Journal Article10.1002/MACO.200804173
Corrosion aspects of metallic implants — An overview
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TL;DR: This review focuses on the several biomaterials corrosion and its measures to prevent corrosion.
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Abstract: The ability to replace or augment diseased body parts totally or partially has improved both the quality and life span of human population. The decline in surgical risks during recent decades has encouraged the development of more complex procedures for prosthetic implantation. Additionally, a variety of extracorporeal devices, such as the heart, lung and blood dialysis machines are used routinely, but these prosthetic elements have several limitations. Hence, research projects are currently underway to overcome the limitations of synthetic materials by developing formulations with varying properties, such as asymptomatic, long-term function in the human physiological environment, etc., to meet the needs of biomedical surgeons. This review focuses on the several biomaterials corrosion and its measures to prevent corrosion.
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Citations
Effect of DC Plasma Electrolytic Oxidation on Surface Characteristics and Corrosion Resistance of Zirconium.
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TL;DR: The coatings that were obtained at 200 V were the most corrosion resistant, however, they lacked the porous structure, which is typical for PEO coatings, and is sought after in the biomedical applications.
Development of Titanium Surgery Implants for Improving Osseointegration Through Formation of a Titanium Nanotube Layer
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Potentially toxic metallic wear nanoparticles and trace metal ions release from metal-on-metal orthopedic implants in the human biological specimens: An Overview of in vivo and ex vivo clinical studies
Henryk Matusiewicz,Magdalena Richter +1 more
- 30 Dec 2020
TL;DR: In this paper, the authors explore how migration of metallic wear nanoparticles and ultratrace metal ions in the area of metal-on-metal orthopedic implants influences the surrounding tissues and bodily fluids, and what the toxicological consequences of this process may be.
Surface engineering of additively manufactured titanium alloys for enhanced clinical performance of biomedical implants: A review of recent developments
TL;DR: In this article , a review of the recent advances in surface engineering of Ti-alloys fabricated by additive manufacturing (AM) toward clinical use of these implants is presented. And the challenges and opportunities for attaining greater control over the surface properties of additively manufactured Ti-based biomaterials by post-AM surface treatments for enhancing the clinical performance of implant.
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