In vivo characterization of the aortic wall stress-strain relationship.

Arterial stiffness has been shown to be a good indicator of arterial wall disease. However, a single parameter is insufficient to describe the complex stress-strain relationship of a multi-component, non-linear tissue such as the aorta. We therefore propose a new approach to measure the stress-strain relationship locally in vivo noninvasively, and present a clinically relevant parameter describing the mechanical interaction between aortic wall constituents. The slope change of the circumferential stress-strain curve was hypothesized to be related to the contribution of elastin and collagen, and was defined as the transition strain (epsilon(theta)(T)). A two-parallel spring model was employed and three Young's moduli were accordingly evaluated, i.e., corresponding to the: elastic lamellae (E(1)), elastin-collagen fibers (E(2)) and collagen fibers (E(3)). Our study was performed on normal and Angiotensin II (AngII)-treated mouse abdominal aortas using the aortic pressure after catheterization and the local aortic wall diameters change from a cross-correlation technique on the radio frequency (RF) ultrasound signal at 30 MHz and frame rate of 8 kHz. Using our technique, the transition strain and three Young's moduli in both normal and pathological aortas were mapped in 2D. The slope change of the circumferential stress-strain curve was first observed in vivo under physiologic conditions. The transition strain was found at a lower strain level in the AngII-treated case, i.e., 0.029+/-0.006 for the normal and 0.012+/-0.004 for the AngII-treated aortas. E(1), E(2) and E(3) were equal to 69.7+/-18.6, 214.5+/-65.8 and 144.8+/-55.2 kPa for the normal aortas, and 222.1+/-114.8, 775.0+/-586.4 and 552.9+/-519.1 kPa for the AngII-treated aortas, respectively. This is because of the alteration of structures and content of the wall constituents, the degradation of elastic lamella and collagen formation due to AngII treatment. While such values illustrate the alteration of structure and content of the wall constituents related to AngII treatment, limitations regarding physical assumptions (isotropic, linear elastic) should be kept in mind. The transition strain, however, was shown to be a pressure independent parameter that can be clinically relevant and noninvasively measured using ultrasound-based motion estimation techniques. In conclusion, our novel methodology can assess the stress-strain relationship of the aortic wall locally in vivo and quantify important parameters for the detection and characterization of vascular disease.

[1]  K. Hayashi Cardiovascular solid mechanics. Cells, tissues, and organs , 2003 .

[2]  R. Armentano,et al.  Assessment of elastin and collagen contribution to aortic elasticity in conscious dogs. , 1991, The American journal of physiology.

[3]  S. Glagov,et al.  Transmural Organization of the Arterial Media: The Lamellar Unit Revisited , 1985, Arteriosclerosis.

[4]  K Kramer,et al.  A new method for measurement of blood pressure, heart rate, and activity in the mouse by radiotelemetry. , 2000, Journal of applied physiology.

[5]  W. Nichols,et al.  McDonald's Blood Flow in Arteries: Theoretical, Experimental and Clinical Principles , 1998 .

[6]  R H Cox,et al.  Viscoelastic properties of canine pulmonary arteries. , 1984, The American journal of physiology.

[7]  S. Glagov,et al.  Structural Basis for the Static Mechanical Properties of the Aortic Media , 1964, Circulation research.

[8]  R. Armentano,et al.  Arterial wall mechanics in conscious dogs. Assessment of viscous, inertial, and elastic moduli to characterize aortic wall behavior. , 1995, Circulation research.

[9]  H S Borovetz,et al.  Identification of elastic properties of homogeneous, orthotropic vascular segments in distension. , 1995, Journal of biomechanics.

[10]  R. Cox Comparison of arterial wall mechanics in normotensive and spontaneously hypertensive rats. , 1979, American Journal of Physiology.

[11]  Jonas Stålhand,et al.  Parameter Identification in Arteries Using Constraints , 2006 .

[12]  ValérieMarque,et al.  Aortic Wall Mechanics and Composition in a Transgenic Mouse Model of Marfan Syndrome , 2001 .

