Abstract
Pure iron has been confirmed as a promising biodegradable metal. However, the degradation rate of pure iron should be accelerated to meet the clinical requirements. In this work, two different designs of platinum disc arrays, including sizes of Φ20 μm × S5 μm and Φ4 μm × S4 μm, have been coated on the surface of pure iron. Corrosion tests showed the platinum discs formed plenty of galvanic cells with the iron matrix which significantly accelerated the degradation of pure iron. Simultaneously, due to the designability of the shape, size as well as distribution of Pt discs, the degradation rate as well as degradation uniformity of pure iron can be effectively controlled by coating with platinum discs. The cytotoxicity test results unveiled that Pt discs patterned pure iron exhibited almost no toxicity to human umbilical vein endothelial cells, but a significant inhibition on proliferation of vascular smooth muscle cells. In addition, the hemolysis rate of Pt discs patterned pure iron was lower than 1%. Moreover, Pt discs also effectively reduced the number of adhered platelets. All these results indicated that Pt discs patterning is an effective way to accelerate degradation and improve biocompatibility of pure iron.
Highlights
Pure iron has been confirmed as a promising biodegradable metal
Two different designs of platinum disc arrays including sizes of Φ 20 μm × S5 μm (Φ 20 μm represents that the diameter of the platinum disc is 20 μm, S5 μm means that the space between two nearest platinum discs is 5 μm) and Φ 4 μm × S4 μm were prepared
Pt disc arrays on the surface of pure iron was prepared by lithography and electron beam evaporation, aiming at accelerating the degradation rate of pure iron matrix through galvanic corrosion
Summary
Pure iron has been confirmed as a promising biodegradable metal. the degradation rate of pure iron should be accelerated to meet the clinical requirements. Pt discs effectively reduced the number of adhered platelets All these results indicated that Pt discs patterning is an effective way to accelerate degradation and improve biocompatibility of pure iron. Numerous methods have been tried to enhance mechanical properties and corrosion rate of pure iron, such as alloying[3,14,17,18,19], compositing as well as new preparation techniques[20,21,22,23]. Researches on surface modification of pure iron have been reported, such as Fe-O thin film[24], calcium zinc phosphate coating[25], lanthanum ion implanting[26], and ion nitriding[27]. Using surface patterning to control corrosion behavior of metallic materials has not been reported previously
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