Eoghan Maher scite author profile

Little mechanical test data exists regarding the inelastic behavior of atherosclerotic plaques. As a result finite element (FE) models of stenting procedures commonly use hyperelastic material models to describe the soft tissue response thus limiting the accuracy of the model to the expansion stage of stent implantation and leave them unable to predict the lumen gain. In this study, cyclic mechanical tests were performed to characterize the inelastic behavior of fresh human carotid atherosclerotic plaque tissue due to radial compressive loading. Plaques were classified clinically as either mixed (M), calcified (Ca), or echolucent (E). An approximately linear increase in the plastic deformation was observed with increases in the peak applied strain for all plaque types. While calcified plaques generally appeared stiffest, it was observed that the clinical classification of plaques had no significant effect on the magnitude of permanent deformation on unloading. The test data was characterized using a constitutive model that accounts for both permanent deformation and stress softening to describe the compressive plaque behavior on unloading. Material constants are reported for individual plaques as well as mean values for each plaque classification. This data can be considered as a first step in characterizing the inelastic behavior of atherosclerotic plaques and could be used in combination with future mechanical data to improve the predictive capabilities of FE models of angioplasty and stenting procedures particularly in relation to lumen gain.

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An anisotropic inelastic constitutive model to describe stress softening and permanent deformation in arterial tissue

Maher

Creane

Lally

et al. 2012

Journal of the Mechanical Behavior of Biomedical Materials

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This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.A n anisotropic inelastic constitutive model to describe stress softening and permanent deformation in arterial tissue A bstractInelastic phenomena such as softening and unrecoverable inelastic strains induced by loading have been observed experimentally in soft tissues such as arteries. These phenomena need to be accounted for in constitutive models of arterial tissue so that computational models can accurately predict the outcomes of interventional procedures such as balloon angioplasty and stenting that involve non-physiological loading of the tissue. In this study, a novel constitutive model is described that accounts for inelastic effects such as Mullins-type softening and permanent set in a fibre reinforced tissue. The evolution of inelasticity is governed by a set of internal variables. Softening is introduced through a typical continuum damage mechanics approach, while the inelastic residual strains are introduced through an additive split in the stress tensor. Numerical simulations of aorta and carotid arterial tissue subjected to uniaxial testing in the longitudinal, circumferential and axial directions reproduce the anisotropic inelastic behaviour of the tissue. Material parameters derived from best-fits to experimental data are provided to describe these inelastic effects for both aortic and carotid tissue.

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Site specific inelasticity of arterial tissue

Maher

Early

Creane

et al. 2012

Journal of Biomechanics

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1Understanding the mechanical behaviour of arterial tissue is vital to the development and 2 analysis of medical devices targeting diseased vessels. During angioplasty and stenting, stress 3 softening and permanent deformation of the vessel wall occur during implantation of the 4 device, however little data exists on the inelastic behaviour of cardiovascular tissue and how 5 this varies through the arterial tree. The aim of this study was to characterise the magnitude 6 of stress softening and inelastic deformations due to loading throughout the arterial tree and 7 to investigate the anisotropic inelastic behaviour of the tissue. Cyclic compression tests were 8 used to investigate the differences in inelastic behaviour for carotid, aorta, femoral and 9 coronary arteries harvested from 3-4 month old female pigs, while the anisotropic behaviour 10 of aortic and carotid tissue was determined using cyclic tensile tests in the longitudinal and 11 circumferential directions. The differences in inelastic behaviour were correlated to the ratio 12 of collagen to elastin content of the arteries. It was found that larger inelastic deformations 13 occurred in muscular arteries (coronary), which had a higher collagen to elastin ratio than 14 elastic arteries (aorta), where the smallest inelastic deformations were observed. Lower 15 magnitude inelastic deformations were observed in the circumferential tensile direction than 16 in the longitudinal tensile direction or due to radial compression. This may be as a result of 17 non-fibrous matrix or smooth muscle in the artery becoming more easily damaged than the 18 collagen fibers during loading. Stress softening was also found to be dependent on artery

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Finite element modelling of diseased carotid bifurcations generated from in vivo computerised tomographic angiography

Creane

Maher

Sultan

et al. 2010

Computers in Biology and Medicine

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Eoghan Maher

Tensile and compressive properties of fresh human carotid atherosclerotic plaques

Inelasticity of Human Carotid Atherosclerotic Plaque

An anisotropic inelastic constitutive model to describe stress softening and permanent deformation in arterial tissue

Site specific inelasticity of arterial tissue

Finite element modelling of diseased carotid bifurcations generated from in vivo computerised tomographic angiography

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