Along with the coming of aged society, the prevalence of heart valvular disease is significantly increasing, and the use of bioprosthetic valves for treating patients with severe valve disease has increased over the last two decades. As a consequence, a growing number of patients with surgical bioprosthesis degeneration is predicted in the near future. In this setting, valve-in-valve (ViV) transcatheter aortic/mitral valve replacement (TAVR/TMVR) has emerged as an alternative to redo surgery. A deep knowledge of the mechanism and features of the failed bioprosthetic heart valve is pivotal to plan an adequate procedure. Multimodal imaging is fundamental in the diagnostic and pre-procedural phases. The immediate and mid-term clinical and hemodynamic results have demonstrated the safety and feasibility of ViV techniques, but the development of these techniques faces several specific challenges, such as coronary obstruction, potential post-procedural mismatch and leaflet thrombosis. This article reviews the current status and prospects of ViV-TAVR technology in the treatment for biological valve degeneration, and suggests that ViV-TAVR should be promoted and implemented in existing medical centers with good surgical aortic valve replacement experience, so as to provide better treatment for patients.
Objective To investigate the effects of 1, 25-( OH) 2D3 on the expression of matrix metalloprotease-9 ( MMP-9) and nuclear factor κB ( NF-κB) activity in a murine model of chronic asthma. Methods BALB/ c mice were sensitized and challenged with ovalbumin to establish chronic asthmatic model. The animals were randomly divided into a control group, an asthma group and a VD group. Lung sections from the mice were stained by HE and Masson’s trichrome, respectively. Morphometric analysis of the stained sections was performed using computerized image analysis system. Nuclear translocation of NF-κB p65 was examined using Western blot. The level of IκBαwas detected with real-time quantitative PCR ( RTPCR) and Western blot. In addition, the expression of MMP-9 in both activity and mRNA level was detected by gelatin zymograph and RT-PCR, respectively. Results Prominent airway remodeling developed in the asthma group, including the inflammatory cell infiltration, subepithelial collagen deposition and increased airway smooth muscle mass. In contrast, 1, 25-( OH) 2D3 attenuated these established structural changes of the airways. Stimulation with OVA induced a 7. 87-fold increase in the MMP-9 activity compared with that in the control group, and 1, 25-( OH) 2D3 treatment only induced a 3. 46-fold increase in the MMP-9 activity compared with that in the control group ( P lt;0. 05) . The mRNA level of MMP-9 in the VD group ( 3.16 ± 0.09) was decreased compared with the asthma group ( 5.74 ±0.13) ( P lt;0.05) , but itwas still higher than that in the control group ( 0.57 ±0.08) ( P lt;0.05) . 1, 25-( OH) 2D3 reduced the nuclear translocation of NF-κB p65 while up-regulated the IκBα level in lung tissue of chronic asthma. Conclusions 1, 25- ( OH) 2D3 can inhibit the NF-κB activity and down-regulate the expression of MMP-9 in lung tissue of chronic asthma, thus alleviating the established chronic asthma-induced airway remodeling.
Abstract: Objective To investigate the effects of βreceptor blocker on intraventricular pressure gradient and left ventricle remodeling after valve replacement for critical aortic stenosis. Methods Fifty-six patients with critical aortic stenosis underwent aortic valve replacement surgery from January 2008 to January 2010 in the First Affiliated Hospital of Zhengzhou University. Thirtytwo of them who were followed up were selected to be enrolled in this study. The patients were divided into two groups under the same basis of clinical features. Twelve patients in the experimental group received oral βreceptor blocker (Metoprolol, 6.2525.00 mg once, twice daily). The rest 20 patients in the control group had no βreceptor blocker. The various indicators of ultrasound cardiogram (UCG) shortly after operation (within a week) and long after operation (6-24 months) were compared between the two groups. Results No death occurred in both groups, and chest distress, shortness of breath and other symptoms were obviously alleviated. Although left ventricular endsystolic dimension (LVESD) and left ventricular outflow tract dimension (LVOTD) of both groups increased 6-24 months after operation, compared with the early postoperative period, only the increase of LVOTD in the experimental group showed statistical difference (t=-47.937, P=0.001). In both groups, interventricular septum thickness (IVST), left ventricular posterior wall thickness (LVPWT), filament band velocity of left ventricular outflow tract (V), intraventricular pressure gradient (G) and left ventricular mass index (LVMI) of the later period after operation were significantly lower than those of the early postoperative period. All these indicators in the experimental group showed significant differences (t=7.781, P=0.001;t=5.749, P=0.001; t=2.637, P=0.023; t=7.167, P=0.001; t=100.061, P0.001), while only V, G, and LVMI showed statistical differences in the control group (t=4.051, P=0.001; t= 4.759, P= 0.001; t=-0.166,P=0.001). EF in the experimental group also indicated significant difference compared with early period after aortic valve replacement (t=-6.621, P=0.001). EF between two groups indicated no significant difference (t=-0.354,P=0.726). But differences between the two groups in LVEDD, IVS, G, and LVMI were all statistically significant in the later period after surgery (t=-2.494, P=0.018; t=-3.434, P=0.002;t=-2.171,P=0.038; t=-2.316, P=0.028). Conclusion β-receptor blocker is a safe and reliable drug for those patients who have undergone aortic valve replacement surgery for critical aortic stenosis, and can decrease significantly the residual intraventricular pressure gradient and accelerate left ventricular cardiac remodeling.
