Abstract
The vascular wall exhibits nonlinear anisotropic mechanical properties. The identification of a strain energy function (SEF) is the preferred method to describe its complex nonlinear elastic properties. Earlier constituent-based SEF models, where elastin is modeled as an isotropic material, failed in describing accurately the tissue response to inflation–extension loading. We hypothesized that these shortcomings are partly due to unaccounted anisotropic properties of elastin. We performed inflation–extension tests on common carotid of rabbits before and after enzymatic degradation of elastin and applied constituent-based SEFs, with both an isotropic and an anisotropic elastin part, on the experimental data. We used transmission electron microscopy (TEM) and serial block-face scanning electron microscopy (SBFSEM) to provide direct structural evidence of the assumed anisotropy. In intact arteries, the SEF including anisotropic elastin with one family of fibers in the circumferential direction fitted better the inflation–extension data than the isotropic SEF. This was supported by TEM and SBFSEM imaging, which showed interlamellar elastin fibers in the circumferential direction. In elastin-degraded arteries, both SEFs succeeded equally well in predicting anisotropic wall behavior. In elastase-treated arteries fitted with the anisotropic SEF for elastin, collagen engaged later than in intact arteries. We conclude that constituent-based models with an anisotropic elastin part characterize more accurately the mechanical properties of the arterial wall when compared to models with simply an isotropic elastin. Microstructural imaging based on electron microscopy techniques provided evidence for elastin anisotropy. Finally, the model suggests a later and less abrupt collagen engagement after elastase treatment.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Briggman KL, Denk W (2006) Towards neural circuit reconstruction with volume electron microscopy techniques. Curr Opin Neurobiol 16: 562–570
Clark JM, Glagov S (1979) Structural integration of the arterial-wall.1. Relationships and attachments of medial smooth-muscle cells in normally distended and hyper-distended aortas. Lab. Invest. 40: 587–602
Clark JM, Glagov S (1985) Transmural organization of the arterial media—the lamellar unit revisited. Arteriosclerosis 5: 19–34
Daamen WF, Hafmans T, Veerkamp JH, Van Kuppevelt TH (2001) Comparison of five procedures for the purification of insoluble elastin. Biomaterials 22: 1997–2005
Denk W, Horstmann H (2004) Serial block-face scanning electron microscopy to reconstruct three-dimensional tissue nanostructure. PLoS Biol 2: e329
Dingemans KP, Teeling P, Lagendijk JH, Becker AE (2000) Extracellular matrix of the human aortic media: an ultrastructural histochemical and immunohistochemical study of the adult aortic media. Anat Rec 258: 1–14
Dobrin PB (1989) Patho-physiology and pathogenesis of aortic-aneurysms-current concepts. Surg Clin North Am 69: 687–703
Dobrin PB, Canfield TR (1984) Elastase, collagenase, and the biaxial elastic properties of dog carotid-artery. Am J Physiol 247: H124–H131
Driessen NJB, Bouten CVC, Baaijens FPT (2005) A structural constitutive model for collagenous cardiovascular tissues incorporating the angular fiber distribution. J Biomech Eng-Trans Asme 127: 494–503
Driessen NJB, Bouten CVC, Baaijens FPT (2005) A structural constitutive model for collagenous cardiovascular tissues incorporating the angular fiber distribution. J Biomech Eng 127: 494–503
Fonck E, Prod’hom G, Roy S, Augsburger L, Rufenacht D, Stergiopulos N (2007) Effect of elastin degredation on carotid wall mechanics as assessed by a constituent-based biomechanical model. Am J Physiol Heart Circ Physiol 292: H2754–H2763
