The fiber orientation in the coronary arterial wall at physiological loading evaluated with a two-fiber constitutive model

Horst, A Arjen van der; Broek, CN Chantal van den; Vosse, F.N. van de; Rutten, Mcm Marcel

doi:10.1007/s10237-011-0331-1

Cited by 14 publications

(17 citation statements)

References 41 publications

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“…The mechanical tests clearly demonstrate hysteresis effects and thus indicate a viscoelastic component. However, axial prestretch as reported in arteries of young healthy humans or mammals and equal to ≈1.3-1.4 [43,44] could not be taken into account due to the limitations of the experimental setup (uniaxial testing). When focusing on the SSI data measured along the (presumed) tissue's circumferential direction (0 ∘ /180 ∘ ), SSI measurements varied cyclically with the same period as imposed by the uniaxial testing.…”

Section: Discussionmentioning

confidence: 99%

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Supersonic Shear Wave Imaging to Assess Arterial Nonlinear Behavior and Anisotropy: Proof of Principle via Ex Vivo Testing of the Horse Aorta

Shcherbakova

Papadacci

Swillens

et al. 2014

Advances in Mechanical Engineering

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Supersonic shear wave imaging (SSI) is a noninvasive, ultrasound-based technique to quantify the mechanical properties of bulk tissues by measuring the propagation speed of shear waves (SW) induced in the tissue with an ultrasound transducer. The technique has been successfully validated in liver and breast (tumor) diagnostics and is potentially useful for the assessment of the stiffness of arteries. However, SW propagation in arteries is subjected to different wave phenomena potentially affecting the measurement accuracy. Therefore, we assessed SSI in a less complex ex vivo setup, that is, a thick-walled and rectangular slab of an excised equine aorta. Dynamic uniaxial mechanical testing was performed during the SSI measurements, to dispose of a reference material assessment. An ultrasound probe was fixed in an angle position controller with respect to the tissue to investigate the effect of arterial anisotropy on SSI results. Results indicated that SSI was able to pick up stretch-induced stiffening of the aorta. SW velocities were significantly higher along the specimen's circumferential direction than in the axial direction, consistent with the circumferential orientation of collagen fibers. Hence, we established a first step in studying SW propagation in anisotropic tissues to gain more insight into the feasibility of SSI-based measurements in arteries.

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Section: Discussionmentioning

confidence: 99%

“…where is the shear modulus (kPa), is the elasticity modulus (kPa), is the tissue density assumed to be 1066 kg/m 3 [43], and is the group shear wave speed (m/s), which was assumed to be equal to the median SWS value derived over 15 depths for each time point.…”

Section: Ssi Acquisition and Data Analysismentioning

confidence: 99%

Supersonic Shear Wave Imaging to Assess Arterial Nonlinear Behavior and Anisotropy: Proof of Principle via Ex Vivo Testing of the Horse Aorta

Shcherbakova

Papadacci

Swillens

et al. 2014

Advances in Mechanical Engineering

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“…In van der Horst et al [20], it was demonstrated that a model based on the two-fiber constitutive model developed by Holzapfel et al [17] was able to accurately capture the radius-pressure relations of porcine and human coronary arteries. In that model the arterial wall was modeled as a cross-ply of helically wound fibers embedded in a cylinder composed of hyperelastic material.…”

Section: Methodsmentioning

confidence: 99%

“…It was assumed that in compression no stress can be transmitted by the fibers, with τ f defined as:

\begin{matrix} τ_{f} = k_{1} λ_{f}^{2} (λ_{f}^{2} - 1) e^{k_{2} {(λ_{f}^{normal2} - normal1)}^{2}} if λ_{f} \geq 1 \\ τ_{f} = 0 if λ_{f} < 1 . \end{matrix}

Here, λ f is the collagen fiber stretch and k 1 and k 2 are constants determining the stress-stretch relation of the collagen fibers. For coronary arteries the value of these four parameters have been determined [20]. With removal of the outliers, the median of the four parameters are: G = 19.3 kPa, k 1 = 2.01 kPa, k 2 = 5.10, β 0 = 34.6°.…”

Section: Methodsmentioning

confidence: 99%

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Towards Patient-Specific Modeling of Coronary Hemodynamics in Healthy and Diseased State

Horst

Boogaard

Veer

et al. 2013

Computational and Mathematical Methods in Medicine

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A model describing the primary relations between the cardiac muscle and coronary circulation might be useful for interpreting coronary hemodynamics in case multiple types of coronary circulatory disease are present. The main contribution of the present study is the coupling of a microstructure-based heart contraction model with a 1D wave propagation model. The 1D representation of the vessels enables patient-specific modeling of the arteries and/or can serve as boundary conditions for detailed 3D models, while the heart model enables the simulation of cardiac disease, with physiology-based parameter changes. Here, the different components of the model are explained and the ability of the model to describe coronary hemodynamics in health and disease is evaluated. Two disease types are modeled: coronary epicardial stenoses and left ventricular hypertrophy with an aortic valve stenosis. In all simulations (healthy and diseased), the dynamics of pressure and flow qualitatively agreed with observations described in literature. We conclude that the model adequately can predict coronary hemodynamics in both normal and diseased state based on patient-specific clinical data.

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Non-invasive, energy-based assessment of patient-specific material properties of arterial tissue

Smoljkic

Sloten

Segers

et al. 2015

Biomech Model Mechanobiol

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The mechanical properties of human biological tissue vary greatly. The determination of arterial material properties should be based on experimental data, i.e. diameter, length, intramural pressure, axial force and stress-free geometry. Currently, clinical data provide only non-invasively measured pressure-diameter data for superficial arteries (e.g. common carotid and femoral artery). The lack of information forces us to take into account certain assumptions regarding the in situ configuration to estimate material properties in vivo. This paper proposes a new, non-invasive, energy-based approach for arterial material property estimation. This approach is compared with an approach proposed in the literature. For this purpose, a simplified finite element model of an artery was used as a mock experimental situation. This method enables exact knowledge of the actual material properties, thereby allowing a quantitative evaluation of material property estimation approaches. The results show that imposing conditions on strain energy can provide a good estimation of the material properties from the non-invasively measured pressure and diameter data.

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The fiber orientation in the coronary arterial wall at physiological loading evaluated with a two-fiber constitutive model

Cited by 14 publications

References 41 publications

Supersonic Shear Wave Imaging to Assess Arterial Nonlinear Behavior and Anisotropy: Proof of Principle via Ex Vivo Testing of the Horse Aorta

Supersonic Shear Wave Imaging to Assess Arterial Nonlinear Behavior and Anisotropy: Proof of Principle via Ex Vivo Testing of the Horse Aorta

Towards Patient-Specific Modeling of Coronary Hemodynamics in Healthy and Diseased State

Non-invasive, energy-based assessment of patient-specific material properties of arterial tissue

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