The nature of the surface strongly influences the composition and recognisability of the adsorbed protein layer, which in turn affects the subsequent cellular interactions. Thus, to understand the biological response to a material, especially in vitro, one must fully understand the nature of the adsorbed protein film that forms on the material. This study is to investigate the fundamental interactions between the human serum albumin (no-cell adhesive) and human plasma fibronectin and bioinert ceramic following the CO2 laser treatment. The analysis of the albumin and fibronectin adsorption was conducted on the untreated and CO2 laser modified magnesia partially stabilised zirconia (MgO-PSZ) bioceramic using an ellipsometry. It was found that the adsorptions of albumin and fibronectin were influenced by the surface properties. The albumin adsorption was affected by the surface roughness and wettability characteristics of the MgO-PSZ and decreased with these properties. While the fibronectin adsorption was increased with wettability characteristic and predominantly governed by this property. Moreover, the considerable change in the  polar component of surface energy, γsvp, and its effect on protein adsorption implied that the albumin and fibronectin adsorption on the MgO-PSZ surfaces was probably due to the polar and chemical interactions. The value of this work is to provide a novel technique and useful information for mediating protein adsorption and thereof cellular interactions.

Topics
Fundamental interactions, Metal oxides, Transition metals, Experimental serum, Proteins, Laser treatment, Bioceramic, Ceramics
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