In order to identify whether the regeneration of costal cartilage is the basis of post-surgical repair of pectus excavatum and thoracic cage remodeling, 151 cases were followed up for 0.25 to 14 years. The main procedures in treatment were 3 steps: To curve the mental strut as a bow, to repair the perichondrium as a tube, and to persist in post-operative therapy. The results showed that regeneration of the costal cartilages appeared 3 months postoperatively in the cases treated by this method. It was concluded that a satisfactory thoracic cage could be remodeled by improving the technique of repairing pectus excavatum and persisting in postoperative therapy according to the regeneration regularity.
Objective To investigate the effects of tissue inhibitor-3 of matrix metalloproteinases(TIMP-3) genetransfected vascular smooth muscle cells(VSMCs) transplantation on heart structure after acute myocardial infarction (AMI) in rats and to explore the potential mechanisms. Methods Sixty-one female Wistar rats were produced AMI models by ligating the descending left coronary artery. Fifty-four rats were survived and divided into 3 groups randomly(n=18): 0.5 ml PBS containing 1×106 TIMP-3 gene-transfected VSMCs(group A), 1×106 VSMCs(group B) or 0.5 ml PBS without cell(group C) were injected into the ischemic myocardium immediately. Ischemic myocardium samples were harvested at 1 weekafter operation. The heart structure was observed through the tissue morphologic examination. The activity of TIMP-3 gene-transfected VSMCs were measured by immunohistochemical method. Proteins of TIMP-3 and matrix metalloproteinase 9(MMP-9) were determined by Western blot. Results VSMCs were cultivated and had a high purity(98%). TIMP-3 gene was transfected into VSMCs successfully. One week after operation in groups A, B and C, the average percentage of infarction myocardium size 〖KG6〗and left ventricle free wal area were 28.73%±1.56%, 39.63%±1.84% and 46.32%±2.16% separately.Group A was significantly lower than groups B and C(P<0.01), group B was significantly lower than group C(P<0.01). In groups A, B and C the averageleft ventricle volume indexes were 5.27±0.21 mm3/g, 6.69±0.34 mm3/g and 9.67±0.88 mm3/g respectively. Group A was significantly smaller than groups B and C(P<0.01), group B was significantly smaller than group C(P<0.01). The immunohistochemical observation confirmed that the implanted VSMCs and TIMP-3 gene were survival in ischemic area. The protein content of TIMP-3 in ischemicmyocardium was significantly higher in group A (300 704.8±3 692.8) than in groups B and C(195 548.8±3 014.2,177 991.1±2 502.1)(P<0.01), the protein content of MMP-9 in ischemic myocardium was significantly lower in group A(594 827.4±5 708.5) than in groups B and C(921 461.4±8 887.4,1 044 445.0±8 788.6)(P<0.01). Conclusion Implanted TIMP3 gene transfected VSMCs in ischemic myocardium can conspicuously reduce the myocardium remodeling after AMI.
