Abstract
In this study, a two-step surface treatment was developed to restrain the rapid primary degradation of a biodegradable Mg alloy and to improve their biocompatibility. Micro arc oxidation (MAO) coating was performed in alkaline electrolytes such as 1.0 M NaOH with 0.1 M glycerol and 0.1 M Na3PO4. Hydrothermal treatment was performed in 0.1 M Ca-EDTA (C10H12CaN2Na2O8) and 0.5 M NaOH solution at 90 °C for different times (6, 12, 24, and 48 h). The film morphology and chemical properties were evaluated by XRD and FE-SEM. The electrochemical and corrosion behaviors were examined in the simulated body fluid, and cytotoxicity was assessed using MC3T3-E1 cells. After MAO coating, an oxide layer containing {bf{P}}{{bf{O}}}_{4}^{3-} formed on the surface. During the hydrothermal treatment in Ca-EDTA solution, calcium phosphate and Mg(OH)2 were produced via a reaction between {bf{P}}{{bf{O}}}_{4}^{3-} on the surface and Ca2+ in solution. The layer with ceramics and oxides was grown on the surface with increasing hydrothermal treatment time, and improved the surface corrosion resistance. The 24 h hydrothermal-treated group showed the lowest immersion corrosion rate and high cell viability. Therefore, this treatment was the most favorable surface modification for improving the initial corrosion resistance and bioactivity of the biodegradable Mg alloy.
Highlights
The demand for temporary implants for bone fracture and bone loss has rapidly increased
The pores produced by micro arc oxidation (MAO) coating were nearly completely sealed after the hydrothermal treatment, and the surface was formed
PO34− and Na ions contained in the MAO-coated layer bonded with Ca ions in the hydrothermal treatment solution (Ca-EDTA), so that it induced the formation of apatite
Summary
The demand for temporary implants for bone fracture and bone loss has rapidly increased. Mg has been constantly studied as a biomedical implant material (stent, pin, bone plate etc.)[2,3,4] It has a high corrosion rate in body fluids and undergoes rapid corrosion at a primary stage. Micro arc oxidation (MAO) can create a magnesium oxide layer with different thicknesses by varying types of electrolytes, current density, and applied voltage This oxide layer can reduce the corrosion rate of the surface upon reaction with body fluid, and prevent the peeling off caused by implantation. To improve corrosion resistance by sealing the pores and enhance the bioactivity of the magnesium surface, hydrothermal treatment was conducted with different exposure times in Ca-EDTA solution. The corrosion characteristics and biocompatibility with the different surface treatments were assessed
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