Hydrolytic instability of laser-ablatively deposited CaSi2 coatings in air and neutral water affects the behavior of bone healing-related cell types

Calcium silicide (CaSi2) instability in humid air or pH-neutral water remains unknown, although the topochemical formation of silicene from CaSi2 in various aqueous phases is a well-known process. Here we report on laser ablation of CaSi2 in the vacuum and ethanol, characterize coatings deposited on...

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Bibliographic Details
Published in:Surfaces and interfaces 2024-12, Vol.55, p.105381, Article 105381
Main Authors: Křenek, Tomáš, Pola, Josef, Stich, Theresia, Pattappa, Girish, Docheva, Denitsa, Koštejn, Martin, Medlín, Rostislav, Mikysek, Petr, Jandová, Věra, Pola, Michal, Kovářík, Tomáš, Cassel, Júlia, Holzman, Martin, Moskal, Denys
Format: Article
Language:English
Subjects:
Bioactivity
biocompatibility
Calcium silicide
CaSi2 hydrolysis
HUVECs
Laser ablation in a vacuum
Laser ablation in liquid
Macrophages
Mesenchymal stromal cells
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Summary:Calcium silicide (CaSi2) instability in humid air or pH-neutral water remains unknown, although the topochemical formation of silicene from CaSi2 in various aqueous phases is a well-known process. Here we report on laser ablation of CaSi2 in the vacuum and ethanol, characterize coatings deposited on titanium substrates with electron microscopy, X-ray photoelectron, Raman, and infrared spectroscopy, and examine the instability of the deposited coatings in humid air and neutral water. We further investigate the behavior of human mesenchymal stromal cells (hMSCs), vascular cells (HUVECS, human umbilical vein endothelial cells), and macrophages (derived from THP-1 cell line) in contact with the deposited coatings submerged in cell culture medium. The observed results indicate that the CaSi2 coatings undergo topochemical conversion to silicene, which is accompanied by hydrolytic reactions leading to inorganic Ca compounds and SiO2, and that the response of all cell types in the hydrolyzed CaSi2 surface domain is negatively affected by the nature of the hydrolytic products. In contrast, cells showed a tendency for enhanced biocompatibility towards the CaSi2 particles ablated in the vacuum. The results suggest that coating approaches can significantly influence cell behavior outcomes. Laser ablation of metastable and hydrolytic CaSi2 in the vacuum and in the liquid onto smooth and textured titanium surfaces and unique comparison of used routes for surface modification and their influence evaluation onto bone regeneration performance. [Display omitted]
ISSN:2468-0230
DOI:10.1016/j.surfin.2024.105381