Fluid-solid coupling model and analysis on pulse wave propagation properties of iliac artery_Journal of Biomedical Engineering

Authors：

SUN Xuehang , LI Bensen , LU Yicheng ,  MIAO Fuxing

Key laboratory of impact and safety engineering, Ningbo University, Ningbo, Zhejiang 315211, P. R. China;

Corresponding author：

MIAO Fuxing, Email: miaofuxing@nbu.edu.cn

Keywords：

Pressure pulse wave; Velocity pulse wave; Vascular bifurcation; Fluid-solid coupling analysis; Numerical simulation

DOI：

10.7507/1001-5515.202306004

Video：

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In this work, we investigated the influence of the bifurcation geometry of the iliac artery on the propagation properties of the pulse wave, and applied software to establish the straight bifurcation and curved bifurcation bi-directional fluid-solid coupling finite element analysis models based on the iliac artery, and compared and analyzed the influence of the bifurcation angle of the blood vessel on the propagation characteristics of the pulse wave. It was found that the bifurcation geometry had a significant effect on the pulse wave propagation in the iliac arteries, and the pressure and velocity pulse wave amplitudes predicted by these two models had a good agreement with that before the vessel bifurcation in a cardiac cycle. The curvilinear bifurcation model predicted the pulse wave amplitude to be lower and the pressure drop to be smaller after the bifurcation, which was more in line with the actual situation of the human body. In addition, the bifurcation point is accompanied by the stress concentration phenomenon in the vessel wall, and there is a transient increase in the velocity pulse waveform amplitude, which was consistent with the fact that the bifurcation site is prone to phenomena such as arterial stenosis and hardening. The preliminary results of this paper will provide some reference for the use of pulse waveforms in the diagnosis of arterial diseases.

Citation： SUN Xuehang, LI Bensen, LU Yicheng, MIAO Fuxing. Fluid-solid coupling model and analysis on pulse wave propagation properties of iliac artery. Journal of Biomedical Engineering, 2024, 41(2): 351-359. doi: 10.7507/1001-5515.202306004 Copy

