Finite Element Analysis of Effect of Key Dimension of Nitinol Stent on Its Fatigue Behaviour_Journal of Biomedical Engineering

Authors：

李建军 ,  王盛章 , LIJianjun ,  WANGShengzhang

复旦大学力学与工程科学系, 上海 200433;
Department of Mechanics and Engineering Science, Fudan University, Shanghai 200433, China;

Corresponding author：

王盛章, Email: szwang@fudan.edu.cn; WANGShengzhang, Email: szwang@fudan.edu.cn

Keywords：

nitinol stent; fatigue; finite element; crown area dimension; strain

DOI：

10.7507/1001-5515.20150056

Video：

Export PDF Favorites Scan Get Citation

Abstract Full text Figures/Tables Video References Cited by

To evaluate the fatigue behavior of nitinol stents, we used the finite element method to simulate the manufacture processes of nitinol stents, including expanding, annealing, crimping, and releasing procedure in applications of the clinical treatments. Meanwhile, we also studied the effect of the crown area dimension of stent on strain distribution. We then applied a fatigue diagram to investigate the fatigue characteristics of nitinol stents. The results showed that the maximum strain of all three stent structures, which had different crown area dimensions under vessel loads, located at the transition area between the crown and the strut, but comparable deformation appeared at the inner side of the crown area center. The cause of these results was that the difference of the area moment of inertia determined by the crown dimension induced the difference of strain distribution in stent structure. Moreover, it can be drawn from the fatigue diagrams that the fatigue performance got the best result when the crown area dimension equaled to the intermediate value. The above results proved that the fatigue property of nitinol stent had a close relationship with the dimension of stent crown area, but there was no positive correlation.

Citation： 李建军, 王盛章, LIJianjun, WANGShengzhang. Finite Element Analysis of Effect of Key Dimension of Nitinol Stent on Its Fatigue Behaviour. Journal of Biomedical Engineering, 2015, 32(2): 305-310. doi: 10.7507/1001-5515.20150056 Copy

1.	ECKER R D, SAUVAGEAU E, LEVY E I, et al.Complications of carotid artery stenting at a high-volume teaching center:experience of University at Buffalo endovascular fellows from 2004 to 2006[J].Neurosurgery, 2008, 62(4):812-816.
2.	BUSSIÈRE M, PELZ D M, KALAPOS P, et al. Results using a self-expanding stent alone in the treatment of severe symptomatic carotid bifurcation stenosis[J]. J Neurosurg, 2008, 109(3):454-460.
3.	THÉRIAULT P, TERRIAULT P, BRAILOVSKI V, et al. Finite element modeling of a progressively expanding shape memory stent[J]. J Biomech, 2006, 39(15):2837-2844.
4.	SHOBAYASHI Y, TANOUE T, TATESHIMA S, et al. Mechanical design of an intracranial stent for treating cerebral aneurysms[J]. Med Eng Phys, 2010, 32(9):1015-1024.
5.	高振宇, 梁栋科, 齐民, 等.镍钛合金超弹性支架抗压缩性能的实验与分析[J].功能材料与器件学报, 2006, 12(1):49-53.
6.	赵振心, 刘道志, 孙康, 等.镍钛合金血管支架的有限元分析及疲劳测试[J].中国医疗器械杂志, 2008, 32(5):373-376.
7.	DUMOULIN C, COCHELIN B. Mechanical behaviour modelling of balloon-expandable stents[J]. J Biomech, 2000, 33(11):1461-1470.
8.	DUERIG T W, TOLOMEO D E, WHOLEY M. An overview of superelastic stent design[J]. Minim Invasive Ther Allied Technol, 2000, 9(3/4):235-246.
9.	US Food and Drug Administration. The guidance for industry and FDA staff:non-clinical tests and recommended labeling for intravascular stents and associated delivery systems[C]//Maryland:2005:14-19.
10.	LI J, LUO Q, XIE Z, et al. Fatigue Life analysis and experimental verification of coronary stent[J]. Heart Vessels, 2010, 25(4):333-337.
11.	TABANLI R M, SIMHA N K, BERG B T. Mean strain effects on the fatigue properties of superelastic NiTi[J]. Metallurgical and Materials Transactions A, 2001, 32(7):1866-1869.
12.	TOLOMEO D, DAVIDSON S, SANTINORANONT M. Cyclic property of superelastic nitinol:design implication[C]//Proceedings of the International Conference on Shape Memory and Superelastic Technologies. California:2001:471-476.
13.	KUGLER C, MATSON D, PERRY K. Non-Zero mean fatigue test protocol for NiTi[C]//Proceedings of the International Conference on Shape Memory and Superelastic Technologies. California:2001:409-417.
14.	PELTON A R, GONG X Y, DUERIG T. Fatigue testing of diamond shaped specimens[C]//International Conference on Shape Memory and Superelastic Technologies.International Organization on SMST. California:2003:293-302.
15.	CANAN T, LEE M S. Drug-eluting stent fracture:incidence, contributing factors, and clinical implications[J]. Catheter Cardiovasc Interv, 2010, 75(2):237-245.
16.	LEE M S, JUREWITZ D, ARAGON J, et al. Stent fracture associated with drug-eluting stents:clinical characteristics and implications[J]. Catheter Cardiovasc Interv, 2007, 69(3):387-394.
17.	AOKI J, NAKAZAWA G, TANABE K, et al. Incidence and clinical impact of coronary stent fracture after sirolimus-eluting stent implantation[J]. Catheter Cardiovasc Interv, 2007, 69(3):380-386.

