Abstract
Plasma modification of soft polymeric surfaces has many prospects in creating biomedical devices. The deformability of the obtained coatings should be studied, as the usage of such materials implies mechanical loads. Polyurethane (a two-phase synthetic polymer) treated in argon/acetylene plasma, with post-treatment in argon plasma, was investigated. A carbon-containing nanocoating (discontinuous mesh-like structures) with structural–mechanical inhomogeneities is formed by the action of Ar/C2H2 plasma. The heterogeneities of the coating are due to the complex structure of the initial substrate and short duration of treatment; as the treatment time increases, the coatings become homogeneous, but their stiffness rises. The treated surfaces in the uniaxial tensile state have micro and/or nanocracks in certain cases of plasma treatment. This is associated with an increased elastic modulus of the coatings. The coatings without cracks have regions with sufficiently alternating stiffness. Post-treatment in argon plasma increases wettability and free surface energy, positively affecting the adsorption of albumin. The stiffness of such coatings increases, becoming more homogeneous, which slightly reduces their crack resistance. Thus, plasma coatings on soft polymers operating under mechanical loads without causing damage should have sufficiently low stiffness, and/or structural-mechanical heterogeneities that provide redistribution of stress.
Highlights
Introduction iationsTo date, a sufficient number of methods of plasma modification of polymers, for improving their biomedical characteristics, have been proposed
The aim of this work was to study the changes in the surface properties of polyurethane under the action of argon/acetylene plasma; as a result, carbon-containing nanostructures are formed on the surface
Elastic polyurethane is a synthetic two-phase polymer that is widely used in various applications
Summary
Introduction iationsTo date, a sufficient number of methods of plasma modification of polymers, for improving their biomedical characteristics, have been proposed. The treatment affects wettability, free surface energy, chemical structure, and surface topography. Sorption of “good” proteins (e.g., albumin [1,2]) can be improved, which, in turn, affects cell adhesion [3,4]; in certain cases, the amount of “bad” proteins, such as fibrinogen, responsible for thrombosis, is reduced [5,6]. Under certain treatment conditions, when the elastic modulus of the modified layer exceeds that of the polymer material, the surface loses its stability, forming a wrinkled topography. The chaotic structure of the wrinkles has a positive antibacterial effect [10].
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