In vitro biomineralization by osteoblast-like cells I. Retardation of tissue mineralization by metal salts

Title	In vitro biomineralization by osteoblast-like cells I. Retardation of tissue mineralization by metal salts
Publication Type	Journal Article
	1998
Authors	Morais, S, Sousa, JP, Fernandes, MH, Carvalho, GS
Journal	BiomaterialsBiomaterials
Volume	19
Issue	1-3Exeter, United Kingdom
Pagination	13 - 21
Date Published	1998///
	01429612 (ISSN)
	Absorption spectroscopy, alkaline phosphatase, animal cell, Animalia, Animals, article, ascorbic acid, atomic absorption spectrometry, balanced salt solution, Bioassay, Biocompatibility, biomaterial, Biomaterials, biomineralization, bone marrow cell, bone mineralization, Bovinae, Calcification, Physiologic, Calcium, calcium phosphate, Carbon, Cations, Cattle, Cell Division, cell proliferation, cell survival, cell viability, Cells, Cultured, Chromium, controlled study, Corrosion, dexamethasone, electrochemistry, enzyme activity, Enzyme kinetics, glycerol 2 phosphate, histochemistry, Iron, Kinetics, manganese, metal ion, Metal ions, Metals, molybdenum, Nickel, nonhuman, Oryctolagus cuniculus, osteoblast, Osteoblast cells, Osteoblast-like cells, Osteoblasts, Phosphates, priority journal, rabbit, Rabbits, serum, Silicon, Stainless steel, Steel corrosion, Tetrazolium Salts, Thiazoles, Tissue culture
	The cytocompatibility of stainless steel 316L (SS 316L) corrosion products was investigated with particular focus on the dose- and time-effect of electrochemically dissolved SS and the corresponding separate metal ions on osteogenic bone marrow derived cells. Type AISI 316L stainless steel (Fe 63.9%, Cr 18.0%, Ni 12.5%, Mo 2.8%, Si 1.2%, Mn 1.6% and C 0.025%, weight for weight) was anodically dissolved in Hank's Balanced Salt Solution (HBSS) and diluted to the following concentrations: 500 μgml
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