| Title |
Single step nanosecond laser structuring for cost effective functional titanium surfaces with topography driven preosteoblast adhesion |
| Authors |
Barylyak, Adriana ; Meskinis, Sarunas ; Lazauskas, Algirdas ; Krzemiński, Piotr ; Wojnarowska-Nowak, Renata ; Trzyna-Sowa, Małgorzata ; Trzaskowska, Marta ; Vivcharenko, Vladyslav ; Cieniek, Bogumił ; Przekora, Agata ; Dziedzic, Andrzej ; Bobitski, Yaroslav ; Kisała, Joanna |
| DOI |
10.1038/s41598-026-38369-y |
| Full Text |
|
| Is Part of |
Scientific reports.. Berlin : Springer. 2026, vol. 16, art. no. 7104, p. 1-13.. ISSN 2045-2322 |
| Keywords [eng] |
Biocompatibility ; Cell adhesion ; Laser surface modification ; Nanosecond laser ; Roughness ; Wettability |
| Abstract [eng] |
Early bone formation around implants depends on both the chemical composition and the micro-, nanoscale architecture of the implant surface. Nanoscale modifications can accelerate osseointegration, and laser processing offers a versatile method of creating such features. In this study, titanium substrates were modified using a single-step nanosecond laser treatment at two energy regimes (1.95 mJ/pulse for P_0.5; 4.00 mJ/pulse for P_0.4). The resulting surfaces were characterized by SEM, EDS, XRD, Raman spectroscopy, ToF-SIMS, contact angle, and topography measurements, with biological assessment performed using a mouse preosteoblast cell line. Analyses revealed various titanium oxo clusters (TiO3-, TiO2-, TiO-) and moderate oxidation levels (25-31 at% O). Both laser regimes produced rough, hydrophobic surfaces. Cytotoxicity tests confirmed that the materials were non-toxic, and proliferation assays showed increasing preosteoblast numbers over time, indicating that both surfaces supported cell division. Good adhesion of preosteoblasts was observed on P_0.4 and P_0.5. This work demonstrates that nanosecond laser processing alone can generate micro-, nanostructured titanium implant surfaces with favourable biocompatibility, achieving performance comparable to more complex femtosecond methods while offering a cost-effective and scalable surface engineering strategy. |
| Published |
Berlin : Springer |
| Type |
Journal article |
| Language |
English |
| Publication date |
2026 |
| CC license |
|
