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BACKGROUND@#Thymomas are the most common primary malignant tumors of anterior mediastinal. However, there are no specific laboratory indicator for the diagnosis the diagnosis of thymoma. The aim of this study was to screen out a tumor marker for diagnosis of thymoma by mRNA microarray analysis and confirmed it.@*METHODS@#By mRNA microarray analysis of 31 thymomas and peritumoral thymic tissues, we found that the transcription level of neuronal pentraxin 1 (NPTX1) gene was up-regulated more than 4 times in thymomas. To further verify the above results, we detected the transcription and expression level of NPTX1 in 60 thymoma and 30 thymic cyst patients by quantitative Real-Time polymerase chain reaction (PCR), immunohistochemistry and enzyme-linked immunosorbent assay (ELISA). Furthermore, the diagnostic value of NPTX1 in thymoma by receiver operating characteristic curve (ROC) was analyzed.@*RESULTS@#The transcription level of NPTX1 mRNA in thymoma tissues was significantly higher than that in the thymic tissues of control group [(2.88±1.02) vs (1.35±0.47), P<0.001); The expression level of NPTX1 in thymoma tissues was significantly higher than that in the thymic tissues of control group (2 vs 1, P<0.001); The preoperative serum level of NPTX1 protein in thymoma patients were significantly higher than that in the thymic cyst patients of control group [(1,018.29±209.38) pg/mL vs (759.95±66.02) pg/mL, P<0.001]; At the threshold of 842.22 pg/mL, sensitivity and specificity of NPTX1 as a serologic marker were 85.00% and 93.33%, respectively for thymoma. ROC showed that the area the under curve (AUC) of NPTX1 was 0.902.@*CONCLUSIONS@#NPTX1 was highly expressed in thymoma patients, and had diagnostic value for thymoma.
ABSTRACT
ObjectiveCardiopulmonary bypass (CPB) and its related ischemia reperfusion injury may cause endothelial cell injury.To study the protective effects of sodium ferulate in vascular endothelial function during CPB by testing the changes of vascular endothelial cell( CEC),nitric oxide( NO) and endothelin-1 ( ET-1 ) in children with congenital heart disease.MethodsSixty patients with congenital heart disease,including 28 males and 32 females were studied.The mean age was (19.7 ±10.4) months and body weight (10.5 ±6.1) kg.There were 37 VSD,8 ASD,7 TOF,5 TAPVC and 3 CAVC,among them 26 patients had pulmonary hypertension.They were randomly divided in to two groups:sodium ferulate group ( group S,n = 30),and control group ( group C,n =30) .Sodium ferulate (8 mg/kg) was given intravenously before CPB.Blood samples were taken from the arterial line at following time points:before CPB (TO),bypass 30 min(Tl ),the termination of CPB (T2 ),2h after operation ( T3 ) and 6h after operation ( T4 ),respectively for determination the concentration of vascular endothelial cell (CEC) in the blood,the concentration of nitric oxide (NO) and endothelin-1 ( ET-1) in the plasma.ResultsThere were no significant difference for the two groups regarding above parameters at TO ( P > 0.05).The level of CEC was significantly elevated after CPB in both groups ( P < 0.05 ) .CEC were lower at T2 in group S than in group C ( P < 0.05 ) .NO was decreased in both groups,but was higher in group S at T2,T3 and T4 ( P < 0.05 ) .The concentration of plasma ET-1 was not significantly different before CPB,but there was a slight decrease at T1,and then it was significantly increased in both groups (P<0.05).But it was lower in group S than in group C at T1,T2,T3 and T4(P<0.05 orP<0.01).ConclusionThere was severe endothelial cell damage during CPB.Sodium Ferulate can effectively antagonize the secretion of ET-1 to promote the formation of NO.Therefore,it reduces CPB-induced endothelial cell damage and protects vascular endothelial function during CPB.
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Objective To summarize experiences of surgical correction of aortopulmanary septal defect (APSD) in children. Methods Fifteen children with APSD,aged 5 months to 11 years,weighed 4.5 to 21.0kg,underwent surgical correction. Based on Richardson's classification,type I in 7 cases,type II in 3,and type III in 5. Eight cases were associated with other cardiac defects (53.5%),including 4 cases with complicated cardiac defects (26.7%). Operative technique included patch repair of defect in 8 cases with type I and II,an intraaotic synthetic baffle directed pulmonary blood from the APSD to the right pulmonary artery (RPA) in 3 cases with type III,an artificial conduit was used to connect the RPA with main pulmonary artery (MPA) and a flap of aortic wall was excised along with the anomalous RPA to extend the anastomosis in each case with type III,direct suture was used in 2 cases. Other associated cardiac defects were repaired simultaneously. Results The post-operative mortality rate was 6.7% (1/15). Eleven cases were followed-up from 3 months to 13 years in good condition. Conclusion APSD associated with complicated cardiac defects is apt to be misdiagnosed. Correct diagnosis can be made by 2-D echocardiography, cardiac catheterization angiography,and MRI. The operation should be done as early as possible once definite diagnosis is made. Operation should be done infancy to prevent development of pulmonary vascular disease. In type III APSD and APSD associated with complicated cardiac defects,operative mortalith is high. Preoperative accurate diagnosis and full understanding of the pathophysiology are the keys to an optimal surgical correction.