Coordinated control of drug release and corrosion resistance for 3D-printed porous Mg alloy in bone implant applications
Jiaping Han, Jingpeng Xia, Hao Zhang, Wanyu Zhao, Hongshan San, Yan Liu, Jirui Ma, Maria Serdechnova, Wojciech Simka, Xiaopeng Lu, Carsten Blawert, Mikhail L. Zheludkevich, Hui Chen
Abstract
• Two drug loaded coating systems are introduced inside 3D porous on AZ91 Mg. • In situ incorporation of LDH capsules effectively reduced the porosity of PEO layer. • The post-deposited LDH on PEO layer demonstrated highly stable corrosion resistance. • Both drug loaded coatings exhibited good corrosion resistance and biocompatibility. The advent of three-dimensional (3D) printed porous Mg alloys is considered a significant milestone in the development of metal-based degradable implants. However, the poor corrosion resistance of additively manufactured Mg alloys, along with the occurrences of inflammation and bacterial infections following implantation, pose critical challenges. In this study, two drug-loaded coatings were prepared within a porous Mg alloy using in situ incorporation and post-deposition of layered double hydroxides (LDHs) to enhance corrosion resistance, antibacterial properties, and biological compatibility combined with plasma electrolytic oxidation (PEO). The results revealed that in situ incorporation of LDH capsules effectively reduced the porosity of the PEO layer and improved the long-term corrosion resistance of the coating. The post-deposited LDH layer effectively sealed the PEO layer, demonstrating highly stable corrosion resistance during 7 d electrochemical impedance spectroscopy (EIS) test, with the impedance modulus at 10 –2 Hz stabilizing at 5 × 10 5 Ω·cm 2 . After soaking, the surface morphology of the in situ drug-loaded PEO coating exhibited more cracks and defects, whereas the PEO-LDH coating maintained a relatively dense morphology. Among the tested samples, the PEO-LDH coating showed the best performance in terms of corrosion resistance, cell proliferation and differentiation capabilities, and antibacterial efficacy (>99%). Its strong compatibility with the porous structure of 3D-printed Mg alloy highlights the potential of this coating system for biomedical applications. The design strategy proposed in this study offers valuable insights for future development of drug-loaded coatings for 3D-printed porous materials.