Anodic spark deposition of P, Me(II) or Me(III) containing coatings on aluminium and titanium alloys in electrolytes with polyphosphate complexes

Руднев, В. С.; Yarovaya, T. P.; Boguta, D. L.; Tyrina, L. M.; Недозоров, П. М.; Гордиенко, П. С.

doi:10.1016/s0022-0728(00)00483-6

Cited by 81 publications

(20 citation statements)

References 13 publications

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“…[81,82] The introduction of silver in the oxide is also a critical research topic, as Ag-doped TiO 2 significantly contributes to advances in the regulation of microbial colonisation and to reduce implantrelated infections, owing to its broad-spectrum bactericidal activity. [83] Ag-functionalised TiO 2 films are mostly produced by chemical techniques (solÀgel, chemical deposition, precipitationÀreduction), but ASD treatments have been developed as well, which consist of high-voltage anodising in silver acetate or silver nitrate-containing electrolytes.…”

Section: Biocompatible and Antibacterial Coatingsmentioning

confidence: 99%

Application-wise nanostructuring of anodic films on titanium: a review

Diamanti

Ormellese

Pedeferri

2015

Journal of Experimental Nanoscience

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Section: Biocompatible and Antibacterial Coatingsmentioning

confidence: 99%

Application-wise nanostructuring of anodic films on titanium: a review

Diamanti

Ormellese

Pedeferri

2015

Journal of Experimental Nanoscience

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“…Modifications of the electronic structure of the oxide can also be obtained by anodizing in sulfuric acid: these principles can be exploited in photoelectrochemical applications of TiO 2 , such as photocatalytic devices or dye-sensitized solar cells (87)(88)(89). In general, phosphates electrolytes are probably the most frequently studied, owing to the improvement in corrosion resistance, catalytic activity, and biocidal effect induced by the presence of polyphosphates, elemental phosphorus or phosphides in the coating (90)(91)(92)(93)(94)(95). Metal doping of the oxide is also performed by using transition element-containing electrolytes, as widely documented in the earlier stages of the study of the process, where the chosen electrolyte is usually composed of sodium hexametaphosphate and metal acetate or polyphosphate (96)(97)(98)(99)(100).…”

Section: Enhancement Of Biocompatibility and Osseointegrationmentioning

confidence: 99%

Anodic oxidation of titanium: from technical aspects to biomedical applications

Diamanti

Curto

Pedeferri

2011

JABB

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Titanium biomaterials are widely employed to produce medical components, such as hip and knee-joint prostheses, bone plates and screws, dental implants, pacemaker cases, surgical equipment, etc. Their diffusion is ascribed to the broad spectrum of optimal mechanical and surface properties, such as the corrosion resistance and correlated low ionic release, the biocompatibility, and especially, the enhanced osseointegration that can be achieved by surface modifications, particularly by suitable anodizing treatments. This review is intended to provide a survey of the wide class of anodic oxidation treatments on titanium, focusing on the oxide structures, morphologies, and compositions that best apply to the variegated fields of titanium applications.

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“…The reverse current modes promote refinement of the coating morphology and facilitate precipitation of crystalline CaPs without the need to chelate Ca 2+ cations30 or use electrolytes with a high Ca to P ratio (>2:1). This offers substantial benefits as the phosphate forming capacity of the electrolyte is known to increase with an increasing Me to P content ratio whereas the solution stability decreases31; however, the coatings produced by these methods are somewhat less studied.…”

Section: Introductionmentioning

confidence: 99%

In vitro biological response of plasma electrolytically oxidized and plasma‐sprayed hydroxyapatite coatings on Ti–6Al–4V alloy

et al. 2013

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Plasma electrolytic oxidation (PEO) is a relatively new surface modification process that may be used as an alternative to plasma spraying methods to confer bioactivity to Ti alloy implants. The aim of this study was to compare physical, chemical and biological surface characteristics of two coatings applied by PEO processes, containing different calcium phosphate (CaP) and titanium dioxide phases, with a plasma-sprayed hydroxyapatite (HA) coating. Coating characteristics were examined by X-ray diffraction, energy dispersive X-ray spectroscopy, scanning electron microscopy, surface profilometry, and wettability tests. The biological properties were determined using the human osteoblastic cell line MG-63 to assess cell viability, calcium and collagen synthesis. The tests showed that PEO coatings are significantly more hydrophilic (6%) and have 78% lower surface roughness (Ra) than the plasma-sprayed coatings. Cell behavior was demonstrated to be strongly dependent on the phase composition and surface distribution of elements in the PEO coating. MG-63 viability for the TiO2 -based PEO coating containing amorphous CaPs was significantly lower than that for the PEO coating containing crystalline HA and the plasma-sprayed coating. However, collagen synthesis on both the CaP and the TiO2 PEO coatings was significantly higher (92% and 71%, respectively) than on the plasma-sprayed coating after 14 days. PEO has been demonstrated to be a promising method for coating of orthopedic implant surfaces.

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Anodic spark deposition of P, Me(II) or Me(III) containing coatings on aluminium and titanium alloys in electrolytes with polyphosphate complexes

Cited by 81 publications

References 13 publications

Application-wise nanostructuring of anodic films on titanium: a review

Application-wise nanostructuring of anodic films on titanium: a review

Anodic oxidation of titanium: from technical aspects to biomedical applications

In vitro biological response of plasma electrolytically oxidized and plasma‐sprayed hydroxyapatite coatings on Ti–6Al–4V alloy

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