Protein-resistant polymer surfaces

## Abstract Surfaces with resistance to non‐specific protein adsorption and a high capacity to bind plasminogen from plasma are developed for application as fibrinolytic surfaces in blood contact. A new method is reported for grafting poly(OEGMA__‐co‐__HEMA) copolymers on polyurethane surfaces. The

Novel polymer latexes were prepared that can be applied in several ways for the control and study of cell behavior on surfaces. Acrylic latexes with glass transitions ranging from -30 to 100°C were synthesized by dispersion polymerization in a water and alcohol solution using an amphiphilic comb cop

Synthetic materials capable of specifically recognizing proteins are important in separations, biosensors, and biomaterials. In this study, polysaccharide-like surfaces with tailored protein-binding nanocavities were prepared by a novel templating approach based on radiofrequency plasma deposition o

at later stages of the adsorption process proteins like high Competitive adsorption from a ternary mixture of human serum molecular weight kininogen dominated the adsorbed layer. albumin (HSA), human IgG, and human fibrinogen (Fgn) at con-This sequential adsorption is widely referred to as the Vroce