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2.	张永会, 高长青, 王嵘. 脉搏波分析方法及其应用. 北京生物医学工程, 2019, 38(3): 319-326.
3.	Zhong Q, Hu M J, Cui Y J, et al. Carotid–femoral pulse wave velocity in the prediction of cardiovascular events and mortality: an updated systematic review and meta-analysis. Angiology, 2018, 69(7): 617-629.
4.	Kim J H, Kim M Y, Lee J U, et al. Waveform analysis of the brachial-ankle pulse wave velocity in hemiplegic stroke patients and healthy volunteers: a pilot study. J Phys Ther Sci, 2014, 26(4): 501-504.
5.	Gajdova J, Karasek D, Goldmannova D, et al. Pulse wave analysis and diabetes mellitus: a systematic review. Biomed Pap Med Fac Univ Palacky Olomouc Czech Repub, 2017, 161(3): 223-233.
6.	Wang P, Mao Y M, Zhao C N, et al. Increased pulse wave velocity in systemic lupus erythematosus: a meta-analysis. Angiology, 2018, 69(3): 228-235.
7.	İsmail O Y, Olcay M D, Barıs A, et al. Endovascular management of iatrogenic iliac rupture during atheterectomy treatment for steno-occlusive iliac artery disease: case report. Am J Cardiol, 2018, 121(8): 155.
8.	Lin M S , Drucker C B , Morales D , et al. Spontaneous thrombosis of an isolated internal iliac artery aneurysm. Ann Vasc Surg, 2021, 73(21): 545-548.
9.	陈斌, 符伟国, 郭大乔, 等. 血管腔内支架治疗动脉狭窄性病变的临床分析. 中华外科杂志, 2001, 39(12): 911-914.
10.	陈忠, 吴庆华, 杨宝钟, 等. 主髂动脉破裂外科治疗23例体会. 中华普通外科杂志, 2005, 20(12): 771-773.
11.	Perktold K, Resch M. Numerical flow studies in human carotid artery bifurcations: basic discussion of the geometric factor in atherogenesis. J Med Biol Eng, 1990, 12(2): 111-123.
12.	Perktold K, Resch M, Peter R O. Three-dimensional numerical analysis of pulsatile flow and wall shear stress in the carotid artery bifurcation. J Biomech, 1991, 24(6): 409-420.
13.	王青, 王炜哲, 万大伟, 等. 三例人体颈动脉分叉管血液动力学的数值对比分析. 水动力学研究与进展A辑, 2009, 24(3): 313-319.
14.	Kotmakova A A, GataulinY A, Yukhnev A D, et al. The abdominal aorta bifurcation with iliac arteries: the wall elasticity effect on the flow structure. St Petersbg, 2020, 13(50): 68-76.
15.	于风旭, 邓明彬, 陈槐卿, 等. 人颈动脉分叉模型流场分布的数值模拟. 第三军医大学学报, 2007, 29(24): 2336-2338.
16.	Abbasi B, Darvish A, Akhavan R, et al. Decreased pulmonary artery bifurcation angle: a novel imaging criterion for the diagnosis of chronic pulmonary thromboembolism. Iran J Med Sci, 2022, 47(4): 360-366.
17.	彭红梅, 杨德全. 双分叉动脉血流动力学特性的边界元分析. 医用生物力学, 2010, 25(4): 283-287.
18.	张丽娜, 周润景, 武佩, 等. 基于心电、脉搏波信号的动脉硬化无创检测. 生物医学工程学杂志, 2016, 33(4): 631-638,644.
19.	Westerhof N, Bosman F, De Vries C J, et al. Analog studies of the human systemic arterial tree. J Biomech, 1969, 2(2): 121-143.
20.	牛朝诗, 张为龙. 髂总动脉分支及其临床意义. 广东解剖学通报, 1991, 13(2): 1-3.
21.	陈锡昌, 张友云, 张耕臣. 腹主动脉叉的几何解剖及血流动力学分析. 数理医药学杂志, 1993, 6(3): 1-4.
22.	Wang S H, Lee L P, Lee J S. A linear relation between the compressibility and density of blood. J Acoust Soc Am, 2001, 109(1): 390-396.
23.	Urick R J. A sound velocity method for determining the compressibility of finely divided substances. J Appl Phys, 1947, 18(11): 983-987.
24.	Laurent S, Girerd X, Mourad J J, et al. Elastic modulus of the radial artery wall material is not increased in patients with essential hypertension. Arterioscler Thromb, 1994, 14(7): 1223-1231.
25.	刘莹, 罗院明, 殷艳飞, 等. 动脉内流-固耦合作用下两相血流动力学数值模拟. 介入放射学杂志, 2017, 26(3): 253-257.
26.	Wu C, Liu X, Ghista D, et al. Effect of plaque compositions on fractional flow reserve in a fluid-structure interaction analysis. Biomech Model Mechanobiol, 2021, 21(1): 203-220.
27.	佀友友, 丁兆东. Y型分叉狭窄动脉血管中血液流动的数值模拟. 应用数学进展, 2021, 10(5): 1631-1638.
28.	梅志军. 结构-负荷失衡在腹主动脉瘤形成中的作用. 上海: 第二军医大学, 2004.
29.	刘明, 孙安强, 邓小燕. 主动脉瘤位置对内脏分支动脉血流动力学的影响. 第五届中美生物医学工程暨海内外生物力学学术研讨会论文集, 2013: 115.

