Three-dimensional printed 316L stainless steel cardiovascular stent’s electrolytic polishing and its mechanical properties_Journal of Biomedical Engineering

Authors：

CHEN Zhiang ¹ , MIAO Jingtao ¹ , WANG Qilong ¹ , HUANG Suxia ¹ , CAO Jingjing ¹ ,  LI Hezong ¹ , ZHAO Liguo ² , YUAN Jiangyong ³

1. Key Laboratory of Intelligent Industrial Equipment Technology of Hebei Province, Hebei University of Engineering, Handan, Hebei 056038, P. R. China;
2. Wolfson School of Mechanical, Electrical and Manufacturing Engineering, Loughborough University, Loughborough, LE11 3TU, UK;
3. Affiliated Hospital of Hebei Engineering University, Handan, Hebei 056001, P. R. China;

Corresponding author：

LI Hezong, Email: lhzong@126.com

Keywords：

Vascular stent; Three-dimensional printing; 316L stainless steel; Electrolytic polishing; Balloon expansion

DOI：

10.7507/1001-5515.202211078

Video：

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Abstract Full text Figures/Tables Video References Cited by

The interventional therapy of vascular stent implantation is a popular treatment method for cardiovascular stenosis and blockage. However, traditional stent manufacturing methods such as laser cutting are complex and cannot easily manufacture complex structures such as bifurcated stents, while three-dimensional (3D) printing technology provides a new method for manufacturing stents with complex structure and personalized designs. In this paper, a cardiovascular stent was designed, and printed using selective laser melting technology and 316L stainless steel powder of 0−10 µm size. Electrolytic polishing was performed to improve the surface quality of the printed vascular stent, and the expansion behavior of the polished stent was assessed by balloon inflation. The results showed that the newly designed cardiovascular stent could be manufactured by 3D printing technology. Electrolytic polishing removed the attached powder and reduced the surface roughness Ra from 1.36 µm to 0.82 µm. The axial shortening rate of the polished bracket was 4.23% when the outside diameter was expanded from 2.42 mm to 3.63 mm under the pressure of the balloon, and the radial rebound rate was 2.48% after unloading. The radial force of polished stent was 8.32 N. The 3D printed vascular stent can remove the surface powder through electrolytic polishing to improve the surface quality, and show good dilatation performance and radial support performance, which provides a reference for the practical application of 3D printed vascular stent.

Citation： CHEN Zhiang, MIAO Jingtao, WANG Qilong, HUANG Suxia, CAO Jingjing, LI Hezong, ZHAO Liguo, YUAN Jiangyong. Three-dimensional printed 316L stainless steel cardiovascular stent’s electrolytic polishing and its mechanical properties. Journal of Biomedical Engineering, 2023, 40(3): 552-558. doi: 10.7507/1001-5515.202211078 Copy

1.	中国心血管健康与疾病报告编写组. 中国心血管健康与疾病报告2019概要. 中华老年病研究电子杂志, 2020, 7(4): 4-15.
2.	Momiyama Y, Ishzakka N, Adachi H, et al. Inflammation, atherosclerosis and coronary artery disease. Clin Med Insights, 2014, 8: 67-70.
3.	Finazzi V, Demir A G, Biffi C A, et al. Design and functional testing of a novel balloon-expandable cardiovascular stent in CoCr alloy produced by selective laser melting. J Manuf Processes, 2020, 55: 161-173.
4.	Guerra A, Ciurana J. 3D-printed bioabsordable polycaprolactone stent: The effect of process parameters on its physical features. Mater Design, 2018, 137: 430-437.
5.	Veerubhotla K, Lee Y Y, Lee C H. Parametric optimization of 3D printed hydrogel-based cardiovascular stent. Pharm Res, 2021, 38(5): 885-900.
6.	Wen Peng, Voshage M, Jauer L, et al. Laser additive manufacturing of Zn metal parts for biodegradable applications: Processing, formation quality and mechanical properties. Mater Design, 2018, 155: 36-45.
7.	Demir A G, Previtali B. Additive manufacturing of cardiovascular CoCr stents by selective laser melting. Mater Design, 2017, 119: 338-350.
8.	陈姗姗, 张炳春, 杨柯. 医用无镍不锈钢在血管支架领域的研究进展. 中国医疗设备, 2018, 33(5): 14-17.
9.	刘磊, 李东波, 童一飞, 等. 血管支架的激光加工工艺及研究进展. 热加工工艺, 2017, 46(5): 15-18.
10.	张宏辉, 冯海全, 李治国, 等. 镁合金冠脉支架支撑性能分析及其优化. 医用生物力学, 2019, 34(1): 14-20.
11.	魏云波, 赵丹阳, 王敏杰, 等. 高径向支撑性可生物降解聚合物血管支架结构设计与力学性能分析. 中国机械工程, 2020, 31(9): 1098-1107.
12.	Finazzi V, Demir A G, Biffi C A, et al. Design rules for producing cardiovascular stents by selective laser melting: Geometrical constraints and opportunities. Procedia Structur Integr, 2019, 15: 16-23.
13.	蒋华臻, 房佳汇钰, 陈启生, 等. 激光选区熔化成形316l不锈钢工艺、微观组织、力学性能的研究现状. 中国激光, 2022, 49(14): 309-329.
14.	Kao J K, Lin Shengyao, Chen Y S. Surface processing technology for 316LVM stainless steel stents. J Appl Sci Eng, 2018, 21(3): 343-350.
15.	杨希明, 侯章垒. 超薄不锈钢基材连续电解抛光工艺的优化. 电镀与涂饰, 2017, 36(13): 689-695.
16.	Sojitra P, Engineer C, Kothwala D, et al. Electropolishing of 316LVM stainless steel cardiovascular stents: An investigation of material removal, surface roughness and corrosion behaviour. Trends Biomater Artif Organs, 2010, 23(3): 115-121.
17.	Han Wei, Fang Fengzhou. Orientation effect of electropolishing characteristics of 316L stainless steel fabricated by laser powder bed fusion. Front Mech Eng, 2021, 16: 580-598.
18.	魏云波, 王敏杰, 赵丹阳, 等. 可降解聚合物血管支架体外力学性能测试实验研究. 生物医学工程学杂志, 2019, 36(4): 604-612.
19.	季文彬, 徐立奎, 戴士杰, 等. 激光选区熔化成型316L不锈钢的工艺参数对硬度与微观组织的影响. 材料导报, 2021, 35(22): 22125-22131.
20.	姚讯杰, 王佳玮, 杨雁程, 等. 金属构件激光增材制造缺陷产生机理及控制机制探究. 中国激光, 2022, 49(14): 286-296.
21.	Zhang Bi, Li Yongtao, Bai Qian. Defect formation mechanisms in selective laser melting: A review. Chin J Mech Eng, 2017, 30: 515-527.
22.	张园园, 颜文涛, 李建军, 等. 不同结构的左旋聚乳酸冠脉支架的力学行为研究. 生物医学工程学进展, 2021, 42(22): 63-67.

