Research Status and Development Trends of the Heart Valve Mechanical Properties_Journal of Biomedical Engineering

Authors：

 LIYusheng , ZENGPei , RENGuorong

Research Center of Fluid Machinery Engineering and Technology, Jiangsu University, Zhenjiang 212013, China;

Corresponding author：

LIYusheng, Email: lys0410@foxmail.com

Keywords：

heart valve; mechanical property; uniaxial tension; biaxial tension; constitutive model

DOI：

10.7507/1001-5515.20140219

Video：

Export PDF Favorites Scan Get Citation

Abstract Full text Figures/Tables Video References Cited by

The study of mechanical properties on heart valves can provide an important theoretical basis for doctors to repair heart valves and prosthetic valve materials research. In this paper, we present the current status of the mechanical property study methods of heart valve, expound the methods and special requirements about uniaxial tensile test and biaxial tensile test of the heart valve, and further discuss several establishment methods of heart valve constitutive models. We also discuss the development trend of heart valve mechanics.

Citation： LIYusheng, ZENGPei, RENGuorong. Research Status and Development Trends of the Heart Valve Mechanical Properties. Journal of Biomedical Engineering, 2014, 31(5): 1160-1163. doi: 10.7507/1001-5515.20140219 Copy

1.	HE Zhaoming. Mitral valve mechanics and function[J]. 医用生物力学,2010,25(S1):47-48.
2.	BIIIIAR K L, SACKS M S. A method to quantify the fiber kinematics of planar tissues under biaxial stretch[J].J Biomech. 1997, 30(7):753-756.
3.	PATEL S S,MORSI Y S, Making of functional tissue engineered heart valve[C] //26th Southern Biomedical Engineering Conference.Maryland,USA: 2010: 180-182.
4.	HSIAO A, LUSTIG M, ALLEY M T, et al. Evaluation of valvular insufficiency and shunts with parallel-imaging compressed-sensing 4D phase-contrast MR imaging with stereoscopic 3D velocity-fusion volume-rendered visualization [J]. Radiology, 2012, 265(1):87-95.
5.	陈善良,许莉,王雪梅,等.戊二醛鞣制驴心包与牛心包的体外力学性能比较[J]. 山东大学学报(医学版),2012,50(6):42-45.
6.	SANCHEZ-AREVALO F M, FARFAN M, COVARRUBIAS D, et al. The micromechanical behavior of lyophilized glutaraldehyde-treated bovine pericardium under uniaxial tension[J]. J Mech Behav Biomed Mater, 2010,3(8):640-646.
7.	刁颖敏. 组织工程瓣的拉伸试验及力学参数的选取[J].力学季刊,2004,25(1):140-144.
8.	陈炜生,杨胜生,陈龙,等.10名正常人二尖瓣膜的一维拉伸测试[J].福建医药杂志,2001,23(4):89-91.
