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Literature DB >> 31279063

Interaction of blood plasma proteins with superhemophobic titania nanotube surfaces.

Roberta Maia Sabino¹, Kirsten Kauk², Sanli Movafaghi³, Arun Kota⁴, Ketul C Popat⁵.

Abstract

The need to improve blood biocompatibility of medical devices is urgent. As soon as blood encounters a biomaterial implant, proteins adsorb on its surfaces, often leading to several complications such as thrombosis and failure of the device. Therefore, controlling protein adsorption plays a major role in developing hemocompatible materials. In this study, the interaction of key blood plasma proteins with superhemophobic titania nanotube substrates and the blood clotting responses was investigated. The substrate stability was evaluated and fibrinogen adsorption and thrombin formation from plasma were assessed using ELISA. Whole blood clotting kinetics was also investigated, and Factor XII activation on the substrates was characterized by an in vitro plasma coagulation time assay. The results show that superhemophobic titania nanotubes are stable and considerably decrease surface protein adsorption/Factor XII activation as well as delay the whole blood clotting, and thus can be a promising approach for designing blood contacting medical devices.

Entities: Chemical Disease Gene Species

Keywords: Factor XII; Fibrinogen; Hemocompatibility; Protein adsorption; Superhemophobic; Titania nanotubes

Mesh：

Substances：

Year: 2019 PMID： 31279063 PMCID： PMC6814547 DOI： 10.1016/j.nano.2019.102046

Source DB: PubMed Journal: Nanomedicine ISSN： 1549-9634 Impact factor: 5.307

44 in total

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