posted on 2022-10-20, 10:29authored byKamil Kopeć, Agata Ryżko, Roman Major, Hanna Plutecka, Justyna Wiȩcek, Grzegorz Pikus, Jakub W. Trzciński, Adrianna Kalinowska, Tomasz Ciach
Surface properties are crucial for medical device and
implant research
and applications. We present novel polycatecholamine coatings obtained
by oxidative polymerization of l-tyrosine, l-phenylalanine,
and 2-phenylethylamine based on mussel glue-inspired chemistry. We
optimized the reaction parameters and examined the properties of coatings
compared to the ones obtained from polydopamine. We produced polycatecholamine
coatings on various materials used to manufacture implantable medical
devices, such as polyurethane, but also hard-to-coat polydimethylsiloxane,
polytetrafluoroethylene, and stainless steel. The coating process
results in significant hydrophilization of the material’s surface,
reducing the water contact angle by about 50 to 80% for polytetrafluoroethylene
and polyurethane, respectively. We showed that the thickness, roughness,
and stability of the polycatecholamine coatings depend on the chemical
structure of the oxidized phenylamine. In vitro experiments showed
prominent hemocompatibility of our coatings and significant improvement
of the adhesion and proliferation of human umbilical vein endothelial
cells. The full confluence on the surface of coated polytetrafluoroethylene
was achieved after 5 days of cell culture for all tested polycatecholamines,
and it was maintained after 14 days. Hence, the use of polycatecholamine
coatings can be a simple and versatile method of surface modification
of medical devices intended for contact with blood or used in tissue
engineering.