Analysis of disordered abrasive scratches on titanium surfaces and their impact on nuclear translocation of yes-associated protein.

The morphology of the metallic surface of an implant is important for its contact with bone tissue as it directly affects osteoblast functions, such as cell adhesion, proliferation, and differentiation. Firm contact between the implant and cells creates a barrier that prevents inflammation and bacterial infections. Therefore, optimizing surface morphology, such as surface roughness adjustments, is essential to improving the adhesion between the implant and cells for successful tissue regeneration. However, the manner in which the cells sense the surface roughness and morphology remains unclear. Previously, we analyzed cell adhesion behavior and observed that inhibited cell spreading can delay osteoblast functions. Therefore, assuming that the surface morphology can be sensed through cell spreading, we investigated the cell spreading area and yes-associated protein (YAP) localization in mouse osteoblasts (MC3T3-E1) on a titanium surface with disordered abrasive scratches. Surface roughness of 100-150 nm was obtained by polishing, which inhibited the cell spreading, indicating that YAP localization in the nucleus was lower than that on other surfaces. The obtained results indicate that the cells sense the surface environment based on their spreading area, which regulates cellular functions via the Hippo pathway.

Binding stability of peptides to Co-Cr-Mo alloy affects proliferation and differentiation of osteoblast.

Cobalt-chromium-molybdenum (CCM) alloys possess high corrosion-resistant properties as well as good mechanical properties. Hence, the alloys are employed in medical implants such as artificial knee and hip joints, coronary stents, and removable partial dentures. To improve the biocompatibility of CCM alloys, we reported that CCM-binding peptide (CBP) linked to cell-adhesive motif Arg-Gly-Asp (RGD) improved the attachment of endothelial cells on CCM alloys. However, the stability of CBP adsorption on the alloy and its effect on osteoblast compatibility are still unclear. In this study, we evaluated the stabilization of the adsorption layer of CBP-RGD on CCM alloy surface and investigated the effect of CBP-RGD peptide on the proliferation and differentiation of the osteoblasts. CBP-RGD layer exhibited higher stabilization than the RGD adsorption layer for 7 days. In addition, the proliferation of osteoblast on CBP-RGD adsorbed alloy higher than that on RGD adsorbed alloy. Moreover, the calcification of cells cultured on the CBP-RGD adsorbed alloy was significantly higher than that of the cells on RGD adsorbed alloy. These findings indicate that the CBP binding was stable during the culture of osteoblasts on the CCM alloy.