Arterial Wall Mechanics in Conscious Dogs: Assessment of Viscous, Inertial, and Elastic Moduli to Characterize Aortic Wall Behavior

To evaluate arterial physiopathology, complete arterial wall mechanical characterization is necessary. This study presents a model for determining the elastic response of elastin (sigmaE, where sigma is stress), collagen (sigmaC), and smooth muscle (sigmaSM) fibers and viscous (sigmaeta) and inertia...

Full description

Saved in:
Bibliographic Details
Published in:Circulation research 1995-03, Vol.76 (3), p.468-478
Main Authors: Armentano, Ricardo Luis, Barra, Juan Gabriel, Levenson, Jaime, Simon, Alain, Pichel, Ricardo Horacio
Format: Article
Language:English
Subjects:
Animals
Aorta - physiology
Biological and medical sciences
Biomechanical Phenomena
Blood vessels and receptors
Collagen - physiology
Dogs
Elasticity
Elastin - physiology
Fundamental and applied biological sciences. Psychology
Male
Muscle, Smooth, Vascular - physiology
Stress, Mechanical
Vertebrates: cardiovascular system
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:To evaluate arterial physiopathology, complete arterial wall mechanical characterization is necessary. This study presents a model for determining the elastic response of elastin (sigmaE, where sigma is stress), collagen (sigmaC), and smooth muscle (sigmaSM) fibers and viscous (sigmaeta) and inertial (sigmaM) aortic wall behaviors. Our work assumes that the total stress developed by the wall to resist stretching is governed by the elastic modulus of elastin fibers (E sub E), the elastic modulus of collagen (EC) affected by the fraction of collagen fibers (fC) recruited to support wall stress, and the elastic modulus of the maximally contracted vascular smooth muscle (ESM) affected by an activation function (fA). We constructed the constitutive equation of the aortic wall on the basis of three different hookean materials and two nonlinear functions, fA and fCEquation 5 and Equation 6 where epsilon is strain and epsilon0E is strain at zero stress. Stress-strain relations in the control state and during activation of smooth muscle (phenylephrine, 5 mu g centered dot kg 1 centered dot min 1 IV) were obtained by transient occlusions of the descending aorta and the inferior vena cava in 15 conscious dogs by using descending thoracic aortic pressure (microtransducer) and diameter (sonomicrometry) measurements. The fC was not linear with strain, and at the onset of significant collagen participation in the elastic response (break point of the stress-strain relation), 6.02 plus minus 2.6% collagen fibers were recruited at 23% of stretching of the unstressed diameter. The fA exhibited a skewed unimodal curve with a maximum level of activation at 28.3 plus minus 7.9% of stretching. The aortic wall dynamic behavior was modified by activation increasing viscous (eta) and inertial (M) moduli from the control to active state (viscous, 3.8 plus minus 1.3 times 10 to 7.8 plus minus 1.1 times 10 dyne centered dot s centered dot cm 2, P less than .0005; inertial, 61 plus minus 42 to 91 plus minus 23 dyne centered dot s centered dot cm 2, P less than .05). Finally, the purely elastic stress-strain relation was assessed by subtracting the viscous and inertial behaviors.(Circ Res. 1995;76:468-478.)
ISSN:0009-7330
1524-4571
DOI:10.1161/01.res.76.3.468