Fung YC, Fronek K, Patitucci P (1979) Pseudoelasticity of arteries and the choice of its mathematical expression. Am J Physiol 237: H620–H631
Gasser TC, Ogden RW, Holzapfel GA (2006) Hyperelastic modelling of arterial layers with distributed collagen fibre orientations. J Royal Soc Interf 3: 15–35
Grut W, Edwards J, Evans EJ (1977) Scanning electron microscopy of freeze-dried aortic elastin. J Microsc 110: 271–275
Gundiah N, Ratcliffe BM, Pruitt AL (2007) Determination of strain energy function for arterial elastin: experiments using histology and mechanical tests. J Biomech 40: 586–594
Gundiah N, Ratcliffe MB, Pruitt LA (2009) The biomechanics of arterial elastin. J Mech Behav Biomed Mater 2: 288–296
Hayashi K, Takamizawa K, Nakamura T, Kato T, Tsushima N (1987) Effects of elastase on the stiffness and elastic properties of arterial-walls in cholesterol-fed rabbits. Atherosclerosis 66: 259–267
Holzapfel GA, Gasser TC, Ogden RW (2000) A new constitutive framework for arterial wall mechanics and a comparative study of material models. J Elast 61: 1–48
Holzapfel GA, Weizsacker HW (1998) Biomechanical behavior of the arterial wall and its numerical characterization. Comput Biol Med 28: 377–392
Humphery JD (2002) Cardiovascular solid mechanics: cells, tissues and organs. Springer, New York
Lillie MA, Gosline JM (1990) The effects of hydration on the dynamic mechanical properties of elastin. Biopolymers 29: 1147–1160
O’Connell MK, Murthy S, Phan S, Xu C, Buchanan J, Spilker R, Dalman RL, Zarins CK, Denk W, Taylor CA (2008) The three-dimensional micro- and nanostructure of the aortic medial lamellar unit measured using 3D confocal and electron microscopy imaging. Matrix Biol 27: 171–181
Rezakhaniha R, Stergiopulos N (2008) A structural model of the venous wall considering elastin anisotropy. J Biomech Eng 130. doi:10.1115/1111.2907749
Roy S, Silacci P, Stergiopulos N (2005) Biomechanical proprieties of decellularized porcine common carotid arteries. Am J Physiol Heart Circ Physiol 289: H1567–H1576
Roy S, Tsamis A, Prod’hom G, Stergiopulos N (2008) On the in-series and in-parallel contribution of elastin assessed by a structure-based biomechanical model of the arterial wall. J Biomech 41: 737–743
Silver FH, Snowhill PB, Foran DJ (2003) Mechanical behavior of vessel wall: a comparative study of aorta, vena cava, and carotid artery. Ann Biomed Eng 31: 793–803
Treloar LRG (1942) Thermodynamic study of the elastic extension of rubber. Trans Faraday Soc 293–298
VanDijk AM, Wieringa PA, van der Meer M, Laird JD (1984) Mechanics of resting isolated single vascular smooth muscle cells from bovine coronary artery. Am J Physiol 246: C277–287
Vito RP, Dixon SA (2003) Blood vessel constitutive models-1995-2002. Ann Rev Biomed Eng 5: 413–439
Watton PN, Ventikos Y, Holzapfel GA (2009) Modelling the mechanical response of elastin for arterial tissue. J Biomech 42: 1320–1325
Zhou J, Fung YC (1997) The degree of nonlinearity and anisotropy of blood vessel elasticity. Proc Natl Acad Sci USA 94: 14255–14260
Zulliger MA, Fridez P, Stergiopulos N, Hayashi K (2004a) A strain energy function for arteries accounting for wall composition and structure. J Biomech 37: 989–1000
Zulliger MA, Stergiopulos N, Rachev A (2004b) A constitutive formulation of arterial mechanics including vascular smooth muscle tone. Am J Physiol Heart Circ Physiol 287: H1335–1343
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Rezakhaniha, R., Fonck, E., Genoud, C. et al. Role of elastin anisotropy in structural strain energy functions of arterial tissue. Biomech Model Mechanobiol 10, 599–611 (2011). https://doi.org/10.1007/s10237-010-0259-x
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10237-010-0259-x