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A COMPARATIVE STUDY ON THE FATIGUE STRENGTH AND SERVICE LIFE OF LOWER LIMB ARTERIAL STENT AT DIFFERENT STENOSIS RATES

SHUANGQUAN MA

School of Mechanical Engineering, Inner Mongolia University of Technology, Hohhot, Inner Mongolia 010051, P. R. China

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HAIQUAN FENG

https://orcid.org/0000-0002-9078-494X

School of Mechanical Engineering, Inner Mongolia University of Technology, Hohhot, Inner Mongolia 010051, P. R. China

E-mail Address: fhq515@163.com

Corresponding author.

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YANLONG CHEN

School of Mechanical Engineering, Inner Mongolia University of Technology, Hohhot, Inner Mongolia 010051, P. R. China

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, and

HAOXIANG FENG

School of Materials Science and Technology, Nanjing University of Aeronautics and Astronautics, Nanjing, Jiangsu 210000, P. R. China

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https://doi.org/10.1142/S0219519423500197Cited by:0 (Source: Crossref)

Abstract

In order to study the influence of different stenosis rates of blood vessels on the fatigue strength and service life of lower limb arterial stent, numerical simulation was conducted for the mechanical behavior of four types of nickel-titanium alloy lower limb arterial stents (Absolute Pro, Complete SE, E-luminexx-B and Pulsar-35) under the action of radial compression, release and pulsating loads, so as to predict the fatigue life and safety of stents at different stenosis rates (0%, 30%, 50% and 70%). The study found that with increased vascular stenosis rate, both the elastic stress and strain of stent tend to increase, while the fatigue strength, service life and safety tend to decrease. When a stent is implanted in a normal blood vessel, its fatigue strength satisfies the requirement of a 10-year service life requirement, with maximum elastic stress and strain occurring on both sides of the connecting ribs at the end of stent. When the vascular stenosis rate is greater than 30%, the fatigue strength of the stent does not meet requirement of a 10-year service life, and fatigue fracture is likely to occur at the most stenotic part of the blood vessel. With increased vascular stenosis rate, the E-luminexx-B stent with the largest width of support had a significant decrease in its service life. The stent whose supporting unit is of symmetric wave peak structure has a longer service life compared with that whose supporting unit is of offset wave peak structure. The revealing of the influence of vascular stenosis rate on the mechanical properties and fatigue life of stents provides theoretical reference for the fracture failure mechanism of stents.

