Nickel release and surface characteristics of fine powders of nickel metal and nickel oxide in media of relevance for inhalation and dermal contact

Wang

et al. 2013

J Mater Sci: Mater Med

106

141

Implantation using stainless steels (SS) is an example where an understanding of protein-induced metal release from SS is important when assessing potential toxicological risks. Here, the protein-induced metal release was investigated for austenitic (AISI 304, 310, and 316L), ferritic (AISI 430), and duplex (AISI 2205) grades in a phosphate buffered saline (PBS, pH 7.4) solution containing either bovine serum albumin (BSA) or lysozyme (LSZ). The results show that both BSA and LSZ induce a significant enrichment of chromium in the surface oxide of all stainless steel grades. Both proteins induced an enhanced extent of released iron, chromium, nickel and manganese, very significant in the case of BSA (up to 40-fold increase), whereas both proteins reduced the corrosion resistance of SS, with the reverse situation for iron metal (reduced corrosion rates and reduced metal release in the presence of proteins). A full monolayer coverage is necessary to induce the effects observed.Electronic supplementary materialThe online version of this article (doi:10.1007/s10856-013-4859-8) contains supplementary material, which is available to authorized users.

Section: Resultssupporting

confidence: 57%

Surface-protein interactions on different stainless steel grades: effects of protein adsorption, surface changes and metal release

Wang

et al. 2013

J Mater Sci: Mater Med

106

141

“…30 (4) Delayed release of metals (from grade AISI 304) in the presence of albumin, 23 which is typical for ligandinduced dissolution due to the relatively slow detachment step. 58,92,93 (5) Enhanced release of metals and enrichment of Cr in the surface oxide (grade AISI 316L) at increased albumin solution concentrations, despite the lack of significant change of the thickness and structure of the adsorbed albumin layer at albumin concentrations in solution above a threshold value. 38 This indicates that measured amounts of released metals in solution, at least to some extent, also involve surface-solution exchanged albumin.…”

Section: Protein-induced Metal Releasementioning

confidence: 99%

Metal release from stainless steel in biological environments: A review

Wallinder

2015

Biointerphases

Self Cite

Due to its beneficial corrosion resistance, stainless steel is widely used in, e.g., biomedical applications, as surfaces in food contact, and for products intended to come into skin contact. Low levels of metals can be released from the stainless steel surface into solution, even for these highly corrosion resistant alloys. This needs to be considered in risk assessment and management. This review aims to compile the different metal release mechanisms that are relevant for stainless steel when used in different biological settings. These mechanisms include corrosion-induced metal release, dissolution of the surface oxide, friction-induced metal release, and their combinations. The influence of important physicochemical surface properties, different organic species and proteins in solution, and of biofilm formation on corrosion-induced metal release is discussed. Chemical and electrochemical dissolution mechanisms of the surface oxides of stainless steel are presented with a focus on protonation, complexation/ligand-induced dissolution, and reductive dissolution by applying a perspective on surface adsorption of complexing or reducing ligands and proteins. The influence of alloy composition, microstructure, route of manufacture, and surface finish on the metal release process is furthermore discussed as well as the chemical speciation of released metals. Typical metal release patterns are summarized.

Environ. Sci.: Processes Impacts

“…25 Comparison studies of predominantly oxidic nickel particulate matter found that the Zatka method over-reported the amount of metallic nickel and under-reported the amount of oxidic nickel where the XANES analysis identied no Ni 0 . It is known that Ni powders have thin oxide surfaces that occur as the powders are passivated during formation.…”

Section: Papermentioning

confidence: 99%

Comparison of nickel speciation in workplace aerosol samples using sequential extraction analysis and X-ray absorption near-edge structure spectroscopy

Loon

Throssell

Dutton

2015

There is a pressing need to further develop speciation knowledge of Ni workplace aerosols as the Zatka sequential extraction method used until now to speciate workplace Ni exposures has limitations. Here we compare the Zatka and XANES methods and evaluate XANES spectroscopy as a more appropriate and accurate technique for identifying nickel species in workplace aerosols. XANES spectroscopy is capable of identifying unique Ni species in the unaltered samples. Our findings indicate some significant departures in speciation assignment between the Zatka and XANES methods. In particular, the Zatka method can overestimate the soluble Ni fraction and it may underestimate the sulphidic and metallic fractions in some samples. Of particular importance, XANES is able to identify component sulphidic species. This information can lead to more accurate exposure matrices and more refined epidemiological analysis of respiratory cancer causation in sulphidic Ni processing.