A nonlinear anisotropic inverse method for computational dissection of inhomogeneous planar tissues

Witzenburg, Colleen M.; Barocas, Victor H.

doi:10.1080/10255842.2016.1176154

Cited by 13 publications

(9 citation statements)

References 72 publications

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“…For the latter, the microstructure organization of collagen fibers was assumed to be a fully random process and not a result of microstructural investigation which further leads to a non-physiological rupture stretch value for collagen fibers. Nonetheless, [54,60] do reinforce the hypothesis that tissue level failure is directly related to failure at the scale of fibrous microstructure.…”

Section: Introductionsupporting

confidence: 55%

“…They have been extensively implemented to study the failure properties of random fiber networks under tensile loading [20,21]. More recently, this methodology has been extended to study the failure of lamellar unit of the aortic media [54] and the whole arterial wall [60]. Although they show good agreement with experimental observations, some limitations should be addressed.…”

Section: Introductionmentioning

confidence: 99%

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An evaluation of fiber-based damage for assessing the failure of aortic tissue: comparison between healthy and aneurysmal aortas

2022

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The decision of surgical intervention for an aortic aneurysm is usually associated with an assessment of risk of its rupture. Global rupture risk assessment parameters like wall diameter and growth of the aneurysm over time often fail at predicting the risk of rupture with accuracy. This paper will investigate the hypothesis that the tissue’s microstructure determines its macroscopic failure. To this aim, two different testing protocols have been implemented. Human ascending thoracic aortic aneurysm (ATAA) tissue samples were subjected to bulge-inflation testing until rupture coupled with multi-photon microscopy (MPM) imaging. Image stacks of the sample were acquired at different pressure levels. Additionally, porcine aorta samples were tested under uniaxial tension until failure and their response was recorded. Prior to mechanical testing, MPM image stacks were acquired at four different zones on the sample. The image stacks acquired at the load free state were used to extract morphological information relating to collagen fibers. Then, an inverse random sampling approach was used to generate pseudomorphological parameters for network reconstruction. A discrete model of the collagen network signifying its stochastic nature was then developed, including both prefailure and post-failure mechanics. The model was able to replicate the mechanical response and failure of the tissue, and demonstrated that fiber-based damage can strongly shape the macroscopic failure response of the tissue. Identified values of collagen fiber failure strain were in the range of 8.8 to 29.3% in the case of aneurysmal samples, and 18.7 to 25.5% in the case of porcine samples. A statistical analysis enabled the characterization of correlation between fiber morphology and tissue failure. The model may serve as a useful tool for predicting macroscale failure of the aortic wall based on the variations in microscale morphology.

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Section: Introductionsupporting

confidence: 55%

Section: Introductionmentioning

confidence: 99%

An evaluation of fiber-based damage for assessing the failure of aortic tissue: comparison between healthy and aneurysmal aortas

2022

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“…Additionally, post-partitioning analysis assumes the regions to be linearly elastic for quick calculation of the regional C ijkl which may not be a valid assumption in vascular tissues. To combat this shortcoming, a nonlinear GAIM can be performed by doing multiple analyses using different boundary conditions throughout the loading curves obtained during ex-perimentation [29]. This more extensive version of GAIM was deemed to be unnecessary for the purposes of studying the presence of heterogeneity and preliminarily characterizing the regional anisotropy.…”

Section: Discussionmentioning

confidence: 99%

Characterizing Tissue Remodeling and Mechanical Heterogeneity in Cerebral Aneurysms

Shih¹,

Provenzano²,

Witzenburg³

et al. 2021

J Vasc Res

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Accurately assessing the complex tissue mechanics of cerebral aneurysms (CAs) is critical for elucidating how CAs grow and whether that growth will lead to rupture. The factors that have been implicated in CA progression – blood flow dynamics, immune infiltration, and extracellular matrix remodeling – all occur heterogeneously throughout the CA. Thus, it stands to reason that the mechanical properties of CAs are also spatially heterogeneous. Here, we present a new method for characterizing the mechanical heterogeneity of human CAs using generalized anisotropic inverse mechanics, which uses biaxial stretching experiments and inverse analyses to determine the local Kelvin moduli and principal alignments within the tissue. Using this approach, we find that there is significant mechanical heterogeneity within a single acquired human CA. These results were confirmed using second harmonic generation imaging of the CA’s fiber architecture and a correlation was observed. This approach provides a single-step method for determining the complex heterogeneous mechanics of CAs, which has important implications for future identification of metrics that can improve accuracy in prediction risk of rupture.

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“…Thickness was measured in nine evenly spaced locations and averaged while the sample was unpinned in a stress-free state, outside of any solution. The tissue was then embedded in optimal cutting temperature compound and snap frozen in liquid nitrogen cooled isopentane for sectioning and imaging [27,28]. We assumed symmetry between the two halves of the diaphragm, as differences in microstructure are not observed between the left and right sides [12,29].…”

Section: In Vitro Biaxial Mechanical Testingmentioning

confidence: 99%

It's more than the amount that counts: implications of collagen organization on passive muscle tissue properties revealed with micromechanical models and experiments

Sahani,

Hixson,

Blemker

2024

J. R. Soc. Interface.

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Collagen accumulation is often used to characterize skeletal muscle fibrosis, but the role of collagen in passive muscle mechanics remains debated. Here we combined finite-element models and experiments to examine how collagen organization contributes to macroscopic muscle tissue properties. Tissue microstructure and mechanical properties were measured from in vitro biaxial experiments and imaging in dystrophin knockout ( mdx ) and wild-type (WT) diaphragm muscle. Micromechanical models of intramuscular and epimuscular extracellular matrix (ECM) regions were developed to account for complex microstructure and predict bulk properties, and directly calibrated and validated with the experiments. The models predicted that intramuscular collagen fibres align primarily in the cross-muscle fibre direction, with greater cross-muscle fibre alignment in mdx models compared with WT. Higher cross-muscle fibre stiffness was predicted in mdx models compared with WT models and differences between ECM and muscle properties were seen during cross-muscle fibre loading. Analysis of the models revealed that variation in collagen fibre distribution had a much more substantial impact on tissue stiffness than ECM area fraction. Taken together, we conclude that collagen organization explains anisotropic tissue properties observed in the diaphragm muscle and provides an explanation for the lack of correlation between collagen amount and tissue stiffness across experimental studies.

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A nonlinear anisotropic inverse method for computational dissection of inhomogeneous planar tissues

Cited by 13 publications

References 72 publications

An evaluation of fiber-based damage for assessing the failure of aortic tissue: comparison between healthy and aneurysmal aortas

An evaluation of fiber-based damage for assessing the failure of aortic tissue: comparison between healthy and aneurysmal aortas

Characterizing Tissue Remodeling and Mechanical Heterogeneity in Cerebral Aneurysms

It's more than the amount that counts: implications of collagen organization on passive muscle tissue properties revealed with micromechanical models and experiments

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