Multiscale bio-chemo-mechanical model of intimal hyperplasia

Abstract: We consider a computational multiscale framework of a bio-chemo-mechanical model for intimal hyperplasia. With respect to existing models, we investigate the interactions between hemodynamics, cellular dynamics and biochemistry on the development of the pathology. Within the arterial wall, we propose a mathematical model consisting of kinetic differential equations for key vascular cell types, collagen and growth factors. The luminal hemodynamics is modelled with the Navier-Stokes equations. Coupling hypothesi… Show more

“…In agreement with [33,34,45,48,50], greater neointimal thickness was observed in regions where WSS was low. Furthermore, Jansen et al [51] devised a multiscale bio-chemo-mechanical model of intimal hyperplasia, where haemodynamic indices are coupled to restenosis in an idealised artery through an influx of growth factors. Although CFD is included within these models [34,45,49], the role of stent deployment on arterial healing is not considered, as is present in [19][20][21]25,38]; a feature ubiquitously linked to neointimal thickening [52,53].…”

“…[25,38]), we assume that damage induced by stent deployment is the predominant driver of the biological cascade of events that initiate the healing process. Alternative approaches in the literature include linking haemodynamic indices such as WSS to a damage index [49], a function describing endothelial dysfunction [45] or an influx of growth factors [51]. Damage, d (r, z, t), is modelled as a spatiotemporal variable mapped throughout the domain in response to the stresses present following stent expansion.…”

An intricate interplay between stent drug dose and release rate dictates arterial restenosis

“…In agreement with [33,34,45,48,50], greater neointimal thickness was observed in regions where WSS was low. Furthermore, Jansen et al [51] devised a multiscale bio-chemo-mechanical model of intimal hyperplasia, where haemodynamic indices are coupled to restenosis in an idealised artery through an influx of growth factors. Although CFD is included within these models [34,45,49], the role of stent deployment on arterial healing is not considered, as is present in [19][20][21]25,38]; a feature ubiquitously linked to neointimal thickening [52,53].…”

“…[25,38]), we assume that damage induced by stent deployment is the predominant driver of the biological cascade of events that initiate the healing process. Alternative approaches in the literature include linking haemodynamic indices such as WSS to a damage index [49], a function describing endothelial dysfunction [45] or an influx of growth factors [51]. Damage, d (r, z, t), is modelled as a spatiotemporal variable mapped throughout the domain in response to the stresses present following stent expansion.…”

An intricate interplay between stent drug dose and release rate dictates arterial restenosis

In silico experiments of intimal hyperplasia development: disendothelization in an axisymmetric idealized artery

Arterial tissues and their inflammatory response to collagen damage: A continuum in silico model coupling nonlinear mechanics, molecular pathways, and cell behavior