Constitutive modelling of arteries considering fibre recruitment and three-dimensional fibre distribution

Weisbecker, Hannah; Unterberger, Michael Johannes; Holzapfel, Gerhard

doi:10.1098/rsif.2015.0111

Cited by 55 publications

(27 citation statements)

References 26 publications

(51 reference statements)

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“…Although two families (peaks in probability density histogram) are frequently apparent in the present data, in each case one constitutes a significantly greater area fraction than the other. O'Connell et al (2008), Horny et al (2010), Schriefl et al (2012), Chow et al (2014), Sassani et al (2015), Weisbecker et al (2015) and Sugita & Matsumoto (2018) report that a single family of fibres was evident; however, others have reported two (Schriefl et al 2012;Laksari et al 2016), three (Schriefl et al 2012) and even four (Rezakhaniha et al 2012;Schriefl et al 2012) fibre families, all of which are evident here, further emphasising aortic microarchitectural heterogeneity at a local level. It is shown that a von Mises mixture model is required accurately to fit the complexity of collagen fibre orientations that exist along the aorta, which suggests that common constitutive laws implemented through finite element analysis (Holzapfel et al 2000;Nolan et al 2014) may not be capable of fully capturing the full anisotropy of the vessel.…”

Section: Discussionmentioning

confidence: 41%

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Quantification of the regional bioarchitecture in the human aorta

et al. 2019

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Regional variance in human aortic bioarchitecture responsible for the elasticity of the vessel is poorly understood. The current study quantifies the elements responsible for aortic compliance, namely, elastin, collagen and smooth muscle cells, using histological and stereological techniques on human tissue with a focus on regional heterogeneity. Using donated cadaveric tissue, a series of samples were excised between the proximal ascending aorta and the distal abdominal aorta, for five cadavers, each of which underwent various staining procedures to enhance specific constituents of the wall. Using polarised light microscopy techniques, the orientation of collagen fibres was studied for each location and each tunical layer of the aorta. Significant transmural and longitudinal heterogeneity in collagen fibre orientations were uncovered throughout the vessel. It is shown that a von Mises mixture model is required accurately to fit the complex collagen fibre distributions that exist along the aorta. Additionally, collagen and smooth muscle cell density was observed to increase with increasing distance from the heart, whereas elastin density decreased. Evidence clearly demonstrates that the aorta is a highly heterogeneous vessel which cannot be simplistically represented by a single compliance value. The quantification and fitting of the regional aortic bioarchitectural data, although not without its limitations, including mean cohort age of 77.6 years, facilitates the development of next‐generation finite element models that can potentially simulate the influence of regional aortic composition and microstructure on vessel biomechanics.

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Section: Discussionmentioning

confidence: 41%

“…(), Weisbecker et al. () and Sugita & Matsumoto () report that a single family of fibres was evident; however, others have reported two (Schriefl et al. ; Laksari et al.…”

Section: Discussionmentioning

confidence: 96%

Quantification of the regional bioarchitecture in the human aorta

et al. 2019

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“…We submit that the consequent lack of quantitative mechanistic insight limits the field in designing and testing treatment approaches to target the ultrastructural basis of arterial stiffening (15,37,140,159). Motivated by previous work of ours and others (13,23,39,125,142,151), we consider the skillful application of constitutive models to clinical arterial stiffness data of great potential value to close the mentioned gap. Therefore, in the next section, we will discuss the applicability of constitutive modeling and provide some guidance on releasing its potential.…”

Section: Overall Summary Of Clinical-epidemiological Review Findingsmentioning

confidence: 98%

Constitutive interpretation of arterial stiffness in clinical studies: a methodological review