OBJECTIVE: To study the characteristics of, morphology histology and ultrastructure of anterior cruciate ligament(ACL) autograft and two-step cryopreserved ACL allograft after transplantation. METHODS: Sixty New Zealand rabbits and sixty Japanese rabbits were randomly divided into two groups: ACL autograft group and two-step cryopreserved ACL allograft group. Immunosuppressant were not used after transplantation. The histology and ultrastructure of the ACL of transplantation and normal knee were observed after 4 weeks and 12 weeks, respectively. RESULTS: The rate of remodeling process was faster in ACL autograft than in two-step cryopreserved ACL allograft, but there was similar remodeling process between two groups 12 weeks after transplantation. The proportions of large-diameter fibers(gt; or = 80 nm) of ACL autograft and cryopreserved ACL allograft were 6% and 24% in the 4th week, and were 0 and 2% in the 12th week, respectively. The proportions of small-diameter of fibers(lt; 80 nm) of ACL autogrft and cryopreserved ACL allograft were 94% and 76% in the 4th week, and 100% and 98% in the 12th week, respectively. Histologic incorporation in ACL autograft was similar to that in cryopreserved ACL allograft. CONCLUSION: Two-step cryopreserved bone-ACL-bone allograft were similar to bone-ACL-bone autograft cryopreserved in remodeling process and histology. The rate of remodeling process was faster in ACL autograft than in cryopreserved ACL allograft.
Objective To observe the effects of fine particulate matter (PM2.5) on airway remodeling and Notch signaling pathway in mice with bronchial asthma, and explore the possible mechanism of its influence on airway remodeling in asthmatic mice. Methods Forty eight-week-old SPF female BALB/c mice were divided into a healthy control group, a healthy PM2.5 group, an asthma group and an asthma PM2.5 group by random number table, with 10 mice in each group. The asthma group and the asthma PM2.5 group were sensitized with ovalbumin to establish asthma mouse model, and the healthy PM2.5 group and the asthma PM2.5 group received aerosol inhalation of PM2.5 (510 μg/m3) after each provocation. After modeling, lung function was measured in each group. Hematoxylin and eosin staining and Masson staining were performed on the lung tissue sections of mice. Image analysis software was used to determine the circumference of the bronchial basement membrane, the total area of the bronchial wall, the area of bronchial smooth muscle and the area of collagen deposition. The expressions of Notch1, Hes1, α-smooth muscle actin (α-SMA), transforming growth factor-β1 (TGF-β1) and type Ⅰ collagen (Col-Ⅰ) were detected by immunohistochemistry and western blotting. The content of hydroxyproline (HYP) in lung tissue was determined by alkaline water method. Results The total airway wall area, airway smooth muscle area and collagen deposition area in the asthma group [(365.81±46.10), (132.80±20.14), (221.82±25.20) μm2/μm] were significantly higher than those in the healthy control group [(187.70±14.80), (89.73±8.49), (123.91±16.88) μm2/μm] (P<0.01). The healthy PM2.5 group [(244.62±42.86), (116.40±20.40), (174.91±57.41) μm2/μm] and the asthma PM2.5 group [(447.70±76.14), (236.14±36.35), (294.89±75.96) μm2/μm] were higher than those in the control group (all P<0.01). The expressions of Notch1, Hes1, α-SMA, TGF-β1 and Col-Ⅰ were strongly positive in the lung tissues of the asthmatic mice, but weak in the healthy control group. After PM2.5 intervention, compared with the control group, the expression intensity of the above molecules increased. Notch1 receptor and downstream Hes1 protein in the asthma group (0.86±0.10, 1.02±0.06) were significantly higher than those in the healthy control group (0.26±0.07, 0.56±0.09) (all P<0.01). The healthy PM2.5 group (0.44±0.06, 0.77±0.07) and asthma PM2.5 group (1.33±0.23, 1.25±0.18) were higher than the control group (all P<0.01). Airway remodeling related molecules α-SMA, TGF-β1 and Col-Ⅰ protein in the asthma group (0.60±0.04, 0.52±0.09, 0.36±0.04) were significantly higher than those in the healthy control group (0.31±0.03, 0.22±0.04, 0.23±0.04) (all P<0.01). The health PM2.5 group (0.49±0.02, 0.30±0.03, 0.28±0.03) and the asthma PM2.5 group (0.88±0.09, 0.62±0.03, 0.49±0.07) were higher than the control group (P<0.05 or P<0.01), respectively. The content of HYP in lung tissue of the asthma group (57.71±7.60) μg/100mg was significantly higher than that of healthy control group (40.53±5.73) μg/100mg. The healthy PM2.5 group (53.92±6.82) μg/100mg and asthma PM2.5 group (70.96±4.44) μg/100mg were higher than the control group (P<0.01), respectively. In asthma group and asthma PM2.5 group, the expression of Notch1 and Hes1 protein was positively correlated with the total airway wall area, airway smooth muscle area, collagen deposition area, α-SMA, TGF-β1, Col-Ⅰ and HYP (all P<0.01). Conclusion PM2.5 can promote early airway remodeling in asthma, and the activation of Notch signaling pathway may be involved in the promoting effect of PM2.5 on early airway remodeling.
