Objective:To investigate the relationship between the changes in extracellular vesicles (EVs) size distribution before and after cardiopulmonary bypass (CPB) cardiac surgery and postoperative coagulation function.Methods:A total of 103 patients undergoing cardiac surgery with CPB were enrolled. Venous blood samples were collected at preoperation, postoperative 12 h and 3 days. Additionally, 50 age- and gender-matched healthy volunteers served as a control group. EVs were isolated using gradient centrifugation, and their size distribution was assessed by dynamic light scattering (DLS). The relationship between EV size characteristics, including peak diameter, peak height, and interquartile range( IQR), and postoperative coagulation function was analyzed. Results:Compared to patients with normal postoperative coagulation function, those with postoperative coagulation dysfunction had lower size at peak and IQR, and significantly higher peak intensity. Logistic regression analysis indicated that elevated peak intensity and lower size at peak and IQR were risk factors for coagulation dysfunction. The area under the curve ( AUC) for diagnosing coagulation dysfunction with 12 h postoperative EVs peak intensity was 0.76, with a positive predictive value of 85% at the optimal cutoff of 8.2; the AUC for IQR was 0.84, with a sensitivity of 83%, specificity of 82%, and negative predictive value of 86% at the optimal cutoff of 125.05 nm. Conclusion:The size distribution of circulating EVs show a correlation with coagulation function after cardiac surgery with CPB and may serve as a novel biomarker to predict postoperative coagulation dysfunction.

Objective:To investigate the relationship between the changes in extracellular vesicles (EVs) size distribution before and after cardiopulmonary bypass (CPB) cardiac surgery and postoperative coagulation function.Methods:A total of 103 patients undergoing cardiac surgery with CPB were enrolled. Venous blood samples were collected at preoperation, postoperative 12 h and 3 days. Additionally, 50 age- and gender-matched healthy volunteers served as a control group. EVs were isolated using gradient centrifugation, and their size distribution was assessed by dynamic light scattering (DLS). The relationship between EV size characteristics, including peak diameter, peak height, and interquartile range( IQR), and postoperative coagulation function was analyzed. Results:Compared to patients with normal postoperative coagulation function, those with postoperative coagulation dysfunction had lower size at peak and IQR, and significantly higher peak intensity. Logistic regression analysis indicated that elevated peak intensity and lower size at peak and IQR were risk factors for coagulation dysfunction. The area under the curve ( AUC) for diagnosing coagulation dysfunction with 12 h postoperative EVs peak intensity was 0.76, with a positive predictive value of 85% at the optimal cutoff of 8.2; the AUC for IQR was 0.84, with a sensitivity of 83%, specificity of 82%, and negative predictive value of 86% at the optimal cutoff of 125.05 nm. Conclusion:The size distribution of circulating EVs show a correlation with coagulation function after cardiac surgery with CPB and may serve as a novel biomarker to predict postoperative coagulation dysfunction.

Objective: To construct and identify an overexpression recombinant adenovirus vector carrying the mouse PTG gene(NM＿016854), and to lay a foundation for in-depth study of the function of PTG. Methods: The coding sequence of the mouse PTG gene was chemically synthesized, amplified by polymerase chain reaction(PCR), digested with restriction enzymes, and inserted into the GV314 vector(CMV-MCS-3 FLAG-SV40-EGFP) to obtain the recombinant shuttle plasmid pGV314-PTG. BamHⅠ/AgeⅠ double enzyme digestion was further carried out, and the product was transferred into linearized expression vector pDC315 to construct recombinant adenovirus Ad-PTG, which was transfected into HEK293 T cells and packaged into recombinant virus particles. After repeated amplification of several generations of HEK293 T cells, the recombinant adenovirus was purified and titer detected. Finally, PCR, Western blot and sequencing were used to verify the recombinant adenovirus. Results: After PCR, Western blot and sequencing, the results showed that the pGV314-CMV-MCS-3 FLAG-SV40-EGFP-PTG overexpression adenovirus vector(Ad-PTG) was successfully constructed, and the virus titer measured by end-point dilution method was 4×1010PFU/ml, Western blot and RT-qPCR showed that the protein and mRNA expression levels of PTG increased significantly. Conclusion The recombinant adenovirus vector carrying mouse PTG gene is successfully constructed, and the expression of PTG gene in hepatocytes is effectively up regulated.