[13]  F P T Baaijens,et al.  A computational model for collagen fibre remodelling in the arterial wall. , 2004, Journal of theoretical biology.

[14]  B L Langille,et al.  Determinants of mechanical properties in the developing ovine thoracic aorta. , 1999, The American journal of physiology.

[15]  Wei Lu,et al.  Alopecia areata: pathogenesis and potential for therapy , 2006, Expert Reviews in Molecular Medicine.

[16]  Namrata Gundiah,et al.  Determination of strain energy function for arterial elastin: Experiments using histology and mechanical tests. , 2007, Journal of biomechanics.

[17]  Y. Fung,et al.  Biomechanics: Mechanical Properties of Living Tissues , 1981 .

[18]  W. Kübler,et al.  Aortic pressure-diameter relationship assessed by intravascular ultrasound: experimental validation in dogs. , 1999, The American journal of physiology.

[19]  On the in-series and in-parallel contribution of elastin assessed by a structure-based biomechanical model of the arterial wall. , 2008, Journal of biomechanics.

[20]  T. Ozawa,et al.  Accuracy of a continuous blood pressure monitor based on arterial tonometry. , 1993, Hypertension.

[21]  A J Hall,et al.  Aortic Wall Tension as a Predictive Factor for Abdominal Aortic Aneurysm Rupture: Improving the Selection of Patients for Abdominal Aortic Aneurysm Repair , 2000, Annals of vascular surgery.

[22]  E. Konofagou,et al.  A Novel Noninvasive Technique for Pulse-Wave Imaging and Characterization of Clinically-Significant Vascular Mechanical Properties In Vivo , 2007, Ultrasonic imaging.

[23]  Charles A. Taylor,et al.  The three-dimensional micro- and nanostructure of the aortic medial lamellar unit measured using 3D confocal and electron microscopy imaging. , 2008, Matrix Biology.

[24]  P. Canham,et al.  Three-dimensional collagen organization of human brain arteries at different transmural pressures. , 1995, Journal of vascular research.

[25]  Jos A E Spaan,et al.  Elasticity of passive blood vessels: a new concept. , 2003, American journal of physiology. Heart and circulatory physiology.

[26]  Alan Daugherty,et al.  Mouse Models of Abdominal Aortic Aneurysms , 2004, Arteriosclerosis, thrombosis, and vascular biology.

[27]  G. Holzapfel Determination of material models for arterial walls from uniaxial extension tests and histological structure. , 2006, Journal of theoretical biology.

[28]  John C Rutledge,et al.  Angiotensin II injures the arterial wall causing increased aortic stiffening in apolipoprotein E-deficient mice. , 2002, American journal of physiology. Regulatory, integrative and comparative physiology.

[29]  C. Kielty Elastic fibres in health and disease , 2006, Expert Reviews in Molecular Medicine.

[30]  S Marakas,et al.  Pressure-diameter relation of the human aorta. A new method of determination by the application of a special ultrasonic dimension catheter. , 1995, Circulation.

[31]  H. Nakamura,et al.  Electron microscopic study of the prenatal development of the thoracic aorta in the rat. , 1988, The American journal of anatomy.

[32]  B. Strauss,et al.  Biochemical analysis of collagen and elastin synthesis in the balloon injured rat carotid artery. , 2002, Cardiovascular pathology : the official journal of the Society for Cardiovascular Pathology.

[33]  Y. Fung Elasticity of soft tissues in simple elongation. , 1967, The American journal of physiology.

[34]  R H Cox,et al.  Passive mechanics and connective tissue composition of canine arteries. , 1978, The American journal of physiology.

[35]  W. von Maltzahn,et al.  Experimental measurements of elastic properties of media and adventitia of bovine carotid arteries. , 1984, Journal of biomechanics.

[36]  A. Becker,et al.  Extracellular matrix of the human aortic media: An ultrastructural histochemical and immunohistochemical study of the adult aortic media , 2000, The Anatomical record.

[37]  A. Klarbring,et al.  Towards in vivo aorta material identification and stress estimation , 2004, Biomechanics and modeling in mechanobiology.

