nitinol and nickel-monoxide

nitinol has been researched along with nickel-monoxide* in 2 studies

Other Studies

2 other study(ies) available for nitinol and nickel-monoxide

Article	Year
The role of surface oxide thickness and structure on the corrosion and nickel elution behavior of nitinol biomedical implants. Journal of biomedical materials research. Part B, Applied biomaterials, 2021, Volume: 109, Issue:9 Biocompatibility is an important factor for metallic medical device implants, and corrosion resistance of implantable alloys is one aspect of biocompatibility. Corrosion behavior of nitinol is strongly dependent upon the nature of the surface oxide, which forms during processing. The surface oxide is comprised of a mixture of titanium and nickel oxides, and subsequent thermal exposure (e.g., during shape setting) and surface removal (e.g., electropolishing, mechanical polishing, etching, etc.) influence its structure. Corrosion behavior is often assessed through testing methods such as cyclic potentiodynamic polarization (e.g., ASTM F2129) and nickel ion release. Studies have suggested that a correlation exists between oxide thickness and nickel ion release, with thicker oxides eluting more nickel. It is hypothesized that the composition of the surface oxide, and not only its thickness, influences the corrosion performance of nitinol. To investigate this, nitinol wire samples were processed to produce surface oxides with different structures both in terms of thickness and composition. These samples were tested per ASTM F2129 and nickel ion release testing. Topics: Alloys; Biocompatible Materials; Cations, Divalent; Corrosion; Equipment and Supplies; Humans; Materials Testing; Nickel; Prostheses and Implants; Surface Properties; Titanium	2021
Polystyrene formation on monolayer-modified nitinol effectively controls corrosion. Langmuir : the ACS journal of surfaces and colloids, 2008, Oct-07, Volume: 24, Issue:19 A surface-initiated polymerization of styrene on carboxylic acid terminated phosphonic monolayers was utilized to increase the corrosion resistance of nitinol and nickel oxide surfaces. Alkyl chain ordering, organic reactions, wettability, and film quality of the monolayers and polymers were determined by infrared spectroscopy, atomic force microscopy, matrix-assisted laser desorption ionization spectrometry, and water contact angles. The polystyrene film proved to be a better corrosion barrier than phosphonic acid monolayers by analysis with cyclic voltammetry and electrochemical impedance spectroscopy. The protection efficiency of the polystyrene film on nitinol was 99.4% and the monolayer was 42%. Topics: Alloys; Corrosion; Electrochemistry; Microscopy, Atomic Force; Molecular Structure; Nickel; Polystyrenes; Spectrophotometry, Infrared; Surface Properties	2008

Article

Year

The role of surface oxide thickness and structure on the corrosion and nickel elution behavior of nitinol biomedical implants.

Journal of biomedical materials research. Part B, Applied biomaterials, 2021, Volume: 109, Issue:9

Biocompatibility is an important factor for metallic medical device implants, and corrosion resistance of implantable alloys is one aspect of biocompatibility. Corrosion behavior of nitinol is strongly dependent upon the nature of the surface oxide, which forms during processing. The surface oxide is comprised of a mixture of titanium and nickel oxides, and subsequent thermal exposure (e.g., during shape setting) and surface removal (e.g., electropolishing, mechanical polishing, etching, etc.) influence its structure. Corrosion behavior is often assessed through testing methods such as cyclic potentiodynamic polarization (e.g., ASTM F2129) and nickel ion release. Studies have suggested that a correlation exists between oxide thickness and nickel ion release, with thicker oxides eluting more nickel. It is hypothesized that the composition of the surface oxide, and not only its thickness, influences the corrosion performance of nitinol. To investigate this, nitinol wire samples were processed to produce surface oxides with different structures both in terms of thickness and composition. These samples were tested per ASTM F2129 and nickel ion release testing.

Topics: Alloys; Biocompatible Materials; Cations, Divalent; Corrosion; Equipment and Supplies; Humans; Materials Testing; Nickel; Prostheses and Implants; Surface Properties; Titanium

2021

Polystyrene formation on monolayer-modified nitinol effectively controls corrosion.

Langmuir : the ACS journal of surfaces and colloids, 2008, Oct-07, Volume: 24, Issue:19

A surface-initiated polymerization of styrene on carboxylic acid terminated phosphonic monolayers was utilized to increase the corrosion resistance of nitinol and nickel oxide surfaces. Alkyl chain ordering, organic reactions, wettability, and film quality of the monolayers and polymers were determined by infrared spectroscopy, atomic force microscopy, matrix-assisted laser desorption ionization spectrometry, and water contact angles. The polystyrene film proved to be a better corrosion barrier than phosphonic acid monolayers by analysis with cyclic voltammetry and electrochemical impedance spectroscopy. The protection efficiency of the polystyrene film on nitinol was 99.4% and the monolayer was 42%.

Topics: Alloys; Corrosion; Electrochemistry; Microscopy, Atomic Force; Molecular Structure; Nickel; Polystyrenes; Spectrophotometry, Infrared; Surface Properties

2008