Safaa Hashim Radhi scite author profile

The utilisation of metals and alloys in the biomedical field was and is still of immense importance for human life. Typically, the materials used for metallic biomedical applications, particularly those are implanted in vivo, provide appropriate mechanical and biological properties that allow them to accomplish the purpose for which they are used. Nonetheless, there are some inherent limitations impede the optimal use of these materials. One of the most crucial determinants is corrosion, which results in several other problems such as the formation of toxic substances that can not only cause necrosis of the cells attached to the implant, these toxins could also be carried by blood into body tissues and organs. This in turn leads to dire consequences on patient's life. Although a wide variety of approaches may be available to address the corrosion issue, it is alleged that coating these metals and alloys with polymers, especially the conductive ones, is among the best strategies in this regard. This review will highlight the latest developments in using conductive polymers including polypyrrole, polyaniline, polythiophene and their composites in order to enhance biocompatibility, mechanical properties and most importantly corrosion protection performance of metallic implants. The findings obtained from coating 316L stainless steel, titanium and magnesium alloys, which have been widely manipulated in biomedical field as long and short-term implants, will be evaluated.

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A Review on the Latest Developments of Conducting Polymer and Composite Coatings for Enhancing Biocompatibility and Corrosion Resistance of Metallic Biomedical Implants

Mohammed

Radhi

Hadi

2021

EJENG

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Effect of machinable glass ceramic (MACOR) nanoparticles addition on the mechanical properties of Al-Si alloys

Hassan

Radhi

Salman³

2019

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Enhancement of Ti by carbon Nanotubes addition for bone repair

Wetaify

Radhi

Abdullah

2021

IOP Conf. Ser.: Mater. Sci. Eng.

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This study involves fabricating Ti based materials reinforced by carbon nano-tubes. CNTs were added with weight percentage (1, 2, 3, 4 and 5 wt% ) to enhance the mechanical properties of titanium. Some properties were measured for nanocomposites (CNTs/Titanium) such as microhardness, elastic modulus, wear rate in addition to microstructure by SEM. Microhardness was increased for nano-composites, which increased 421 Kg/mm2. The results of elastic modulus shown the decreasing in elastic modulus from 124 GPa to 82 GPa for nanocomposites. Wear rate results exhibited the lower wear rate of nano-composites compared with titanium due to the filling the vacancy in microstructure by CNTs. The scanning electron microscopy images showed that uniform distribution of CNTs in titanium and the lowest defect in microstructure. The good coherence between CNTs and base metal led to good mechanical properties.

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