows the potential to facilitate neoangiogenesis and accelerate maturation of the expanded prefabricated flap.