Surface Engineering of Biodegradable Magnesium Alloys for Enhanced Orthopedic Implants

Magnesium (Mg) alloys have been promised for biomedical implants in orthopedic field, however, the fast corrosion rate and mode challenge their clinical application. To push Mg alloys materials into practice, a composite coating with biodegradable and high compatible components to improve anticorrosion property of an Mg alloy (i.e., AZ31) is designed and fabricated. The inner layer is micro‐nano structured Mg(OH)2 through hydrothermal treatment. Then stearic acid (SA) is introduced to modify Mg(OH)2 for better reducing the gap below a surface‐degradation polymer layer of poly(1,3‐trimethylene carbonate). Benefited by the SA modification effect, this sandwiched coating avoids corrosive medium penetration via enhancing the adhesion strength at the interface between outer and inner layers. Both in vitro and in vivo tests indicate that the composite coating modified AZ31 perform a better anticorrosion behavior and biocompatibility compared to bare AZ31. Strikingly, a 1.7‐fold improvement in volume of newly formed bone is observed surrounding the composite coating modified implant after 12 week implantation. The sandwiched biocompatible coating strategy paves a hopeful way for future translational application of Mg alloys orthopedic materials in clinics. A sandwiched polymeric composite coating with biocompatibility and biodegradability on Mg alloy implants is designed and fabricated via simple and green methods. Compared with uncoated sample, the surface engineered Mg alloy exhibits superior corrosion resistance, enhanced adhesion strength, and excellent cytocompatibility, resulting in more new bone formation. It has potential for translational application in orthopedic field.