Ultrafast Laser Processing of Nanostructured Patterns for the Control of Cell Adhesion and Migration on Titanium Alloy.
Antoine KlosSedao XxxTatiana E ItinaClémentine Helfenstein-DidierChristophe DonnetSylvie PeyrocheLaurence VicoAlain GuignandonVirginie DumasPublished in: Nanomaterials (Basel, Switzerland) (2020)
Femtosecond laser texturing is a promising surface functionalization technology to improve the integration and durability of dental and orthopedic implants. Four different surface topographies were obtained on titanium-6aluminum-4vanadium plates by varying laser processing parameters and strategies: surfaces presenting nanostructures such as laser-induced periodic surface structures (LIPSS) and 'spikes', associated or not with more complex multiscale geometries combining micro-pits, nanostructures and stretches of polished areas. After sterilization by heat treatment, LIPSS and spikes were characterized to be highly hydrophobic, whereas the original polished surfaces remained hydrophilic. Human mesenchymal stem cells (hMSCs) grown on simple nanostructured surfaces were found to spread less with an increased motility (velocity, acceleration, tortuosity), while on the complex surfaces, hMSCs decreased their migration when approaching the micro-pits and preferentially positioned their nucleus inside them. Moreover, focal adhesions of hMSCs were notably located on polished zones rather than on neighboring nanostructured areas where the protein adsorption was lower. All these observations indicated that hMSCs were spatially controlled and mechanically strained by the laser-induced topographies. The nanoscale structures influence surface wettability and protein adsorption and thus influence focal adhesions formation and finally induce shape-based mechanical constraints on cells, known to promote osteogenic differentiation.
Keyphrases
- mesenchymal stem cells
- biofilm formation
- cell adhesion
- bone marrow
- endothelial cells
- aqueous solution
- staphylococcus aureus
- protein protein
- pseudomonas aeruginosa
- binding protein
- stem cells
- oxidative stress
- high speed
- cell cycle arrest
- blood flow
- atomic force microscopy
- ionic liquid
- heat stress
- signaling pathway
- soft tissue