Axial prestretch and circumferential distensibility in biomechanics of abdominal aorta

Horny, Lukas; Netušil, Marek; Voňavková, Tereza

doi:10.1007/s10237-013-0534-8

Cited by 74 publications

(64 citation statements)

References 47 publications

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“…Considering the boundary conditions σ rr (r i )¼ ÀP and σ rr (r o )¼ 0, the equilibrium equations in the radial and axial direction have the form (7) and (8), respectively. Here P denotes internal pressure and F red is the reduced axial (prestretching) force acting on the closed end of the tube additionally to the force generated by the pressure acting on the end (Horný et al, 2014a(Horný et al, , 2014bMatsumoto and Hayashi, 1996).…”

Section: Thick-walled Tube Modelmentioning

confidence: 99%

Constitutive modeling of human saphenous veins at overloading pressures

Vesely¹,

Horny²,

Chlup³

et al. 2015

Journal of the Mechanical Behavior of Biomedical Materials

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In the present study, inflation tests with free axial extension of 15 human vena saphena magna were conducted ex vivo to obtain data suitable for multi-axial constitutive modeling at overloading conditions (pressures up to approximately 15kPa). Subsequently the data were fitted with a hyperelastic, nonlinear and anisotropic constitutive model based on the theory of the closed thick-walled tube. It was observed that initial highly deformable behavior (up to approximately 2.5kPa) in the pressure-circumferential stretch response is followed by progressive large strain stiffening. Contrary to that, samples were much stiffer in longitudinal direction, where the observed stretches were in the range 0.98-1.03 during the entire pressurization in most cases. The effect of possible residual stress was evaluated in a simulation of the intramural stress distribution with the opening angle prescribed to 0°, 10°, 20°, 30°, 40°, and 50°. The result suggests that the optimal opening angle making the stress distribution through the wall thickness uniform is about 40°. The material parameters presented here are suitable for use in mechanobiological simulations describing the adaptation of the autologous vein wall after bypass surgery.

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Section: Thick-walled Tube Modelmentioning

confidence: 99%

Constitutive modeling of human saphenous veins at overloading pressures

Vesely¹,

Horny²,

Chlup³

et al. 2015

Journal of the Mechanical Behavior of Biomedical Materials

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“…The data provided in the Supplement 1 can be directly used in biomechanical models of the porcine aorta that are based on histological findings (Sokolis, 2010;Horný et al, 2014aHorný et al, , 2014b. According to the Delesse principle (Howard and Reed, 1998), the area fractions occupied by the components are consistent estimates of the corresponding volume fractions of these components.…”

Section: Study Implicationsmentioning

confidence: 99%

Segmental and age differences in the elastin network, collagen, and smooth muscle phenotype in the tunica media of the porcine aorta

Tonar

Kubíková

Prior

et al. 2015

Annals of Anatomy - Anatomischer Anzeiger

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“…However, when considering the passive properties of blood vessels only, the contribution of elastin and collagen fibers predominates (Chen et al 2013). Having a relatively low stiffness, elastin fibers support the vascular wall at low pressures, considering also the prestretch of elastin (Cheng et al 2013;Horný et al 2014). Stiff collagen fibers with a nonuniform waviness protect the wall from excessive dilatation (Lanir 1983).…”

Section: Relevance Of the Results To The Biomechanicsmentioning

confidence: 99%

Segmental differences in the orientation of smooth muscle cells in the tunica media of porcine aortae

Tonar

Kochová

Cimrman

et al. 2014

Biomech Model Mechanobiol

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The orientation of vascular smooth muscle cells of porcine aortae was assessed to test the widely accepted assumption that these smooth muscle cells are arranged in two helices. We used tangential histological sections of 82 samples of five anatomical segments of thoracic and abdominal porcine aortae and three age groups in animals ranging in age from 5 to 210 days. The distribution of the orientation of smooth muscle cell nuclei in five proximodistal segments of the porcine aortae was determined using an algorithm that fitted a mixture of one to five von Mises probability distributions of the data retrieved from histological micrographs. Automated tracking of the nuclei was confirmed by and consistent with manual histological analysis. The orientation of the vascular smooth muscle cells was successfully fitted using two von Mises distributions in most of the samples with different ages, wall thicknesses, and anatomical positions, which corresponds to two populations of vascular smooth muscle cells. A minor fraction of samples also required a tertiary von Mises distribution to describe the orientation of the smooth muscle cell nuclei. The distribution of vascular smooth muscle cells in five aortic segments ranging from the thoracic ascending aorta to the abdominal intrarenal aorta exhibited similar main directions but different shapes. These results are consistent with the widely used model of two muscular helices intermingling in the arterial wall. Furthermore, we calculated the central angles of symmetry and the mean value of angles between the two assumed smooth muscle directions. We also successfully approximated the orientation of the smooth muscle cells using a mixture of von Mises distributions and our open-source software named dist_mixtures. This method is openly available to researchers who are interested in mathematically assessing the orientation of cell nuclei in various tissues.

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Axial prestretch and circumferential distensibility in biomechanics of abdominal aorta

Cited by 74 publications

References 47 publications

Constitutive modeling of human saphenous veins at overloading pressures

Constitutive modeling of human saphenous veins at overloading pressures

Segmental and age differences in the elastin network, collagen, and smooth muscle phenotype in the tunica media of the porcine aorta

Segmental differences in the orientation of smooth muscle cells in the tunica media of porcine aortae

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