Biomedical Magnesium Alloys: A Review of Material Properties, Surface Modifications and Potential as a Biodegradable Orthopaedic Implant

Poinern, Gérrard Eddy Jai; Brundavanam, Sridevi; Fawcett, Derek

doi:10.5923/j.ajbe.20120206.02

Cited by 264 publications

(64 citation statements)

References 187 publications

(166 reference statements)

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“…However, this process is complex and it can increase fabrication costs. Given the Mg-based metals’ mechanical properties for pure magnesium: (density of 1.74 gcm −3 ; elastic modulus of 45 GPa; compressive yield strength (0.2% CYS); ultimate compressive strength of 87 ± 4 MPa and 240 ± 9 MPa; tensile yield strength (0.2% YS) and ultimate tensile strength of 125 ± 9 MPa and 169 ± 11 MPa 15–17 ), the conventional manufacturing approach of laser engraved Mg tubbing suffers from considerable limitations. The intrinsic low ductility of bioresorbable metals, which need to balloon-expand without losing mechanical strength, brings another limitation 17 .…”

Section: Introductionmentioning

confidence: 99%

Expandable Mg-based Helical Stent Assessment using Static, Dynamic, and Porcine Ex Vivo Models

Koo

Tiasha

Shanov

et al. 2017

Sci Rep

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A bioresorbable metallic helical stent was explored as a new device opportunity (magnesium scaffold), which can be absorbed by the body without leaving a trace and simultaneously allowing restoration of vasoreactivity with the potential for vessel remodeling. In this study, developed Mg-based helical stent was inserted and expanded in vessels with subsequent degradation in various environments including static, dynamic, and porcine ex vivo models. By assessing stent degradation in three different environments, we observed: (1) stress- and flow-induced degradation; (2) a high degradation rate in the dynamic reactor; (3) production of intermediate products (MgO/Mg(OH)2 and Ca/P) during degradation; and (4) intermediate micro-gas pocket formation in the neighboring tissue ex vivo model. Overall, the expandable Mg-based helical stent employed as a scaffold performed well, with expansion rate (>100%) in porcine ex vivo model.

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Section: Introductionmentioning

confidence: 99%

Expandable Mg-based Helical Stent Assessment using Static, Dynamic, and Porcine Ex Vivo Models

Koo

Tiasha

Shanov

et al. 2017

Sci Rep

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“…These are different to traditional metallic biomaterials, which are dominated by corrosion resistant metals such as titanium, cobalt-chromium alloys and stainless steel [2]. The key application for biodegradable metals is for temporary medical implants and devices [3][4][5][6][7]. Biodegradable metals corrode and disappear after implantation.…”

Section: Medical Magnesium and Biocorrosionmentioning

confidence: 99%

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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“…The favorable mechanical properties of Mg alloy include a high stiffness-to-mass ratio ((9 − 26) × 10 6 m 2 ·s −2 ) and, in particular, an elastic modulus (17 GPa in shear, 45 GPa in tension) in the range of that of cortical bone GPa in tension). This suggests the eventual emergence of a novel biomaterial able to mitigate or even alleviate stress shielding [14] (see Section 5.2) caused by elastic property mismatch between implant and bone. Hence, effort is being expended on designing implant materials with a modulus that approaches that of bone.…”

Section: Introductionmentioning

confidence: 99%

Osseoconductive and Corrosion-Inhibiting Plasma-Sprayed Calcium Phosphate Coatings for Metallic Medical Implants

Heimann

2017

Metals

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During the last several decades, research into bioceramic coatings for medical implants has emerged as a hot topic among materials scientists and clinical practitioners alike. In particular, today, calcium phosphate-based bioceramic materials are ubiquitously used in clinical applications to coat the stems of metallic endoprosthetic hips as well as the surfaces of dental root implants. Such implants frequently consist of titanium alloys, CoCrMo alloy, or austenitic surgical stainless steels, and aim at replacing lost body parts or restoring functions to diseased or damaged tissues of the human body. In addition, besides such inherently corrosion-resistant metals, increasingly, biodegradable metals such as magnesium alloys are being researched for osseosynthetic devices and coronary stents both of which are intended to remain in the human body for only a short time. Biocompatible coatings provide not only vital biological functions by supporting osseoconductivity but may serve also to protect the metallic parts of implants from corrosion in the aggressive metabolic environment. Moreover, the essential properties of hydroxylapatite-based bioceramic coatings including their in vitro alteration in contact with simulated body fluids will be addressed in this current review paper. In addition, a paradigmatic shift is suggested towards the development of transition metal-substituted calcium hexa-orthophosphates with the NaSiCON (Na superionic conductor) structure to be used for implant coatings with superior degradation resistance in the corrosive body environment and with pronounced ionic conductivity that might be utilized in novel devices for electrical bone growth stimulation.

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Biomedical Magnesium Alloys: A Review of Material Properties, Surface Modifications and Potential as a Biodegradable Orthopaedic Implant

Cited by 264 publications

References 187 publications

Expandable Mg-based Helical Stent Assessment using Static, Dynamic, and Porcine Ex Vivo Models

Expandable Mg-based Helical Stent Assessment using Static, Dynamic, and Porcine Ex Vivo Models

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

Osseoconductive and Corrosion-Inhibiting Plasma-Sprayed Calcium Phosphate Coatings for Metallic Medical Implants

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