ACS Appl Mater Interfaces. 2018 Aug 1;10(30):25047-25055. doi: 10.1021/acsami.8b05917. Epub 2018 Jul 19.
Further studies aimed at examining the activity of different Cu(II)-ligand complexes to serve as electron-transfer mediators to prepare novel antimicrobial/thromboresistant nitric oxide (NO)-releasing intravenous catheters are reported. In these devices, the NO release can be modulated by applying different potentials or currents to reduce the Cu(II)-complexes to Cu(I) species which then reduce nitrite ions into NO within a lumen of the catheter. Four different ligands are compared with respect to NO generation efficiency and stability over time using both single- and dual-lumen silicone rubber catheters: N-propanoate- N, N-bis(2-pyridylethyl)amine (BEPA-Pr), N-propanoate- N, N-bis(2-pyridylmethyl)amine (BMPA-Pr), 1,4,7-trimethyl-1,4,7-triazacyclononane (MeTACN), and tris(2-pyridylmethyl)amine (TPMA). Of these, the Cu(II)BEPA-Pr and Cu(II)MeTACN complexes provide biomedically useful NO fluxes from the surface of the catheters, >2 × 10 mol·min·cm, under conditions mimicking the bloodstream environment. Cu(II)MeTACN exhibits the best stability over time with a steady and continuous NO release observed for 8 d under a nitrogen atmosphere. Antimicrobial experiments conducted over 5 d with NO-releasing catheters turned "on" electrochemically for only 3 or 6 h each day revealed >2 logarithmic units in reduction of bacterial biofilm attached to the catheter surfaces. The use of optimal Cu(II)-ligand complexes within a lumen reservoir along with high levels of nitrite ions can potentially provide an effective method of preventing/decreasing the rate of infections caused by intravascular catheters.
进一步的研究旨在考察不同的 Cu(II)-配体络合物作为电子转移介质的活性,以制备新型抗微生物/抗血栓形成的一氧化氮(NO)释放静脉导管。在这些装置中,通过施加不同的电位或电流将 Cu(II)-配合物还原为 Cu(I)物种,可以调节 NO 的释放,然后在导管内腔中将亚硝酸盐离子还原为 NO。使用单腔和双腔硅橡胶导管,比较了四种不同的配体在生成 NO 的效率和稳定性方面的差异:丙酸-N,N-双(2-吡啶基乙基)胺(BEPA-Pr)、丙酸-N,N-双(2-吡啶基甲基)胺(BMPA-Pr)、1,4,7-三甲基-1,4,7-三氮杂环壬烷(MeTACN)和三(2-吡啶基甲基)胺(TPMA)。其中,Cu(II)BEPA-Pr 和 Cu(II)MeTACN 配合物在模拟血流环境的条件下,从导管表面提供了有用的生物医学 NO 通量,超过 2×10 mol·min·cm。Cu(II)MeTACN 具有最佳的稳定性,在氮气气氛下持续和连续释放 8 天的情况下观察到稳定的 NO 释放。在每天仅电化学“开启”3 或 6 h 的条件下,用 NO 释放导管进行了为期 5 天的抗菌实验,发现附着在导管表面的细菌生物膜减少了超过 2 个对数单位。在管腔储液器中使用最佳的 Cu(II)-配体络合物和高浓度的亚硝酸盐离子可能为预防/减少血管内导管引起的感染提供一种有效的方法。