ObjectiveTo preliminarily investigate morghological changes of rabbits reshaping ear cartilage assisted by microdissection needle and explore feasibility of new therapy for ear deformity.MethodsThe bilateral ears of 5 male New Zealand rabbits (aged, 5-6 months) were fixed maintaining the curvature and randomly divided into 2 groups (5 ears in each group). The ears were stimulated by microdissection needle in experimental group and were not treated with stimulation in control group. The skin reaction in the experimental group was observed immediately and at 4 weeks after stimulation. Then, the fixtures were removed at 4 weeks, and the shapes of the ears were observed. The cartilages were harvested from the ears to examined morphological changes after HE staining, and measured the chondrocyte layer thickness.ResultsAll rabbits survived until the end of the experiment. The skin has healed completely after 4 weeks in experimental group. After removing fixtures, the ears in the two groups all maintained certain forms momentarily; while 24 hours later, the ears in the control group mostly recovered original form, and the ears in the experimental group still maintained certain molding form until 8 weeks. HE staining showed there were smooth cartilage and uniform distribution of cells in the control group; the matrix staining was basically consistent; and the skin was normal appearance with epidermis, dermis, and cartilage of normal aspect. But the proliferation of chondrocyte with more layers of cells were observed in the experimental group. In addition, there were degeneration and injury of cartilage cells and connective tissue with necrotic cells and inflammatory cells at needle insertion sites. The chondrocyte layer thickness was (385.714±2.027) μm in the control group and (1 594.732±1.872) μm in the experimental group, there was significant difference between the two groups (t=–759.059, P=0.000).ConclusionRabbit ear cartilage can be effectively reshaped by microdissection needle. Proliferation of chondrocyte and changes in matrix can be found during the reshaping process.
Objective To investigate the change of vasa vasorum in vessel wall of varicose vein of the lower extre-mity. Methods Thirty-two patients with varicose vein of the lower extremity were collected, in which of 12 patients with simple varicose veins (varicose group), 9 patients with recurrent varicose veins (recurrent group), 11 patients withthrombophlebitis of varicose vein (thrombophlebitis group), 9 patients with normal venous tissue as control group. HE staining was performed to observe the distribution of vasa vasorum and detect the vasa vasorum density. Results The increasing vasa vasorums were observed in the adventitia and media, but few was observed in the intima in the varicose, recurrent, and thrombophlebitis groups. The distribution of vasa vasorum was in the adventitia in the control group. The vasa vasorum densities (/mm2) in the varicose, recurrent, and thrombophlebitis groups (5.65±1.45,6.20±1.73, and 5.94±1.63, respectively) were greater than those in the control group (2.87±0.54), the difference wasstatistically significant (P<0.05), but there was no significant difference of the vasa vasorum density among the varicosevein, recurrent, and thrombophlebitis groups (P>0.05). Conclusion Change of vasa vasorum is an important pathol-gical change with the nosogenis of varicose vein of the lower extremity.
ObjectiveTo observe the effect of metformin on airway remodeling in asthma and its possible mechanism.MethodsTwenty-eight B/N rats were randomly divided into control group, asthma group, metformin intervention group and rapamycin intervention group. After that, the asthma model was established and intervened with metformin and rapamycin. The airway resistance and airway reactivity were measured 48 hours after the last challenge, and then the lung tissue samples were collected. Histopathological examination was used to observe airway inflammatory cell infiltration, goblet cell proliferation, airway wall fibrosis and remodeling, as well as airway smooth muscle proliferation. The expression of AMPK/mTOR pathway related proteins was detected by Western blot.ResultsCompared with the asthma group, metformin and rapamycin significantly reduced the airway responsiveness induced by high concentration of acetylcholine (P<0.05), reduced the infiltration of inflammatory cells in lung tissue and the changes of airway wall structure (P<0.05), reduced goblet cell proliferation in airway epithelium, collagen fiber deposition in lung tissue and bronchial smooth muscle hyperplasia (P<0.05). Further studies showed that the effects of metformin and rapamycin were related to AMPK/mTOR pathway. Compared with the asthma group, metformin and rapamycin could significantly reduce the expression of p-mTOR, p-p70s6k1 and SKP2, while p21 protein expression was significantly increased (P<0.05). In addition, metformin and rapamycin had similar effects (P>0.05).ConclusionMetformin can alleviate airway hyperresponsiveness and airway remodeling by activating AMPK and then inhibiting mTOR pathway, which may be a potential drug for treating asthma and preventing airway remodeling.