Fan Yonghong, Pan Xiaxin, Wang Ke, Wu Sisi, Han Honghong, Yang Ping, Luo Rifang, Wang Hong, Huang Nan, Tan Wei, Weng Yajun
Key Laboratory of Advanced Technologies of Materials, Ministry of Education, Southwest Jiaotong University, Chengdu 610031, China; School of Materials Science and Engineering, Southwest Jiaotong University, Chengdu 610031, China.
Department of Mechanical Engineering, University of Colorado at Boulder, Boulder, CO 80309, USA.
Colloids Surf B Biointerfaces. 2016 Sep 1;145:122-129. doi: 10.1016/j.colsurfb.2016.04.043. Epub 2016 Apr 26.
As nitric oxide (NO) plays vital roles in the cardiovascular system, incorporating this molecule into cardiovascular stents is considered as an effective method. In the present study, selenocystine with different chirality (i.e., l- and d-selenocystine) was used as the catalytic molecule immobilized on TiO2 films for decomposing endogenous NO donor. The influences of surface chirality on NO release and platelet behavior were evaluated. Results show that although the amount of immobilized l-selenocystine on the surface was nearly the same as that of immobilized d-selenocystine, in vitro catalytic NO release tests showed that l-selenocystine immobilized surfaces were more capable of catalyzing the decomposition of S-nitrosoglutathione and thus generating more NO. Accordingly, l-selenocystine immobilized surfaces demonstrated significantly increased inhibiting effects on the platelet adhesion and activation, when compared to d-selenocystine immobilized ones. Measurement of the cGMP concentration of platelets further confirmed that surface chirality played an important role in regulating NO generation and platelet behaviors. Additionally, using bovine serum albumin and fibrinogen as model proteins, the protein adsorption determined with quartz crystal microbalance showed that the l-selenocystine immobilized surface enhanced protein adsorption. In conclusion, surface chirality significantly influences protein adsorption and NO release, which may have significant implications in the design of NO-generating cardiovascular stents.
由于一氧化氮(NO)在心血管系统中发挥着至关重要的作用,将这种分子整合到心血管支架中被认为是一种有效的方法。在本研究中,具有不同手性的硒代胱氨酸(即L-和D-硒代胱氨酸)被用作固定在TiO2薄膜上的催化分子,用于分解内源性NO供体。评估了表面手性对NO释放和血小板行为的影响。结果表明,虽然表面固定的L-硒代胱氨酸的量与固定的D-硒代胱氨酸的量几乎相同,但体外催化NO释放试验表明,固定有L-硒代胱氨酸的表面更能催化S-亚硝基谷胱甘肽的分解,从而产生更多的NO。因此,与固定有D-硒代胱氨酸的表面相比,固定有L-硒代胱氨酸的表面对血小板的粘附和活化具有显著增强的抑制作用。血小板cGMP浓度的测定进一步证实,表面手性在调节NO生成和血小板行为中起着重要作用。此外,以牛血清白蛋白和纤维蛋白原为模型蛋白,用石英晶体微天平测定的蛋白吸附表明,固定有L-硒代胱氨酸的表面增强了蛋白吸附。总之,表面手性显著影响蛋白吸附和NO释放,这可能对产生NO的心血管支架的设计具有重要意义。