The clinic applications of bioabsorbable magnesium (Mg) and its alloys have been
significantly restricted owing to their poor corrosion resistance. Besides elemental alloying …

With promising mechanical properties and biodegradability, magnesium (Mg) and its alloys
are considered as potential candidates in both industrial and biomedical fields. However …

Bone plates play a vital role in bone fracture healing by providing the necessary mechanical
fixation for fracture fragments through modulating biomechanical microenvironment adjacent …

Manipulating the degradation rate of biomedical magnesium alloys poses a challenge. The
characteristics of a microarc oxidation (MAO), prepared in phytic acid, and poly (l-lactic …

Zn-based alloys have been viewed as new potential materials for biodegradable implants,
such as cardiovascular stents, mainly in consideration of their lower corrosion rate when …

Mg alloys are emerging as potential and very promising alternatives for replacing permanent
metallic implant materials such as steels and titanium in applications where the implants …

Magnesium (Mg) has emerged as an ideal alternative to the permanent implant materials
owing to its enhanced properties such as biodegradation, better mechanical strengths than …

In recent years, biodegradable magnesium alloys emerge as a new class of biomaterials for
tissue engineering and medical devices. Deploying biodegradable magnesium-based …

Magnesium (Mg) and its alloys have been suggested as revolutionary biodegradable
materials. However, fast degradation hinders its clinic application. To improve the corrosion …

Biodegradable Mg-based implants are widely used in clinical applications because they
exhibit mechanical properties comparable to those of human bone and require no revision …