Surface Engineering for Endothelium-Mimicking Functions to Combat Infection and Thrombosis in Extracorporeal Life Support Technologies.
Morgan AshcraftMark GarrenOrsolya Lautner-CsorbaVicente PinonYi WuDagney CrowleyJoseph HillYeniselis MoralesRobert BartlettElizabeth J BrisboisHitesh HandaPublished in: Advanced healthcare materials (2024)
Blood-contacting medical devices routinely fail from the cascading effects of biofouling towards infection and thrombosis. Nitric oxide (NO) is an integral part of endothelial homeostasis, maintaining platelet quiescence and facilitating oxidative/nitrosative stress against pathogens. Recently, it has been shown that the surface evolution of NO can mediate cell-cell interactions. However, this technique alone cannot prevent the biofouling inherent in device failure with dynamic blood-contacting applications. In this work, we propose an endothelium-mimicking surface design pairing controlled NO release with an inherently antifouling polyethylene glycol interface (NO+PEG). This simple, robust, and scalable platform develops surface-localized NO availability with surface hydration, leading to a significant reduction in protein adsorption as well as bacteria/platelet adhesion. Further in vivo thrombogenicity studies show a decrease in thrombus formation on NO+PEG interfaces, with preservation of circulating platelet and white blood cell counts, maintenance of activated clotting time, and reduced coagulation cascade activation. It is anticipated that this bio-inspired surface design will enable a facile alternative to existing surface technologies to address clinical manifestations of infection and thrombosis in dynamic blood-contacting environments. This article is protected by copyright. All rights reserved.