1. 乔爱科, 伍时桂. 动脉中的脉搏波理论. 生物医学工程学杂志, 2000, 17(1): 95-100,106.
2. 张永会, 高长青, 王嵘. 脉搏波分析方法及其应用. 北京生物医学工程, 2019, 38(3): 319-326.
3. Zhong Q, Hu M J, Cui Y J, et al. Carotid–femoral pulse wave velocity in the prediction of cardiovascular events and mortality: an updated systematic review and meta-analysis. Angiology, 2018, 69(7): 617-629.
4. Kim J H, Kim M Y, Lee J U, et al. Waveform analysis of the brachial-ankle pulse wave velocity in hemiplegic stroke patients and healthy volunteers: a pilot study. J Phys Ther Sci, 2014, 26(4): 501-504.
5. Gajdova J, Karasek D, Goldmannova D, et al. Pulse wave analysis and diabetes mellitus: a systematic review. Biomed Pap Med Fac Univ Palacky Olomouc Czech Repub, 2017, 161(3): 223-233.
6. Wang P, Mao Y M, Zhao C N, et al. Increased pulse wave velocity in systemic lupus erythematosus: a meta-analysis. Angiology, 2018, 69(3): 228-235.
7. İsmail O Y, Olcay M D, Barıs A, et al. Endovascular management of iatrogenic iliac rupture during atheterectomy treatment for steno-occlusive iliac artery disease: case report. Am J Cardiol, 2018, 121(8): 155.
8. Lin M S , Drucker C B , Morales D , et al. Spontaneous thrombosis of an isolated internal iliac artery aneurysm. Ann Vasc Surg, 2021, 73(21): 545-548.
9. 陈斌, 符伟国, 郭大乔, 等. 血管腔内支架治疗动脉狭窄性病变的临床分析. 中华外科杂志, 2001, 39(12): 911-914.
10. 陈忠, 吴庆华, 杨宝钟, 等. 主髂动脉破裂外科治疗23例体会. 中华普通外科杂志, 2005, 20(12): 771-773.
11. Perktold K, Resch M. Numerical flow studies in human carotid artery bifurcations: basic discussion of the geometric factor in atherogenesis. J Med Biol Eng, 1990, 12(2): 111-123.
12. Perktold K, Resch M, Peter R O. Three-dimensional numerical analysis of pulsatile flow and wall shear stress in the carotid artery bifurcation. J Biomech, 1991, 24(6): 409-420.
13. 王青, 王炜哲, 万大伟, 等. 三例人体颈动脉分叉管血液动力学的数值对比分析. 水动力学研究与进展A辑, 2009, 24(3): 313-319.
14. Kotmakova A A, GataulinY A, Yukhnev A D, et al. The abdominal aorta bifurcation with iliac arteries: the wall elasticity effect on the flow structure. St Petersbg, 2020, 13(50): 68-76.
15. 于风旭, 邓明彬, 陈槐卿, 等. 人颈动脉分叉模型流场分布的数值模拟. 第三军医大学学报, 2007, 29(24): 2336-2338.
16. Abbasi B, Darvish A, Akhavan R, et al. Decreased pulmonary artery bifurcation angle: a novel imaging criterion for the diagnosis of chronic pulmonary thromboembolism. Iran J Med Sci, 2022, 47(4): 360-366.
17. 彭红梅, 杨德全. 双分叉动脉血流动力学特性的边界元分析. 医用生物力学, 2010, 25(4): 283-287.
18. 张丽娜, 周润景, 武佩, 等. 基于心电、脉搏波信号的动脉硬化无创检测. 生物医学工程学杂志, 2016, 33(4): 631-638,644.
19. Westerhof N, Bosman F, De Vries C J, et al. Analog studies of the human systemic arterial tree. J Biomech, 1969, 2(2): 121-143.
20. 牛朝诗, 张为龙. 髂总动脉分支及其临床意义. 广东解剖学通报, 1991, 13(2): 1-3.
21. 陈锡昌, 张友云, 张耕臣. 腹主动脉叉的几何解剖及血流动力学分析. 数理医药学杂志, 1993, 6(3): 1-4.
22. Wang S H, Lee L P, Lee J S. A linear relation between the compressibility and density of blood. J Acoust Soc Am, 2001, 109(1): 390-396.
23. Urick R J. A sound velocity method for determining the compressibility of finely divided substances. J Appl Phys, 1947, 18(11): 983-987.
24. Laurent S, Girerd X, Mourad J J, et al. Elastic modulus of the radial artery wall material is not increased in patients with essential hypertension. Arterioscler Thromb, 1994, 14(7): 1223-1231.
25. 刘莹, 罗院明, 殷艳飞, 等. 动脉内流-固耦合作用下两相血流动力学数值模拟. 介入放射学杂志, 2017, 26(3): 253-257.
26. Wu C, Liu X, Ghista D, et al. Effect of plaque compositions on fractional flow reserve in a fluid-structure interaction analysis. Biomech Model Mechanobiol, 2021, 21(1): 203-220.
27. 佀友友, 丁兆东. Y型分叉狭窄动脉血管中血液流动的数值模拟. 应用数学进展, 2021, 10(5): 1631-1638.
28. 梅志军. 结构-负荷失衡在腹主动脉瘤形成中的作用. 上海: 第二军医大学, 2004.
29. 刘明, 孙安强, 邓小燕. 主动脉瘤位置对内脏分支动脉血流动力学的影响. 第五届中美生物医学工程暨海内外生物力学学术研讨会论文集, 2013: 115.

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