Biaxial mechanical properties of the human thoracic and abdominal aorta, common carotid, subclavian, renal and common iliac arteries

Biomechanics and Modeling in Mechanobiology

Volumn 13, Issue 6, 2014, Pages 1341-1359

  Kamenskiy, Alexey V ^a   Dzenis, Yuris A ^b   Kazmi, Syed A Jaffar ^a   Pemberton, Mark A ^a   Pipinos, Iraklis I ^a,c   Phillips, Nick Y ^d   Herber, Kyle ^e   Woodford, Thomas ^e   Bowen, Robert E ^f   Lomneth, Carol S ^a   MacTaggart, Jason N ^a  

^a UNIVERSITY OF NEBRASKA MEDICAL CENTER   (United States)

^b UNIVERSITY OF NEBRASKA LINCOLN   (United States)

^c VA NEBRASKA WESTERN IOWA HEALTH CARE SYSTEM   (United States)

^d University of Nebraska Lincoln   (United States)

^e Nebraska Organ Recovery System   (United States)

^f Physicians Laboratory Services   (United States)

Author keywords

Aorta; Carotid artery; Iliac artery; Mechanical properties; Renal artery; Subclavian artery

Indexed keywords

ANISOTROPY; BIOMECHANICS; BLOOD VESSELS; CONSTITUTIVE MODELS; DISEASES; GLYCOPROTEINS;

ABDOMINAL AORTA; AORTA; ARTERIAL DISEASE; BIAXIAL MECHANICAL PROPERTIES; CAROTID ARTERY; COMMON CAROTIDS; ILIAC ARTERIES; RENAL ARTERIES; SUBCLAVIAN ARTERY; THORACIC AORTA;

ELASTIN;

ABDOMINAL AORTA; ADOLESCENT; ADULT; AGED; ARTERY; BIOLOGICAL MODEL; BIOMECHANICS; COMMON CAROTID ARTERY; DEMOGRAPHY; FEMALE; HUMAN; ILIAC ARTERY; KIDNEY ARTERY; MALE; MECHANICAL STRESS; MIDDLE AGED; PHYSIOLOGY; SUBCLAVIAN ARTERY; THORACIC AORTA; VERY ELDERLY; YOUNG ADULT;

ADOLESCENT; ADULT; AGED; AGED, 80 AND OVER; AORTA, ABDOMINAL; AORTA, THORACIC; ARTERIES; BIOMECHANICAL PHENOMENA; CAROTID ARTERY, COMMON; DEMOGRAPHY; FEMALE; HUMANS; ILIAC ARTERY; MALE; MIDDLE AGED; MODELS, BIOLOGICAL; RENAL ARTERY; STRESS, MECHANICAL; SUBCLAVIAN ARTERY; YOUNG ADULT;

EID: 84919461773     PISSN: 16177959     EISSN: 16177940     Source Type: Journal    
DOI: 10.1007/s10237-014-0576-6     Document Type: Article

References (47)