Reesink

Spronck

2019

American Journal of Physiology-Heart and Circulatory Physiology

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Clinical assessment of arterial stiffness relies on noninvasive measurements of regional pulse wave velocity or local distensibility. However, arterial stiffness measures do not discriminate underlying changes in arterial wall constituent properties (e.g., in collagen, elastin, or smooth muscle), which is highly relevant for development and monitoring of treatment. In arterial stiffness in recent clinical-epidemiological studies, we systematically review clinical-epidemiological studies (2012–) that interpreted arterial stiffness changes in terms of changes in arterial wall constituent properties (63 studies included of 514 studies found). Most studies that did so were association studies (52 of 63 studies) providing limited causal evidence. Intervention studies (11 of 63 studies) addressed changes in arterial stiffness through the modulation of extracellular matrix integrity (5 of 11 studies) or smooth muscle tone (6 of 11 studies). A handful of studies (3 of 63 studies) used mathematical modeling to discriminate between extracellular matrix components. Overall, there exists a notable gap in the mechanistic interpretation of stiffness findings. In constitutive model-based interpretation, we first introduce constitutive-based modeling and use it to illustrate the relationship between constituent properties and stiffness measurements (“forward” approach). We then review all literature on modeling approaches for the constitutive interpretation of clinical arterial stiffness data (“inverse” approach), which are aimed at estimation of constitutive properties from arterial stiffness measurements to benefit treatment development and monitoring. Importantly, any modeling approach requires a tradeoff between model complexity and measurable data. Therefore, the feasibility of changing in vivo the biaxial mechanics and/or vascular smooth muscle tone should be explored. The effectiveness of modeling approaches should be confirmed using uncertainty quantification and sensitivity analysis. Taken together, constitutive modeling can significantly improve clinical interpretation of arterial stiffness findings.

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“…The response of fibers are typically assumed to be governed by exponential functions (Holzapfel et al, 2000(Holzapfel et al, , 2005. However, structurally-motivated material models may provide increased insights into the underlying mechanics and physics of arteries and could overcome this drawback (Weisbecker et al, 2015). The work by Gasser et al (2006) included micro-structural information in the model by means of the assumption of a fiber orientation von Mises distribution function.…”

Section: Introductionmentioning

confidence: 99%

Over length quantification of the multiaxial mechanical properties of the ascending, descending and abdominal aorta using Digital Image Correlation

Peña

Corral

Martı́nez

et al. 2018

Journal of the Mechanical Behavior of Biomedical Materials

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In this paper, we hypothesize that the biaxial mechanical properties of the aorta may be dependent on arterial location. To demonstrate any possible position-related difference, our study analyzed and compared the biaxial mechanical properties of the ascending thoracic aorta, descending thoracic aorta and infrarenal abdominal aorta stemming from the same porcine subjects, and reported values of constitutive parameters for well-known strain energy functions, showing how these mechanical properties are affected by location along the aorta. When comparing ascending thoracic aorta, descending thoracic aorta and infrarenal abdominal aorta, abdominal tissues were found to be stiffer and highly anisotropic. We found that the aorta changed from a more isotropic to a more anisotropic tissue and became progressively less compliant and stiffer with the distance to the heart. We observed substantial differences in the anisotropy parameter between aortic samples where abdominal samples were more anisotropic and nonlinear than the thoracic samples. The phenomenological model was not able to capture the passive biaxial properties of each specific porcine aorta over a wide range of biaxial deformations, showing the best prediction root mean square error ε=0.2621 for ascending thoracic samples and, especially, the worst for the infrarenal abdominal samples ε=0.3780. The micro-structured model with Bingham orientation density function was able to better predict biaxial deformations (ε=0.1372 for ascending thoracic aorta samples). The root mean square error of the micro-structural model and the micro-structured model with von Mises orientation density function were similar for all positions.

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Constitutive modelling of arteries considering fibre recruitment and three-dimensional fibre distribution

Cited by 55 publications

References 26 publications

Quantification of the regional bioarchitecture in the human aorta

Quantification of the regional bioarchitecture in the human aorta

Constitutive interpretation of arterial stiffness in clinical studies: a methodological review

Over length quantification of the multiaxial mechanical properties of the ascending, descending and abdominal aorta using Digital Image Correlation

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