Saqib, MuhammadMuhammadSaqibBeshchasna, NataliaNataliaBeshchasnaPelaccia, RiccardoRiccardoPelacciaRoshchupkin, AntonAntonRoshchupkinYanko, IlyaIlyaYankoHusak, YevheniiaYevheniiaHusakKyrylenko, SergiySergiyKyrylenkoReggiani, BarbaraBarbaraReggianiCuniberti, GianaurelioGianaurelioCunibertiPogorielov, MaksymMaksymPogorielovOpitz, JörgJörgOpitzOrazi, LeonardoLeonardoOrazi2022-11-142022-11-142022https://publica.fraunhofer.de/handle/publica/42865210.1016/j.surfin.2022.102365Laser-Induced Periodic Surface Structures (LIPSS) holds great potential for regenerative biomedicine. Creating highly precise LIPSS enables to generate biomimetic implant surfaces with improved properties. The present study focuses on the fabrication and investigation of laser-treated stainless steel samples with applied linear LIPSS patterns with grooves made by means of a picosecond laser system using wavelengths of 1064 nm and 532 nm. To investigate properties of the laser-treated surfaces and to understand the basics of cell-surface interactions between the LIPSS and human Umbilical Cord Mesenchymal Stem Cells (UCMSC), flat stainless steel samples with various applied nanopatterns were used. Such LIPSSs demonstrated higher surface roughness, good biocompatibility, lower wettability and higher corrosion resistance compared to the untreated (polished) specimens. The surface roughness of laser-treated samples was in microscale that enabled adhesion and migration of endothelial cells, thus increasing the likelihood for endothelialisation. This thereby could reduce the chances for the development of Late Stent Thrombosis (LST) and In-Stent Restenosis (ISR). Furthermore, laser textured surfaces demonstrated an environment supportive for cell attachment, proliferation and alignment with the nanogroves. Therefore, application of the biomimetic nanopatterns could help to overcome frequent post-surgery complications after the stent implantation.enTailoring surface properties, biocompatibility and corrosion behavior of stainless steel by laser induced periodic surface treatment towards developing biomimetic stentsjournal article