1. Abel D (2013) Off-label medical device use. Endovasc, Today
2. Baek S, Gleason RL, Rajagopal KR, Humphrey JD (2007) Theory of small on large: potential utility in computations of fluid-solid interactions in arteries. Comput Methods Appl Mech Eng 196:3070–3078. doi:10.1016/j.cma.2006.06.018
3. Choi G, Cheng CP, Wilson NM, Taylor CA (2009) Methods for quantifying three-dimensional deformation of arteries due to pulsatile and nonpulsatile forces: implications for the design of stents and stent grafts. Ann Biomed Eng 37:14–33. doi:10.1007/s10439-008-9590-0
4. Chuong CJ, Fung YC (1986) On residual stresses in arteries. J Biomech Eng 108:189–92
5. Criscione JC (2003) Rivlin’s representation formula is Ill-conceived for the determination of response functions via biaxial testing. J Elast 70:129–147. doi:10.1023/B:ELAS.0000005586.01024.95
6. Criscione JC (2005) A constitutive framework for tubular structures that enables a semi-inverse solution to extension and inflation. J Elast 77:57–81. doi:10.1007/s10659-005-2155-7
7. Criscione JC (2008) Kinematics framework optimized for deformation, growth, and remodeling in vascular organs. Biomech Model Mechanobiol 7:285–93. doi:10.1007/s10237-007-0103-0
8. Ferruzzi J, Vorp DA, Humphrey JD (2011) On constitutive descriptors of the biaxial mechanical behaviour of human abdominal aorta and aneurysms. J R Soc Interface 8:435–450
9. Fung YC (1993) Biomechanics: mechanical properties of living tissue. Springer, New York
10. Gasser TC, Ogden RW, Holzapfel GA (2006) Hyperelastic modeling of arterial layers with distributed collagen fibre orientations. J R Soc Interface 3:15–35. doi:10.1098/rsif.2005.0073
11. Gleason RL, Dye WW, Wilson E, Humphrey JD (2008) Quantification of the mechanical behavior of carotid arteries from wild-type, dystrophin-deficient, and sarcoglycan-delta knockout mice. J Biomech 41:3213–3218. doi:10.1016/j.jbiomech.2008.08.012
12. Go AS, Mozaffarian D, Roger VL et al (2013) Heart disease and stroke statistics-2013 update: a report from the American Heart Association. Circulation 127:e6–e245. doi:10.1161/CIR.0b013e31828124ad
13. Grashow JS (2005) Evaluation of the biaxial mechanical properties of the mitral valve anterior leaflet under physiological loading conditions. University of Pittsburgh, Pittsburgh
14. Holzapfel GA, Ogden RW (2009) Constitutive modelling of passive myocardium: a structurally based framework for material characterization. Philisophical Trans R Soc A 367:3445–3475
15. Holzapfel GA, Ogden RW (2010a) Constitutive modeling of arteries. Proc R Soc 466:1551–1597. doi:10.1098/rspa.2010.0058
16. Holzapfel GA, Ogden RW (2010b) Modelling the layer-specific three-dimensional residual stresses in arteries, with an application to the human aorta. J R Soc Interface 7:787–799
17. Holzapfel GA, Gasser TC, Ogden RW, W OR (2000) A new constitutive framework for arterial wall mechanics and a comparative study of material models. J Elast 61:1–48
18. Holzapfel GA, Sommer G, Gasser CT, Regitnig P (2005) Determination of layer-specific mechanical properties of human coronary arteries with nonatherosclerotic intimal thickening and related constitutive modeling. Am J Physiol Hear Circ Physiol 289:H2048–H2058. doi:10.1152/ajpheart.00934.2004
19. Holzapfel GA, Sommer G, Auer M et al (2007) Layer-specific 3D residual deformations of human aortas with non-atherosclerotic intimal thickening. Ann Biomed Eng 35:530–545
20. Hsiao H-M, Nikanorov A, Prabhu S, Razavi MK (2009) Respiration-induced kidney motion on cobalt-chromium stent fatigue resistance. J Biomed Mater Res B Appl Biomater 91:508–16. doi:10.1002/jbm.b.31424
21. Humphrey JD (2002) Cardiovascular solid mechanics: cells, tissues, and organs. Springer, New York
22. Humphrey JD, Eberth JF, Dye WW, Gleason RL (2009) Fundamental role of axial stress in compensatory adaptations by arteries. J Biomech 42:1–8. doi:10.1016/j.jbiomech.2008.11.011.Fundamental
23. Kamenskiy AV, Pipinos II, MacTaggart J et al (2011) Comparative analysis of the biaxial mechanical behavior of carotid wall tissue and biological and synthetic materials used for carotid patch angioplasty. J Biomech Eng 133:111008
