AZ31 magnesium coronary stents were studied through a manufacturing process chain
involving laser cutting, acid pickling, and dip coating. The purpose of this study was to …

Magnesium alloy coronary stent becomes a hot research topic due to its biodegradable
character for avoiding late thrombosis and late restenosis. However, fracture of Mg alloy …

The use of magnesium-alloy stents shows promise as a less intrusive solution for the
treatment of cardiovascular pathologies as a result of the high biocompatibility of the …

Because of the increasing incidence of coronary artery disease, the use of cardiovascular
stents is gradually increasing. In percutaneous coronary intervention, advantage of …

Magnesium alloys are very biocompatible and show promise for use in implant device. The
focus of this article lies in the evaluation of the degradation performance and biological …

Magnesium metal (Mg) is a promising material for stent applications due to its
biocompatibility and ability to be resorbed by the body. Manufacturing of stents by laser …

Biodegradable stents, especially those composed of magnesium alloy-based materials, can
provide a temporary scaffold that support vessels while naturally resorbing in the body after …

Biomedical applications are an emerging field of interest for magnesium technology,
envisioning biodegradable implants that resorb in the human body after having cured a …

Biodegradable magnesium alloy stents (MAS) could present improved long-term clinical
performances over commercial bare metal or drug-eluting stents. However, MAS were found …

Magnesium alloy stents have been extensively studied in the field of biodegradable metal
stents due to their exceptional biocompatibility, biodegradability and excellent …