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Arterial biomechanics and the influences of pulsatility on growth and remodeling

Arterial wall morphology depends strongly on the hemodynamic environment
experienced in vivo. The mammalian heart pumps blood through rhythmic contractions forcing
blood vessels to undergo cyclic, mechanical stimulation in the form of pulsatile blood pressure
and flow. While it has been shown that stepwise, chronic increases in blood pressure and flow
modify arterial wall thickness and diameter respectively, few studies on arterial remodeling have
examined the influences that pulsatility (i.e., the range of cyclic stimuli) may have on biaxial
wall morphology. We experimentally studied the biaxial behavior of carotid arteries from 8
control (CCA), 15 transgenic, and 21 mechanically altered mice using a custom designed
mechanical testing device and correlated those results with hemodynamic measurements using
pulsed Doppler.
In this dissertation, we establish that increased pulsatile stimulation in the right carotid
artery after banding (RCCA-B) has a strong affect on wall morphological parameters that peak at
2 weeks and include thickness (CCA=24.8±0.878, RCCA-B=99.0±8.43 μ m), inner diameter
(CCA=530±7.36, RCCA-B=680±32.0μ m), and in vivo axial stretch (CCA=1.7±0.029, RCCAB=
1.19±0.067). These modifications entail stress and the change in stress across the cardiac
cycle from an arterial wall macro-structural point of view (i.e., cellular and extracellular matrix) citing increases in collagen mass fraction (CCA=0.223±0.056, RCCA-B=0.314±0.011), collagen
to elastin ratio (CCA=0.708±0.152, RCCA-B=1.487±0.26), and cross-sectional cellular nuclei
counts (CCA=298±58.9, RCCA-B=578±28.3 cells) at 0, 7, 10, 14, and 42 post-banding surgery.
Furthermore, we study the biomechanical properties of carotid arteries from a transgenic mouse
of Marfan Syndrome. This arterial disease experiences increased pulse transmission and our
findings indicate that alterations occur primarily in the axial direction. The above results are all
applied to a predictive biaxial model of Cauchy stress vs. strain.

Identiferoai:union.ndltd.org:tamu.edu/oai:repository.tamu.edu:1969.1/ETD-TAMU-3117
Date15 May 2009
CreatorsEberth, John Francis
ContributorsHumphrey, Jay D
Source SetsTexas A and M University
Languageen_US
Detected LanguageEnglish
TypeBook, Thesis, Electronic Dissertation, text
Formatelectronic, application/pdf, born digital

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