9.	PROT V, SKALLERUD B , SOMMER G , et al. On modelling and analysis of healthy and pathological human mitral valves: two case studies [J]. J Mech Behav Biomed Mater, 2010,3(2):167-177.
10.	BILLIAR K L, SACKS M S. Biaxial mechanical properties of the natural and glutaraldehyde treated aortic valve cusp--Part Ⅰ: Experimental results[J]. J Biomech Eng, 2000,122(1):23-30.
11.	罗华安,王化明,游有鹏.超弹性膜的等轴拉伸试验方法及仿真[J].华南理工大学学报(自然科学版),2011,39(4):56-61.
12.	崔彬,刘迎龙,谢宁,等.同种异体人心脏主动脉与肺动脉瓣膜的生物力学比较[J].中国组织工程研究与临床康复,2010,14(18):3352-3354.
13.	王树志,李晓阳,李坤.人体主动脉弓周向应力的非线性数值模型研究[J].医用生物力学,2011,26(1):43-50.
14.	ALBANNA M Z,BOU-AKL T H,WALTERS H L ,et al. Improving the mechanical properties of chitosan-based heart valve scaffolds using chitosan fibers[J]. J Mech Behav Biomed Mater, 2012, 5(1):171-180.
15.	王春敏. 针织复合材料力学性能的研究[J]. 材料导报,2011,25(S2):277-280.
16.	SZOSTKIEWIEZ C,HAMELIN P. Stiffness identifieation and tearing analysis for coated membranes under biaxial loads[J]. Journal of Industrial Textiles,2000,30(2):128-145.
17.	刘君,林小军.生物软组织的正交各向异性超弹性材料模型及数值模拟[J].兰州工业高等专科学校学报,2011,18(3):52-57.
18.	MAY-NEWMAN K, YIN F C, Biaxial mechanical behavior of excised porcine mitral valve[J]. Am J Physiol, 1995, 269(4 Pt 2): H1319-H1327.
19.	罗华安,赵大旭.基于NI-DAQ的双轴拉伸试验平台的设计和实现[J].机床与液压,2010,38(22):9-12.
20.	NATALI A N, PAVAN P G, SCARPA C. Numerical analysis of tooth mobility: formulation of a non-linear constitutive law for the periodontal ligament[J].Dent Mater, 2004,20(7):623-629.
21.	田聪,万荣欣,刘欣, 等.生物交联剂京尼平交联牛心包生物支架材料的性能[J].中国生物医学工程学报,2011,30(2):281-286.
22.	BILLIAR K L, SACKS M S. Biaxial mechanical properties of the native and glutaraldehyde-treated aortic valve cusp: Part Ⅱ--A structural constitutive model[J]. J Biomech Eng, 2000,122(4):327-335.
23.	XU H, QUAN Y, HUA C, et al. Influence of material thickness to the dynamic mechanical properties of bioprosthetic heart valve[J].Adv Mater Research, 2012,502(7): 479-484.
24.	QUAN Y, ZHU H Y, HUA C.Construction parametric model and stress analysis of the biopresthetic heart valve[C]//2nd IEEE International Conference on Information Management and Engineering. China: 2010:141-145.
25.	朱海燕. 基于ANSYS/LS-DYNA的生物瓣膜动态力学性能分析[D]. 济南: 山东大学, 2011.
26.	彭礼清,余建群,杨志刚,等.双源CT评价正常肺动脉瓣形态学及动态特征[J]. 生物医学工程学杂志,2012,29(5):862-866.
27.	KOURSERA C A, WOOD N B, SEED W A, et al. A numerical study of aortic flow stability and comparison with in vivo flow measurements [J]. J Biomech Eng, 2013, 135(1): 011003.

