Degradation behavior, osteogenesis, and antimicrobial properties of Ga-coated ZK60 Mg alloys for medical implants
Feng Lu, Wu Zhou, Yang Huang, Lin Shen, Bo Qiao, Jiale Wu, Ning Wen, Jin Hu, Bingyao Deng
Abstract
• Successful fabrication of mg-ga alloy Layer: the mg-ga alloy layer is composed of Ga 5 Mg 2 and Ga 2 Mg intermetallic compounds, which significantly increase the hardness and durability of the alloy. • Significantly improved corrosion Resistance: the mg-ga alloy layer slows down the rate of ionic degradation of the ZK60 alloy. It contributes to the maintenance of the initial mechanical properties of the alloy. • Enhancement of osteogenic activity and resistance to osteoblastic Differentiation: ZK-GM-XH alloy promotes differentiation of hBMSCs towards osteoblasts and inhibits osteoclastogenesis. • Excellent antibacterial Properties: the synergistic effects of ion release and the formation of an alkaline environment showed excellent antibacterial properties against staphylococcus aureus and escherichia coli. The application of medical magnesium (Mg) alloys in implantable medical devices is promising due to the similar modulus of elasticity and biodegradability to human bone, which facilitates osseointegration. However, rapid degradation and loss of mechanical strength remain critical issues. To tackle these challenges, in this study, liquid metal gallium (Ga), which possesses non-toxicity, excellent biocompatibility, moderate chemical reactivity, and superior alloying capability, was used to develop a novel Mg alloy coating that can simultaneously enhance mechanical strength, reduce the degradation rate, and provide antibacterial and osteogenic properties. A unique, simplified coating process applied liquid Ga to the surface of ZK60 Mg alloy, and coatings of varying thicknesses were successfully fabricated. The phase composition of the Mg-Ga alloy layers was identified mainly consisting of Ga 5 Mg 2 and Ga 2 Mg. Vitro corrosion tests demonstrated that surface alloying of Ga with ZK60 effectively suppressed the degradation rate of the Mg alloy. Prolonged Mg-Ga alloying time improved human bone marrow mesenchymal stem cells (hBMSCs) adhesion, spreading, proliferation, and differentiation. The Mg-Ga alloy layer positively affected the early differentiation of osteoblasts and extracellular matrix mineralization, upregulating the expression of osteogenic-related genes and inhibiting osteoclast activity. Additionally, the Mg-Ga alloy exhibited excellent antibacterial properties through a combined effect of ion release and the formation of an alkaline environment. In short, the Ga-coated ZK60 Mg alloy demonstrated superior corrosion resistance, structural stability, cellular compatibility, osteogenic performance, and antibacterial capability, providing strong support for applying Mg alloys in medical implants.