Computational modelling of atherosclerosis

Parton, Andrew; McGilligan, Victoria; O’Kane, Maurice; Baldrick, Francina R.; Watterson, Steven

doi:10.1093/bib/bbv081

Cited by 52 publications

(40 citation statements)

References 146 publications

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“…Also, the size of this neighbourhood is ultimately arbitrary, selected to be “slightly larger” (in fact, 6% larger) than the sum of the radii of the two interacting cells. Although this inhibition is backed up by biological results (Evans et al, 2008), we need to include more accurate modelling of SMC biology (Parton et al, 2016), for example, mention some recent models for SMC growth), including the response of SMC to transmural pressure (DeMaio et al, 2004). …”

Section: Discussionmentioning

confidence: 99%

A Comparison of Fully-Coupled 3D In-Stent Restenosis Simulations to In-vivo Data

et al. 2017

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We describe our fully-coupled 3D multiscale model of in-stent restenosis, with blood flow simulations coupled to smooth muscle cell proliferation, and report results of numerical simulations performed with this model. This novel model is based on several previously reported 2D models. We study the effects of various parameters on the process of restenosis and compare with in vivo porcine data where we observe good qualitative agreement. We study the effects of stent deployment depth (and related injury score), reendothelization speed, and simulate the effect of stent width. Also we demonstrate that we are now capable to simulate restenosis in real-sized (18 mm long, 2.8 mm wide) vessel geometries.

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Section: Discussionmentioning

confidence: 99%

A Comparison of Fully-Coupled 3D In-Stent Restenosis Simulations to In-vivo Data

et al. 2017

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“…Mathematical modelling of the cellular activity in the vessel wall during atherosclerosis is an area of growing research interest (see Parton et al (2016) for a comprehensive review). To date, however, the vast majority of published models have investigated the actions of monocytes/macrophages in disease initiation (El Khatib et al, 2007;Pappalardo et al, 2008;Cohen et al, 2014;Chalmers et al, 2015;Bhui and Hayenga, 2017) and only a handful have explicitly considered the role of SMCs in plaque progression.…”

Section: Lumen Endotheliummentioning

confidence: 99%

A two-phase model of early fibrous cap formation in atherosclerosis

Watson

Byrne

Macaskill

et al. 2018

Journal of Theoretical Biology

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Atherosclerotic plaque growth is characterised by chronic, non-resolving inflammation that promotes the accumulation of cellular debris and extracellular fat in the inner artery wall. This material is highly thrombogenic, and plaque rupture can lead to the formation of blood clots that occlude major arteries and cause myocardial infarction or stroke. In advanced plaques, vascular smooth muscle cells (SMCs) are recruited from deeper in the artery wall to synthesise a cap of fibrous tissue that stabilises the plaque and sequesters the thrombogenic plaque content from the bloodstream. The fibrous cap provides crucial protection against the clinical consequences of atherosclerosis, but the mechanisms of cap formation are poorly understood. In particular, it is unclear why certain plaques become stable and robust while others become fragile and dangerously vulnerable to rupture. We develop a multiphase model with non-standard boundary conditions to investigate early fibrous cap formation in the atherosclerotic plaque. The model is parameterised using data from a range of in vitro and in vivo studies, and includes highly nonlinear mechanisms of SMC proliferation and migration in response to an endothelium-derived chemical signal. We demonstrate that the model SMC population naturally evolves towards a steady-state, and predict a rate of cap formation and a final plaque SMC content consistent with experimental observations in mice. Parameter sensitivity simulations show that SMC proliferation makes a limited contribution to cap formation, and demonstrate that stable cap formation relies primarily on a critical balance between the rates of SMC recruitment to the plaque, chemotactic SMC migration within the plaque and SMC loss by apoptosis or phenotype change. This model represents the first detailed in silico study of fibrous cap formation in atherosclerosis, and establishes a multiphase modelling framework that can be readily extended to investigate many other aspects of plaque development.

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“…Many mathematical models divide the macrophage population into "macrophage" and "foam cells". This is true in ODE models [28], spatially resolved PDE models [29][30][31] and other computational models [32]. Yet it is clear that there is a continuous distribution of lipid loads across macrophage populations, stretching from monocytes with low lipid loadings and macrophages that can be labelled as foam cells in atherosclerotic plaques.…”

Section: Introductionmentioning

confidence: 99%