1. HE Zhaoming. Mitral valve mechanics and function[J]. 医用生物力学,2010,25(S1):47-48.
2. BIIIIAR K L, SACKS M S. A method to quantify the fiber kinematics of planar tissues under biaxial stretch[J].J Biomech. 1997, 30(7):753-756.
3. PATEL S S,MORSI Y S, Making of functional tissue engineered heart valve[C] //26th Southern Biomedical Engineering Conference.Maryland,USA: 2010: 180-182.
4. HSIAO A, LUSTIG M, ALLEY M T, et al. Evaluation of valvular insufficiency and shunts with parallel-imaging compressed-sensing 4D phase-contrast MR imaging with stereoscopic 3D velocity-fusion volume-rendered visualization [J]. Radiology, 2012, 265(1):87-95.
5. 陈善良,许莉,王雪梅,等.戊二醛鞣制驴心包与牛心包的体外力学性能比较[J]. 山东大学学报(医学版),2012,50(6):42-45.
6. SANCHEZ-AREVALO F M, FARFAN M, COVARRUBIAS D, et al. The micromechanical behavior of lyophilized glutaraldehyde-treated bovine pericardium under uniaxial tension[J]. J Mech Behav Biomed Mater, 2010,3(8):640-646.
7. 刁颖敏. 组织工程瓣的拉伸试验及力学参数的选取[J].力学季刊,2004,25(1):140-144.
8. 陈炜生,杨胜生,陈龙,等.10名正常人二尖瓣膜的一维拉伸测试[J].福建医药杂志,2001,23(4):89-91.
9. PROT V, SKALLERUD B , SOMMER G , et al. On modelling and analysis of healthy and pathological human mitral valves: two case studies [J]. J Mech Behav Biomed Mater, 2010,3(2):167-177.
10. BILLIAR K L, SACKS M S. Biaxial mechanical properties of the natural and glutaraldehyde treated aortic valve cusp--Part Ⅰ: Experimental results[J]. J Biomech Eng, 2000,122(1):23-30.
11. 罗华安,王化明,游有鹏.超弹性膜的等轴拉伸试验方法及仿真[J].华南理工大学学报(自然科学版),2011,39(4):56-61.
12. 崔彬,刘迎龙,谢宁,等.同种异体人心脏主动脉与肺动脉瓣膜的生物力学比较[J].中国组织工程研究与临床康复,2010,14(18):3352-3354.
13. 王树志,李晓阳,李坤.人体主动脉弓周向应力的非线性数值模型研究[J].医用生物力学,2011,26(1):43-50.
14. ALBANNA M Z,BOU-AKL T H,WALTERS H L ,et al. Improving the mechanical properties of chitosan-based heart valve scaffolds using chitosan fibers[J]. J Mech Behav Biomed Mater, 2012, 5(1):171-180.
15. 王春敏. 针织复合材料力学性能的研究[J]. 材料导报,2011,25(S2):277-280.
16. SZOSTKIEWIEZ C,HAMELIN P. Stiffness identifieation and tearing analysis for coated membranes under biaxial loads[J]. Journal of Industrial Textiles,2000,30(2):128-145.
17. 刘君,林小军.生物软组织的正交各向异性超弹性材料模型及数值模拟[J].兰州工业高等专科学校学报,2011,18(3):52-57.
18. MAY-NEWMAN K, YIN F C, Biaxial mechanical behavior of excised porcine mitral valve[J]. Am J Physiol, 1995, 269(4 Pt 2): H1319-H1327.
19. 罗华安,赵大旭.基于NI-DAQ的双轴拉伸试验平台的设计和实现[J].机床与液压,2010,38(22):9-12.
20. NATALI A N, PAVAN P G, SCARPA C. Numerical analysis of tooth mobility: formulation of a non-linear constitutive law for the periodontal ligament[J].Dent Mater, 2004,20(7):623-629.
21. 田聪,万荣欣,刘欣, 等.生物交联剂京尼平交联牛心包生物支架材料的性能[J].中国生物医学工程学报,2011,30(2):281-286.
22. BILLIAR K L, SACKS M S. Biaxial mechanical properties of the native and glutaraldehyde-treated aortic valve cusp: Part Ⅱ--A structural constitutive model[J]. J Biomech Eng, 2000,122(4):327-335.
23. XU H, QUAN Y, HUA C, et al. Influence of material thickness to the dynamic mechanical properties of bioprosthetic heart valve[J].Adv Mater Research, 2012,502(7): 479-484.
24. QUAN Y, ZHU H Y, HUA C.Construction parametric model and stress analysis of the biopresthetic heart valve[C]//2nd IEEE International Conference on Information Management and Engineering. China: 2010:141-145.
25. 朱海燕. 基于ANSYS/LS-DYNA的生物瓣膜动态力学性能分析[D]. 济南: 山东大学, 2011.
26. 彭礼清,余建群,杨志刚,等.双源CT评价正常肺动脉瓣形态学及动态特征[J]. 生物医学工程学杂志,2012,29(5):862-866.
27. KOURSERA C A, WOOD N B, SEED W A, et al. A numerical study of aortic flow stability and comparison with in vivo flow measurements [J]. J Biomech Eng, 2013, 135(1): 011003.

Journal of Biomedical Engineering

Research Status and Development Trends of the Heart Valve Mechanical Properties

Abstract Full text Figures/Tables Video References Cited by

Previous Article

Next Article

Format

Content