Abstract
With the development of minimally invasive treatment technology, coronary stents made of corrosion-resistant steel are in demand for restoring the patency of blood vessels. The effectiveness of coronary stenting depends on various factors, but the quality of the surface of the stents is a major factor. The higher the quality of the surface of the stent is, the less negative the effect on the circulatory system, arterial walls, and the higher the biocompatibility of the stent is. The complex shape, small cross-section, size, and low rigidity of coronary stents are the main reasons for the inability to ensure high surface quality using mechanical finishing methods. Therefore, electrochemical methods are used to polish stents. For electrochemical polishing (ECP) of stents, an electric mode based on direct current is traditionally used. The disadvantages of direct current ECP are excessive metal removal and the need to use electrolytes of complex compositions, often containing toxic components. As an alternative to the traditional ECP with the use of direct current, we have proposed a method of pulsed ECP using pulses of microsecond duration for polishing stents. The use of pulsed current allows one to achieve a significant increase in the efficiency of the SEC process, when, due to the localization of the anodic dissolution, the smoothing speed of the microroughness of the treated surface, referred to the total metal removal, increases significantly. The paper presents a comparative analysis of ECP modes using direct and pulse current to change the surface roughness, removal, radius of curvature of the edges, and corrosion resistance on the example of stents made of the 316LVM stainless steel. Based on the results of the studies, technological regimes of pulsed ECP were established that provide the highest quality polishing of the stent surface with a small metal removal with a slight rounding of the edges.
Highlights
To increase the biological lumen and maintain the patency of the blood vessel after percutaneous transluminal angioplasty, stents are used in medical practice [1, 2]
The processes of Electrochemical polishing (ECP) developed to date for stents made of nitinol [7], corrosion-resistant steel [20, 21], titanium alloys [22, 23] provide high-quality polishing with a significant decrease in surface roughness and an increase in the corrosion resistance of the surface layer
The purpose of this work is a comparative analysis of ECP modes with the use of direct and pulsed currents for changes in surface roughness, metal removal, changes in size, and corrosion resistance on the example of stents made of the 316LVM corrosion-resistant steel, as well as the establishment of technological ECP modes that provide the highest quality polishing of the surface with a relatively low metal removal and geometry changes
Summary
To increase the biological lumen and maintain the patency of the blood vessel after percutaneous transluminal angioplasty, stents are used in medical practice [1, 2]. Stents are made from implant materials widely used in medicine, such as nitinol, titanium, cobalt-chromium alloys, and corrosion-resistant steels These materials combine high resistance to corrosion, strength, resilience, and radiopaque properties [3]. In this case, the most important property of stents, which has a significant effect on their corrosion resistance in an aggressive environment of the body, biocompatibility and the risk of a repeated decrease in the vessel lumen in the implantation zone, is the quality of their surfaces [3,4,5,6,7]. The processes of ECP developed to date for stents made of nitinol [7], corrosion-resistant steel [20, 21], titanium alloys [22, 23] provide high-quality polishing with a significant decrease in surface roughness and an increase in the corrosion resistance of the surface layer
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