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전기전도성 고분자 위에 고정된 압타머에 흡착된 테트라브롬페놀프탈레인 에틸 에스테르를 이용한 트롬빈 검출
정새로미,노희복,심윤보,Chung, Saeromi,Noh, Hui-Bog,Shim, Yoon-Bo 한국전기화학회 2016 한국전기화학회지 Vol.19 No.4
새로운 산화환원 표지자를 이용한 압타머 기반의 전기화학적 트롬빈 검출 바이오 센서를 개발하였다. 1차 지방족 아민(primary aliphatic amine) 으로 개질한 압타머를 전기 전도성 고분자 poly-(5,2':5',2"-terthiophene-3'-carboxylic acid) (polyTTCA) 층 위에 공유결합을 통해 고정하여 센서 표면을 개질하였다. Tetrabromophenolphthalein ethyl ester (KTBPE)를 압타머와 상호 작용시켜 전기화학적인 산화환원 표지자로 사용하였다. 압타머로 개질한 층 위에 KTBPE의 산화반응을 differential pulse voltammetry (DPV)를 사용하여 조사하였으며, 최종 센서의 특성은 voltammetry, QCM, and ESCA 를 사용하여 조사하였다. KTBEF와 압타머 센서와 반응 후, KTBPE의 산화 피크는 감소하였다. 센서의 선형 동적 범위는 10.0 ~ 100.0 nM 이었으며, 이 때 검출 한계는 $1.0{\pm}0.2nM$이었다. An aptamer-based biosensor using a new redox indicator has been examined for the electrochemical detection of thrombin. The aptamer modified primary aliphatic amine was covalently immobilized onto poly-(5,2':5',2"-terthiophene-3'-carboxylic acid) (polyTTCA) layer. Tetrabromophenolphthalein ethyl ester (KTBPE) was interacted to aptamer and used as an electrochemical indicator. Prior to the detection, the oxidation reaction of KTBPE onto aptamer modified layer was also investigated using differential pulse voltammetry. The characterization of the final sensor (KTBPE/aptamer -polyTTCA) was performed by voltammetry, QCM, and ESCA. After binding of thrombin onto KTBPE/aptamer based sensor, the peak signal of KTBPE was gradually decreased. The sensor exhibited a dynamic range between 10.0 and 100.0 nM with the detection limit of $1.0{\pm}0.2nM$.
Valved Conduit with Glutaraldehyde-Fixed Bovine Pericardium Treated by Anticalcification Protocol
임홍국,김기범,정새로미,김용진 대한흉부외과학회 2014 Journal of Chest Surgery (J Chest Surg) Vol.47 No.4
Background: A preclinical study was conducted for evaluating a valved conduit manufactured with a glutaraldehyde (GA)-fixed bovine pericardium treated using an anticalcification protocol. Methods: Bovine pericardia were decellularized, fixed with GA in an organic solvent, and detoxified. We prepared a valved conduit using these bovine pericardia and a specially designed mold. The valved conduit was placed under in vitro circulation by using a mock circulation model, and the durability under mechanical stress was evaluated for 2 months. The valved conduit was implanted into the right ventricular outflow tract of a goat, and the hemodynamic, radiologic, histopathologic, and biochemical results were obtained for 6 months after the implantation. Results: The in vitro mock circulation demonstrated that valve motion was good and that the valved conduit had good gross and microscopic findings. The evaluation of echocardiography and cardiac catheterization demonstrated the good hemodynamic status and function of the pulmonary xenograft valve 6 months after the implantation. According to specimen radiography and a histopathologic examination, the durability of the xenografts was well preserved without calcification at 6 months after the implantation. The calcium and inorganic phosphorus concentrations of the explanted xenografts were low at 6 months after the implantation. Conclusion: This study demonstrated that our synergistic employment of multiple anticalcification therapies has promising safety and efficacy in the future clinical study.