Review of Recent Developments in the Field of Magnesium Corrosion

Atrens, Andrej; Song, Guang‐Ling; Liu, Ming; Shi, Zhiming; Cao, Fuyong; Dargusch, Matthew S.

doi:10.1002/adem.201400434

Cited by 621 publications

(382 citation statements)

References 180 publications

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“…The H 2 evolution gave lower DR compared to the ML method. This difference can be explained by the particle undermining model (Song and Atrens, 1999), and perhaps the dissolution of hydrogen in the Mg sample (Atrens et al, 2015;Remennik et al, 2011;Zainal Abidin et al, 2013).…”

Section: Degradation Rate Analysismentioning

confidence: 99%

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In vivo and in vitro degradation comparison of pure Mg, Mg-10Gd and Mg-2Ag: a short term study

Marco

Myrissa²,

Martinelli³

et al. 2017

eCM

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The purpose of this study was to compare short term in vitro and in vivo biodegradation studies with low purity Mg (> 99.94 %), Mg-10Gd and Mg-2Ag designed for biodegradable implant applications. Three in vitro testing conditions were applied, using (i) phosphate buffered saline (PBS), (ii) Hank's balanced salt solution (HBSS) and (iii) Dulbecco's modified eagle medium (DMEM) in 5 % CO 2 under sterile conditions. Gas evolution and mass loss (ML) were assessed, as well as the degradation layer, by elemental mapping and scanning electron microscopy (SEM). In vivo, implantations were performed on male Sprague-Dawley rats evaluating both, gas cavity volume and implant volume reduction by micro-computed tomography (µCT), 7 d after implantation. Samples were produced by casting, solution heat treatment and extrusion in disc and pin shape for the in vitro and in vivo experiments, respectively. Results showed that when the processing of the Mg sample varied, differences were found not only in the alloy impurity content and the grain size, but also in the corrosion behaviour. An increase of Fe and Ni or a large grain size seemed to play a major role in the degradation process, while the influence of alloying elements, such as Gd and Ag, played a secondary role. Results also indicated that cell culture conditions induced degradation rates and degradation layer elemental composition comparable to in vivo conditions. These in vitro and in vivo degradation layers consisted of Mg hydroxide, Mg-Ca carbonate and Ca phosphate.

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Section: Degradation Rate Analysismentioning

confidence: 99%

“…(iii) Mg metal can store significant amounts of hydrogen (Nogita et al, 2009). Many authors use the dissolution of hydrogen in the Mg sample to explain the difference between the DRs calculated by hydrogen evolution and by ML (Atrens et al, 2015;Remennik et al, 2011;Zainal Abidin et al, 2013). (iv) Mg-RE alloys, e.g.…”

Section: In Vivomentioning

confidence: 99%

In vivo and in vitro degradation comparison of pure Mg, Mg-10Gd and Mg-2Ag: a short term study

Marco

Myrissa²,

Martinelli³

et al. 2017

eCM

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“…Corrosion of Mg alloys is typically faster than the corrosion of high-purity Mg in simple chloride solutions, because the second phase in the Mg alloy causes microgalvanic acceleration of the corrosion of the alpha-Mg matrix [22,[54][55][56]. This micro-galvanic corrosion acceleration typically occurs preferentially next to the second phase, and is often wrongly characterised as pitting corrosion.…”

Section: Magnesium Corrosion Assessmentmentioning

confidence: 99%

“…A detailed description of each technique can be found in any one of several good reviews [54,55,58]. Each technique has strengths and limitations.…”

Section: Magnesium Corrosion Assessmentmentioning

confidence: 99%

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Building towards a standardised approach to biocorrosion studies: a review of factors influencing Mg corrosion in vitro pertinent to in vivo corrosion

2017

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The factors that influence magnesium (Mg) corrosion in vitro are systematically evaluated from a review of the relevant literature. We analysed the influence of the following factors on Mg biocorrosion in vitro: (i) inorganic ions, including both anions and cations, (ii) organic components such as proteins, amino acids and vitamins, and (iii) experimental parameters such as temperature, pH, buffer system and flow rate. Considerations and recommendations towards a standardised approach to in vitro biocorrosion testing are given. Several potential simulated body fluids are recommended. Implementing a standardised approach to experimental parameters has the potential to significantly reduce variability between in vitro biocorrosion tests, and to help build towards a methodology that accurately and consistently mimics in vivo corrosion. However, there are also knowledge gaps with regard to how best to characterise the in vivo environment and corrosion mechanism. The assumption that blood plasma is the correct bodily fluid upon which to base in vitro methodologies is examined, and factors that influence the corrosion mechanism in vivo, such as specimen encapsulation, bear consideration for further studies.

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