1. 中国心血管健康与疾病报告编写组. 中国心血管健康与疾病报告2019概要. 中华老年病研究电子杂志, 2020, 7(4): 4-15.
2. Momiyama Y, Ishzakka N, Adachi H, et al. Inflammation, atherosclerosis and coronary artery disease. Clin Med Insights, 2014, 8: 67-70.
3. Finazzi V, Demir A G, Biffi C A, et al. Design and functional testing of a novel balloon-expandable cardiovascular stent in CoCr alloy produced by selective laser melting. J Manuf Processes, 2020, 55: 161-173.
4. Guerra A, Ciurana J. 3D-printed bioabsordable polycaprolactone stent: The effect of process parameters on its physical features. Mater Design, 2018, 137: 430-437.
5. Veerubhotla K, Lee Y Y, Lee C H. Parametric optimization of 3D printed hydrogel-based cardiovascular stent. Pharm Res, 2021, 38(5): 885-900.
6. Wen Peng, Voshage M, Jauer L, et al. Laser additive manufacturing of Zn metal parts for biodegradable applications: Processing, formation quality and mechanical properties. Mater Design, 2018, 155: 36-45.
7. Demir A G, Previtali B. Additive manufacturing of cardiovascular CoCr stents by selective laser melting. Mater Design, 2017, 119: 338-350.
8. 陈姗姗, 张炳春, 杨柯. 医用无镍不锈钢在血管支架领域的研究进展. 中国医疗设备, 2018, 33(5): 14-17.
9. 刘磊, 李东波, 童一飞, 等. 血管支架的激光加工工艺及研究进展. 热加工工艺, 2017, 46(5): 15-18.
10. 张宏辉, 冯海全, 李治国, 等. 镁合金冠脉支架支撑性能分析及其优化. 医用生物力学, 2019, 34(1): 14-20.
11. 魏云波, 赵丹阳, 王敏杰, 等. 高径向支撑性可生物降解聚合物血管支架结构设计与力学性能分析. 中国机械工程, 2020, 31(9): 1098-1107.
12. Finazzi V, Demir A G, Biffi C A, et al. Design rules for producing cardiovascular stents by selective laser melting: Geometrical constraints and opportunities. Procedia Structur Integr, 2019, 15: 16-23.
13. 蒋华臻, 房佳汇钰, 陈启生, 等. 激光选区熔化成形316l不锈钢工艺、微观组织、力学性能的研究现状. 中国激光, 2022, 49(14): 309-329.
14. Kao J K, Lin Shengyao, Chen Y S. Surface processing technology for 316LVM stainless steel stents. J Appl Sci Eng, 2018, 21(3): 343-350.
15. 杨希明, 侯章垒. 超薄不锈钢基材连续电解抛光工艺的优化. 电镀与涂饰, 2017, 36(13): 689-695.
16. Sojitra P, Engineer C, Kothwala D, et al. Electropolishing of 316LVM stainless steel cardiovascular stents: An investigation of material removal, surface roughness and corrosion behaviour. Trends Biomater Artif Organs, 2010, 23(3): 115-121.
17. Han Wei, Fang Fengzhou. Orientation effect of electropolishing characteristics of 316L stainless steel fabricated by laser powder bed fusion. Front Mech Eng, 2021, 16: 580-598.
18. 魏云波, 王敏杰, 赵丹阳, 等. 可降解聚合物血管支架体外力学性能测试实验研究. 生物医学工程学杂志, 2019, 36(4): 604-612.
19. 季文彬, 徐立奎, 戴士杰, 等. 激光选区熔化成型316L不锈钢的工艺参数对硬度与微观组织的影响. 材料导报, 2021, 35(22): 22125-22131.
20. 姚讯杰, 王佳玮, 杨雁程, 等. 金属构件激光增材制造缺陷产生机理及控制机制探究. 中国激光, 2022, 49(14): 286-296.
21. Zhang Bi, Li Yongtao, Bai Qian. Defect formation mechanisms in selective laser melting: A review. Chin J Mech Eng, 2017, 30: 515-527.
22. 张园园, 颜文涛, 李建军, 等. 不同结构的左旋聚乳酸冠脉支架的力学行为研究. 生物医学工程学进展, 2021, 42(22): 63-67.

Journal of Biomedical Engineering

Three-dimensional printed 316L stainless steel cardiovascular stent’s electrolytic polishing and its mechanical properties

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