24. Kamenskiy AV, Pipinos II, Dzenis YA et al (2014) Passive biaxial mechanical properties and in vivo axial pre-stretch of the diseased human femoropopliteal and tibial arteries. Acta Biomater 10:1301–1313. doi:10.1016/j.actbio.2013.12.027
25. Kural MMH, Cai M, Tang D et al (2012) Planar biaxial characterization of diseased human coronary and carotid arteries for computational modeling. J Biomech 45:790–798. doi:10.1016/j.jbiomech.2011.11.019.Planar
26. Learoyd BM, Taylor MG (1966) Alterations with age in the viscoelastic properties of human arterial walls. Circ Res 18:278–292. doi:10.1161/01.RES.18.3.278
27. Mithieux SM, Weiss AS (2005) Elastin. Adv Protein Chem 70:437–61. doi:10.1016/S0065-3233(05)70013-9
28. Ogden RW, Saccomandi G, I S (2004) Fitting hyperelastic models to experimental data. Comput Mech 34:484–502
29. Ogden R (2009) Anisotropy and nonlinear elasticity in arterial wall mechanics. Biomech Model Mol Cell Tissue Levels 508:179–258
30. Rezakhaniha R, Agianniotis A, Schrauwen JTC et al (2012) Experimental investigation of collagen waviness and orientation in the arterial adventitia using confocal laser scanning microscopy. Biomech Model Mechanobiol 11:461–473. doi:10.1007/s10237-011-0325-z
31. Rhodin JAG (1980) Architechture of the vessel wall. Handb. Physiol. Cardiovasc. Syst. Americal Physiological Society, Bethesda, pp 1–31
32. Sacks MS, Chuong CJ (1998) Orthotropic mechanical properties of chemically treated bovine pericardium. Ann Biomed Eng 26:892–902
33. Sacks MS (2000) Biaxial mechanical evaluation of planar biological materials. J Elast 61:199–246
34. Sacks MS, Sun W (2003) Multiaxial mechanical behavior of biological materials. Annu Rev Biomed Eng 5:251–284
35. Schulze-Bauer CaJ, Morth C, Holzapfel GA (2003) Passive biaxial mechanical response of aged human iliac arteries. J Biomech Eng 125:395. doi:10.1115/1.1574331
36. Sokolis DP, Sassani S, Kritharis EP, Tsangaris S (2011) Differential histomechanical response of carotid artery in relation to species and region: mathematical description accounting for elastin and collagen anisotropy. Med Biol Eng Comput 49:867–879
37. Sommer G, Holzapfel GA (2012) 3D constitutive modeling of the biaxial mechanical response of intact and layer-dissected human carotid arteries. J Mech Behav Biomed Mater 5:116–128. doi:10.1016/j.jmbbm.2011.08.013
38. Sommer G, Regitnig P, Koltringer L, Holzapfel GA (2010) Biaxial mechanical properties of intact and layer-dissected human carotid arteries at physiological and supra-physiological loadings. Am J Physiol Heart, Circ Physiol 298(3):H898–H912
39. Takamizawa K, Hayashi K (1987) Strain energy density function and uniform strain hypothesis for arterial mechanics. J Biomech 20:7–17
40. Tseders E, Purinya B (1975) The mechanical properties of human blood vessels relative to their location. Mech Compos Mater 11(2):271–275
41. Vande-Geest JP, Sacks MS, Vorp DA (2004) Age dependency of the biaxial biomechanical behavior of human abdominal aorta. J Biomech Eng 126:815–822
42. Vande-Geest JP, Sacks MS, Vorp DA (2006) A planar biaxial constitutive relation for the luminal layer of intra-luminal thrombus in abdominal aortic aneurysms. J Biomech 39:2347–2354
43. Wicker BK, Hutchens HP, Wu Q et al (2008) Normal basilar artery structure and biaxial mechanical behaviour. Comput Methods Biomech Biomed Engin 11:539–51. doi:10.1080/10255840801949793
44. World Health Organization (2011) The World Health report. Fact Sheet N310
45. Yin FC, Chew PH, Zeger SL (1986) An approach to quantification stress-strain of biaxial tissue data. J Biomech 19:27–37
46. Zeller PJ, Skalak TC (1998) Contribution of individual structural components in determining the zero-stress state in small arteries. J Vasc Res 35:8–17
47. Zieman SJ, Melenovsky V, Kass Da (2005) Mechanisms, pathophysiology, and therapy of arterial stiffness. Arterioscler Thromb Vasc Biol 25:932–943. doi:10.1161/01.ATV.0000160548.78317.29