The possibility of using magnesium (Mg) alloys in biomedical field gives a lot of advantages.
Their mechanical properties are more similar to the bone tissue than conventional metals …

This paper focuses on the simulation of the galvanic corrosion process of orthopedic
bimetallic couples used as biomaterials. Galvanic corrosion in the human body is a specific …

Biodegradable bioimplants is a major thrust area in the field of orthopedic implants. The
biodegradable bioimplant materials are characterized based on the elastic modulus …

Magnesium can be potentially used as biomedical implants owing to its biodegradability and
biocompatibility due to its advantages over traditional metallic implants made from stainless …

Magnesium alloy AZ91 is one of the best suited biodegradable biomaterials for bioimplants.
Magnesium is a highly active metal with accelerated corrosion in physiological …

The use of metallic biomaterials, such as titanium alloys, stainless steels and cobalt-
chromium alloys in bone implant devices is indispensable to support the bone during the …

Biocompatible metallic material represents the latest findings of the studies in the field of
medical implants. After achieving many practical and theoretical studies over the past …

Biodegradable magnesium implants are considered as promising fixation devices in the
orthopaedic application to replace the conventional implants with unexpected properties …

Mg-alloys having bone liked mechanical properties are biodegradable, biocompatible and
osteoconductive metallic materials are potential candidates used for orthopaedics and …

The bone surgery often makes use of implants to sustain and fix the bones during the
healing phase. Commonly used implants require a surgical procedure to be removed after …