Laser Structured Dental Zirconium for Soft Tissue Cell Occupation-Importance of Wettability Modulation.
A Debrassi SmaczniakPhilip OsterSusanne SeemannFabian KruseJakob BriefJ Barbara NebePublished in: Materials (Basel, Switzerland) (2022)
Various approaches are being pursued to physico-chemically modify the zirconia neck region of dental implants to improve the integration into the surrounding soft tissue. In this study, polished zirconia discs were laser microstructured with periodic cavities and convex waves. These zirconia samples were additionally activated by argon plasma using the kINPen ® 09. The surface topography was characterized by scanning electron microscopy and the surface wettability by water contact angle. The in vitro study with human gingival fibroblasts (HGF-1) was focused on cell spreading, morphology, and actin cytoskeleton organization within the first 24 h. The laser-induced microstructures were originally hydrophobic (e.g., 60 µm cavities 138.4°), but after argon plasma activation, the surfaces switched to the hydrophilic state (60 µm cavities 13.7°). HGF-1 cells adhered flatly on the polished zirconia. Spreading is hampered on cavity structures, and cells avoid the holes. However, cells on laser-induced waves spread well. Interestingly, argon plasma activation for only 1 min promoted adhesion and spreading of HGF-1 cells even after 2 h cultivation. The cells crawl and grow into the depth of the cavities. Thus, a combination of both laser microstructuring and argon plasma activation of zirconia seems to be optimal for a strong gingival cell attachment.
Keyphrases
- induced apoptosis
- cell cycle arrest
- single cell
- endoplasmic reticulum stress
- cell therapy
- endothelial cells
- signaling pathway
- high resolution
- stem cells
- cell death
- electron microscopy
- mass spectrometry
- biofilm formation
- bone marrow
- induced pluripotent stem cells
- ionic liquid
- extracellular matrix
- liquid chromatography
- cell migration