1. ECKER R D, SAUVAGEAU E, LEVY E I, et al.Complications of carotid artery stenting at a high-volume teaching center:experience of University at Buffalo endovascular fellows from 2004 to 2006[J].Neurosurgery, 2008, 62(4):812-816.
2. BUSSIÈRE M, PELZ D M, KALAPOS P, et al. Results using a self-expanding stent alone in the treatment of severe symptomatic carotid bifurcation stenosis[J]. J Neurosurg, 2008, 109(3):454-460.
3. THÉRIAULT P, TERRIAULT P, BRAILOVSKI V, et al. Finite element modeling of a progressively expanding shape memory stent[J]. J Biomech, 2006, 39(15):2837-2844.
4. SHOBAYASHI Y, TANOUE T, TATESHIMA S, et al. Mechanical design of an intracranial stent for treating cerebral aneurysms[J]. Med Eng Phys, 2010, 32(9):1015-1024.
5. 高振宇, 梁栋科, 齐民, 等.镍钛合金超弹性支架抗压缩性能的实验与分析[J].功能材料与器件学报, 2006, 12(1):49-53.
6. 赵振心, 刘道志, 孙康, 等.镍钛合金血管支架的有限元分析及疲劳测试[J].中国医疗器械杂志, 2008, 32(5):373-376.
7. DUMOULIN C, COCHELIN B. Mechanical behaviour modelling of balloon-expandable stents[J]. J Biomech, 2000, 33(11):1461-1470.
8. DUERIG T W, TOLOMEO D E, WHOLEY M. An overview of superelastic stent design[J]. Minim Invasive Ther Allied Technol, 2000, 9(3/4):235-246.
9. US Food and Drug Administration. The guidance for industry and FDA staff:non-clinical tests and recommended labeling for intravascular stents and associated delivery systems[C]//Maryland:2005:14-19.
10. LI J, LUO Q, XIE Z, et al. Fatigue Life analysis and experimental verification of coronary stent[J]. Heart Vessels, 2010, 25(4):333-337.
11. TABANLI R M, SIMHA N K, BERG B T. Mean strain effects on the fatigue properties of superelastic NiTi[J]. Metallurgical and Materials Transactions A, 2001, 32(7):1866-1869.
12. TOLOMEO D, DAVIDSON S, SANTINORANONT M. Cyclic property of superelastic nitinol:design implication[C]//Proceedings of the International Conference on Shape Memory and Superelastic Technologies. California:2001:471-476.
13. KUGLER C, MATSON D, PERRY K. Non-Zero mean fatigue test protocol for NiTi[C]//Proceedings of the International Conference on Shape Memory and Superelastic Technologies. California:2001:409-417.
14. PELTON A R, GONG X Y, DUERIG T. Fatigue testing of diamond shaped specimens[C]//International Conference on Shape Memory and Superelastic Technologies.International Organization on SMST. California:2003:293-302.
15. CANAN T, LEE M S. Drug-eluting stent fracture:incidence, contributing factors, and clinical implications[J]. Catheter Cardiovasc Interv, 2010, 75(2):237-245.
16. LEE M S, JUREWITZ D, ARAGON J, et al. Stent fracture associated with drug-eluting stents:clinical characteristics and implications[J]. Catheter Cardiovasc Interv, 2007, 69(3):387-394.
17. AOKI J, NAKAZAWA G, TANABE K, et al. Incidence and clinical impact of coronary stent fracture after sirolimus-eluting stent implantation[J]. Catheter Cardiovasc Interv, 2007, 69(3):380-386.

Journal of Biomedical Engineering

Finite Element Analysis of Effect of Key Dimension of Nitinol Stent on Its Fatigue Behaviour

Abstract Full text Figures/Tables Video References Cited by

Previous Article

Next Article

Format

Content