[38]  J. Cockcroft,et al.  Assessment of arterial stiffness in clinical practice. , 2002, QJM : monthly journal of the Association of Physicians.

[39]  R. Ogden,et al.  Hyperelastic modelling of arterial layers with distributed collagen fibre orientations , 2006, Journal of The Royal Society Interface.

[40]  R. Armentano,et al.  Assessment of smooth muscle contribution to descending thoracic aortic elastic mechanics in conscious dogs. , 1993, Circulation research.

[41]  A. Saada Elasticity : theory and applications , 1993 .

[42]  M. Entman,et al.  Noninvasive determination of pulse-wave velocity in mice. , 1997, The American journal of physiology.

[43]  T Yamamura,et al.  Arterial tonometry for noninvasive, continuous blood pressure monitoring during anesthesia. , 1991, Anesthesiology.

[44]  H. W. Weizsäcker,et al.  Biomechanical behavior of the arterial wall and its numerical characterization , 1998, Comput. Biol. Medicine.

[45]  G. Holzapfel,et al.  Stress-driven collagen fiber remodeling in arterial walls , 2007 .

[46]  Alan Daugherty,et al.  Abdominal aortic aneurysms: fresh insights from a novel animal model of the disease , 2002, Vascular medicine.

[47]  M. Safar,et al.  Increased Carotid Wall Elastic Modulus and Fibronectin in Aldosterone-Salt–Treated Rats: Effects of Eplerenone , 2002, Circulation.

[48]  C. Kielty,et al.  Elastic fibres in health and disease , 2006, Expert Reviews in Molecular Medicine.

[49]  Gerhard A. Holzapfel,et al.  A viscoelastic model for fiber-reinforced composites at finite strains: Continuum basis, computational aspects and applications , 2001 .

[50]  Kozaburo Hayashi,et al.  A strain energy function for arteries accounting for wall composition and structure. , 2004, Journal of biomechanics.

[51]  H. Struijker‐Boudier,et al.  Expert consensus document on arterial stiffness: methodological issues and clinical applications. , 2006, European heart journal.

[52]  R. Vito,et al.  Blood vessel constitutive models-1995-2002. , 2003, Annual review of biomedical engineering.

[53]  R. Ogden,et al.  A New Constitutive Framework for Arterial Wall Mechanics and a Comparative Study of Material Models , 2000 .

[54]  H. Gregersen,et al.  Static elastic wall properties of the abdominal porcine aorta in vitro and in vivo. , 1997, European journal of vascular and endovascular surgery : the official journal of the European Society for Vascular Surgery.

[55]  C. Hayward,et al.  Gender-related differences in the central arterial pressure waveform. , 1997, Journal of the American College of Cardiology.

[56]  J. Staessen,et al.  Clinical applications of arterial stiffness; definitions and reference values. , 2002, American journal of hypertension.

[57]  N. Stergiopulos,et al.  Effect of elastin degradation on carotid wall mechanics as assessed by a constituent-based biomechanical model. , 2007, American journal of physiology. Heart and circulatory physiology.

[58]  Y C Fung,et al.  Elastic and inelastic properties of the canine aorta and their variation along the aortic tree. , 1974, Journal of biomechanics.

[59]  M. Epstein,et al.  Cardiovascular Solid Mechanics: Cells, Tissues, and Organs , 2002 .

[60]  Jianwen Luo,et al.  Pulse Wave Imaging of Normal and Aneurysmal Abdominal Aortas In Vivo , 2009, IEEE Transactions on Medical Imaging.

[61]  L. Bortel Is arterial stiffness ready for daily clinical practice , 2006 .

[62]  J.M.A. Lenihan,et al.  Biomechanics — Mechanical properties of living tissue , 1982 .

[63]  D P Sokolis,et al.  Effect of impaired vasa vasorum flow on the structure and mechanics of the thoracic aorta: implications for the pathogenesis of aortic dissection. , 2000, European journal of cardio-thoracic surgery : official journal of the European Association for Cardio-thoracic Surgery.