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References

1. Shishehbor MH, Jaff MR, Percutaneous therapies for peripheral artery disease, Circulation 134(24) :2008–2027, 2016. Crossref, Web of Science, Google Scholar
2. Members WG, Mozaffarian D, Benjamin EJ, et al., Executive summary: Heart disease and stroke statistics — 2016 update: A report from the American Heart Association, Circulation 127(1) :143–152, 2016. Google Scholar
3. Cheng CP, Choi G, Herfkens RJ et al., The effect of aging on deformations of the superficial femoral artery resulting from hip and knee flexion: Potential clinical implications, J Vasc Interventional Radiol Jvir 21(2) :195–202, 2010. Crossref, Web of Science, Google Scholar
4. Lei L, Qi X, Li S et al., Finite element analysis for fatigue behaviour of a self-expanding Nitinol peripheral stent under physiological biomechanical conditions, Computers Biol Med 104(32) :205–214, 2019. Crossref, Web of Science, Google Scholar
5. Morlacchi S, Pennati G, Petrini L et al., Influence of plaque calcifications on coronary stent fracture: A numerical fatigue life analysis including cardiac wall movement, J Biomech 47(4) :899–907, 2014. Crossref, Web of Science, Google Scholar
6. Dordoni E, Meoli A, Wu W et al., Fatigue behaviour of Nitinol peripheral stents: The role of plaque shape studied with computational structural analyses, Med Eng Phys 36(7) :842–849, 2014. Crossref, Web of Science, Google Scholar
7. Zhiguo L, Haiquan F, Wengang Y, Fatigue strength of intracranial arterial stents, J Med Biomech 33(5) :442–446, 2018. Google Scholar
8. Song J, A study on expansion and fatigue performance of medical stents in stenotic tapered blood vessels, Jiangsu University, 2018. Google Scholar
9. Qingshuai R, Finite element analysis of vascular stent expansion, Beijing University of Technology, 2016. Google Scholar
10. Holzapfel GA, Stadler M, Schulze-Bauer CAJ, A layer-specific three-dimensional model for the simulation of balloon angioplasty using magnetic resonance imaging and mechanical testing, Ann Biomed Eng 30(6) :753–767, 2002. Crossref, Web of Science, Google Scholar
11. Gökgöl C, Diehm N, Büchler P, Numerical modeling of nitinol stent oversizing in arteries with clinically relevant levels of peripheral arterial disease: The influence of plaque type on the outcomes of endovascular therapy, Ann Biomed Eng 45(6) :1420–1433, 2017. Crossref, Web of Science, Google Scholar
12. Martin D, Boyle F, Finite element analysis of balloon-expandable coronary stent deployment: Influence of angioplasty balloon configuration, Int J Numer Method Biomed Eng 29(11) :1161–1175, 2013. Crossref, Web of Science, Google Scholar
13. De Bock S, Iannaccone F, De Santis G et al., Virtual evaluation of stent graft deployment: A validated modeling and simulation study, J Mech Behav Biomed Mater 13(7) :129–139, 2012. Crossref, Web of Science, Google Scholar
14. Gökgöl C, Diehm N, Nezami FR et al., Nitinol stent oversizing in patients undergoing popliteal artery revascularization: A finite element study, Ann Biomed Eng 43(12) :2868–2880, 2015. Crossref, Web of Science, Google Scholar
15. Gasser TC, Ogden RW, Holzapfel GA, Hyperelastic modelling of arterial layers with distributed collagen fibre orientations, J R Soc Interface 3(6) :15–35, 2006. Crossref, Web of Science, Google Scholar
16. Cunnane EM, Mulvihill JJ, Barrett HE et al., Mechanical, biological and structural characterization of human atherosclerotic femoral plaque tissue, Acta Biomater 11(10) :295–303, 2015. Crossref, Web of Science, Google Scholar
17. Feng HQ, Hu ZY, Jiang XD et al., Research on elastic and plastic deformation of CoCr alloy used for coronary stents, J Plasticity Eng 19(4) :108–112, 2012. Google Scholar
18. Jimenez-Navarro MF, Lopez-Jimenez F, Barsness G et al., Long-term prognosis of complete percutaneous coronary revascularisation in patients with diabetes with multivessel disease, Heart 101(15) :1233–1239, 2015. Crossref, Web of Science, Google Scholar
19. Lingling W, Structural design and biomechanical analysis of cardiovascular stents, Southeast University, 2016. Google Scholar
20. Stents I, Services H, Guidance for Industry an FDA staff non-clinical engineering tests and recommended labeling for intravascular stentsand associated delivery systems, Maryland, 2010, pp. 14–19. Google Scholar
21. Pelton A, Gong X, Duerig T. Fatigue testing of diamond-shaped specimens, Proc Conf Mater Process Med Dev 2003(2) :199–204, 2003. Google Scholar
22. Duerig TW, Pelton AR, Stocke1 D, An overview of nitinol medical applications, Mater Sci Eng A 273(1) :149–160, 1999. Crossref, Web of Science, Google Scholar
23. Haiquan F, Ruimin Z, Qingsong H, Zhiguo W, Finite element simulation and analysis of fatigue strength of endovascular stents, J Funct Mater 45(14) :14087–14091+14098, 2014. Google Scholar
24. Brown MW, Mil1er KJ, A theory for fatigue failure under multiaxial stress-strain conditions, Proc Inst Mechanical Eng 187(1) :745–755, 1973. Crossref, Google Scholar
25. Zhihao S, Weidong M, Gui C, Guoxing Z, Liancai M, Finite element analysis of mechanical properties of candy-plug NiTi Alloy vascular stents, Chin J Rare Metals 44(7) :706–715, 2020. Google Scholar
26. Tianqi W, Haiquan F, Kun W, A comparative study on mechanical properties of lower limb arterial stents at various deformation modes, J Biomed Eng 38(2) :303–309, 2021. Google Scholar
27. Northeast R, Constable M, Burton HE et al., Mechanical testing of glutaraldehyde cross-linked mitral valves. Part one: In vitro mechanical behaviour, Proc Inst Mech Eng H-J Eng Med 235(3) :281–290, 2021. Crossref, Web of Science, Google Scholar
28. Constable M, Northeast R, Lawless BM et al., Mechanical testing of glutaraldehyde cross-linked mitral valves. Part two: Elastic and viscoelastic properties of chordae tendineae, Proc Inst Mech En H-J Eng Med 235(3) :291–299, 2021. Crossref, Web of Science, Google Scholar