Prediction of Plaque Progression in Coronary Arteries Based on a Novel Hemodynamic Index Calculated From Virtual Stenosis Method

Lee, Jun Young; Shin, Su Hyun; Kim, Gook Tae; Choi, Jin Ho; Shim, Eun Bo

doi:10.3389/fphys.2019.00400

Cited by 3 publications

(2 citation statements)

References 22 publications

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“…Computational fluid dynamics (CFD) is a useful tool to study vascular pathologies and is capable of predicting the location and progression of coronary atherosclerotic plaques [ 12 ], growth/rupture of aneurysms [ 13 ] and microscopic thrombus growth [ 14 ]. The branching of the coronary arteries results in low-shear and stagnant/recirculation environments occurring on the outer walls [ 15 ], being common sites for plaque growth and hence stenosis to occur.…”

Section: Introductionmentioning

confidence: 99%

Numerical modelling of blood rheology and platelet activation through a stenosed left coronary artery bifurcation

et al. 2021

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Coronary bifurcations are prone to atherosclerotic plaque growth, experiencing regions of reduced wall shear stress (WSS) and increased platelet adhesion. This study compares effects across different rheological approaches on hemodynamics, combined with a shear stress exposure history model of platelets within a stenosed porcine bifurcation. Simulations used both single/multiphase blood models to determine which approach best predicts phenomena associated with atherosclerosis and atherothrombosis. A novel Lagrangian platelet tracking model was used to evaluate residence time and shear history of platelets indicating likely regions of thrombus formation. Results show a decrease in area of regions with pathologically low time-averaged WSS with the use of multiphase models, particularly in a stenotic bifurcation. Significant non-Newtonian effects were observed due to low-shear and varying hematocrit levels found on the outer walls of the bifurcation and distal to the stenosis. Platelet residence time increased 11% in the stenosed artery, with exposure times to low-shear sufficient for red blood cell aggregation (>1.5 s). increasing the risk of thrombosis. This shows stenotic artery hemodynamics are inherently non-Newtonian and multiphase, with variations in hematocrit (0.163–0.617) and elevated vorticity distal to stenosis (+15%) impairing the function of the endothelium via reduced time-averaged WSS regions, rheological properties and platelet activation/adhesion.

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Section: Introductionmentioning

confidence: 99%

Numerical modelling of blood rheology and platelet activation through a stenosed left coronary artery bifurcation

et al. 2021

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“…Recent advances in computational fluid dynamics (CFD) have allowed for detailed study into coronary haemodynamics [4,5], in particular, the relationship between atherosclerosis and flow parameters such as wall shear stress [6][7][8][9] (WSS). A detailed overview on the use of patient-specific models by Taylor and Figueroa [10] highlighted many clinical applications [11][12][13][14][15], with the most relevant to this study being predictions in the progression of atherosclerosis [16,17], arterial fibrin clots [18] and thrombus formation [19], as well the effect of arterial stenosis on blood flow [20][21][22]. The lumen wall is assumed smooth for all coronary models to date.…”

Section: Introductionmentioning

confidence: 99%

Assessment of surface roughness and blood rheology on local coronary haemodynamics: a multi-scale computational fluid dynamics study

Owen

Schenkel

Shepherd

et al. 2020

J. R. Soc. Interface.

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The surface roughness of the coronary artery is associated with the onset of atherosclerosis. The study applies, for the first time, the micro-scale variation of the artery surface to a 3D coronary model, investigating the impact on haemodynamic parameters which are indicators for atherosclerosis. The surface roughness of porcine coronary arteries have been detailed based on optical microscopy and implemented into a cylindrical section of coronary artery. Several approaches to rheology are compared to determine the benefits/limitations of both single and multiphase models for multi-scale geometry. Haemodynamic parameters averaged over the rough/smooth sections are similar; however, the rough surface experiences a much wider range, with maximum wall shear stress greater than 6 Pa compared to the approximately 3 Pa on the smooth segment. This suggests the smooth-walled assumption may neglect important near-wall haemodynamics. While rheological models lack sufficient definition to truly encompass the micro-scale effects occurring over the rough surface, single-phase models (Newtonian and non-Newtonian) provide numerically stable and comparable results to other coronary simulations. Multiphase models allow for phase interactions between plasma and red blood cells which is more suited to such multi-scale models. These models require additional physical laws to govern advection/aggregation of particulates in the near-wall region.

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RETRACTED ARTICLE: Prediction of atherosclerosis pathology in retinal fundal images with machine learning approaches

Parameswari¹,

Ranjani²

2020

J Ambient Intell Human Comput

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Prediction of Plaque Progression in Coronary Arteries Based on a Novel Hemodynamic Index Calculated From Virtual Stenosis Method

Cited by 3 publications

References 22 publications

Numerical modelling of blood rheology and platelet activation through a stenosed left coronary artery bifurcation

Numerical modelling of blood rheology and platelet activation through a stenosed left coronary artery bifurcation

Assessment of surface roughness and blood rheology on local coronary haemodynamics: a multi-scale computational fluid dynamics study

RETRACTED ARTICLE: Prediction of atherosclerosis pathology in retinal fundal images with machine learning approaches

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