Uniform transmural strain in pre-stressed arteries occurs at physiological pressure

Michel Destrade; Yi Liu; Jeremiah G. Murphy; Ghassan S. Kassab

doi:10.1016/j.jtbi.2012.03.010

Uniform transmural strain in pre-stressed arteries occurs at physiological pressure

Michel Destrade, Yi Liu, Jeremiah G. Murphy, Ghassan S. Kassab

Research output: Contribution to a Journal (Peer & Non Peer) › Article › peer-review

22 Citations (Scopus)

Abstract

Residual deformation (strain) exists in arterial vessels, and has been previously proposed to induce homogeneous transmural strain distribution. In this work, we present analytical formulations that predict the existence of a finite internal (homeostatic) pressure for which the transmural deformation is homogenous, and the corresponding stress field. We provide evidence on the physical existence of homeostatic pressure when the artery is modeled as an incompressible tube with orthotropic constitutive strain-energy function. Based on experimental data of rabbit carotid arteries and porcine coronary arteries, the model predicts a homeostatic mean pressure of ~90. mmHg and 70-120. mmHg, respectively. The predictions are well within the physiological pressure range. Some consequences of this strain homogeneity in the physiological pressure range are explored under the proposed assumptions.

Original language	English
Pages (from-to)	93-97
Number of pages	5
Journal	Journal of Theoretical Biology
Volume	303
DOIs	https://doi.org/10.1016/j.jtbi.2012.03.010
Publication status	Published - 21 Jun 2012
Externally published	Yes

Keywords

Arterial tissue
Homeostatic strain
Mathematical modeling
Opening angle
Residual strain

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10.1016/j.jtbi.2012.03.010

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title = "Uniform transmural strain in pre-stressed arteries occurs at physiological pressure",

abstract = "Residual deformation (strain) exists in arterial vessels, and has been previously proposed to induce homogeneous transmural strain distribution. In this work, we present analytical formulations that predict the existence of a finite internal (homeostatic) pressure for which the transmural deformation is homogenous, and the corresponding stress field. We provide evidence on the physical existence of homeostatic pressure when the artery is modeled as an incompressible tube with orthotropic constitutive strain-energy function. Based on experimental data of rabbit carotid arteries and porcine coronary arteries, the model predicts a homeostatic mean pressure of ~90. mmHg and 70-120. mmHg, respectively. The predictions are well within the physiological pressure range. Some consequences of this strain homogeneity in the physiological pressure range are explored under the proposed assumptions.",

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AU - Destrade, Michel

AU - Liu, Yi

AU - Murphy, Jeremiah G.

AU - Kassab, Ghassan S.

PY - 2012/6/21

Y1 - 2012/6/21

N2 - Residual deformation (strain) exists in arterial vessels, and has been previously proposed to induce homogeneous transmural strain distribution. In this work, we present analytical formulations that predict the existence of a finite internal (homeostatic) pressure for which the transmural deformation is homogenous, and the corresponding stress field. We provide evidence on the physical existence of homeostatic pressure when the artery is modeled as an incompressible tube with orthotropic constitutive strain-energy function. Based on experimental data of rabbit carotid arteries and porcine coronary arteries, the model predicts a homeostatic mean pressure of ~90. mmHg and 70-120. mmHg, respectively. The predictions are well within the physiological pressure range. Some consequences of this strain homogeneity in the physiological pressure range are explored under the proposed assumptions.

AB - Residual deformation (strain) exists in arterial vessels, and has been previously proposed to induce homogeneous transmural strain distribution. In this work, we present analytical formulations that predict the existence of a finite internal (homeostatic) pressure for which the transmural deformation is homogenous, and the corresponding stress field. We provide evidence on the physical existence of homeostatic pressure when the artery is modeled as an incompressible tube with orthotropic constitutive strain-energy function. Based on experimental data of rabbit carotid arteries and porcine coronary arteries, the model predicts a homeostatic mean pressure of ~90. mmHg and 70-120. mmHg, respectively. The predictions are well within the physiological pressure range. Some consequences of this strain homogeneity in the physiological pressure range are explored under the proposed assumptions.

KW - Arterial tissue

KW - Homeostatic strain

KW - Mathematical modeling

KW - Opening angle

KW - Residual strain

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JO - Journal of Theoretical Biology

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Uniform transmural strain in pre-stressed arteries occurs at physiological pressure

Abstract

Keywords

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