Effects of a sustained extension on arterial growth and remodeling: a theoretical study

Three recent studies reveal that the unloaded length of a carotid artery increases significantly and rapidly in response to sustained increases in axial extension. Moreover, such lengthening involves an “unprecedented” increase in the rate of turnover of cells and matrix. Although current data are n...

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Bibliographic Details
Published in:Journal of biomechanics 2005-06, Vol.38 (6), p.1255-1261
Main Authors: Gleason, R.L., Humphrey, J.D.
Format: Article
Language:English
Subjects:
Adaptation
Adaptation, Physiological - physiology
Animals
Arteries
Blood pressure
Blood Pressure - physiology
Carotid arteries
Carotid Arteries - growth & development
Carotid Arteries - physiology
Collagen
Computer Simulation
Elasticity
Extracellular Matrix - physiology
Humans
Kinematics
Mechanotransduction, Cellular - physiology
Mixture theory
Models, Cardiovascular
Muscle, Smooth, Vascular - physiopathology
Ordinary differential equations
Physical Stimulation - methods
Residual stress
Smooth muscle
Stress, Mechanical
Stress–strain
Veins & arteries
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Summary:Three recent studies reveal that the unloaded length of a carotid artery increases significantly and rapidly in response to sustained increases in axial extension. Moreover, such lengthening involves an “unprecedented” increase in the rate of turnover of cells and matrix. Although current data are not sufficient for detailed biomechanical analyses, we present general numerical simulations that are consistent with the reported observations and support the hypothesis that rates of turnover correlate with the extent that stresses are perturbed from normal. In particular, a 3-D analysis of wall stress suggests that moderate (15%) increases in axial extension can increase the axial stress to a much greater extent than marked (50%) increases in blood pressure increase the circumferential stress. Furthermore, such increases in axial stress can occur without inducing significant gradients in stress within the wall. Consequently, we use a new, 2-D constrained mixture model to study evolving changes in the geometry, structure, and properties of carotid arteries in response to a sustained increase in axial extension. These simulations are qualitatively similar to the reports in the literature and support the notion that the stress-free lengths of individual constituents evolve during growth and remodeling.
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2004.06.017