Recent experimental and computational studies have shown that transmurally heterogeneous material properties through the arterial wall are critical to understanding the heterogeneous expressions of constituent degrading molecules. Given that expression of such molecules is thought to be intimately linked to local magnitudes of stress, modelling the transmural stress distribution is critical to understanding arterial adaption during disease. The aim of this study was to develop an arterial growth and remodelling framework that can incorporate both transmurally heterogeneous constituent distributions and residual stresses, into a 3-D finite element model. As an illustrative example, we model the development of a fusiform aneurysm and investig...
Background Cardiovascular system is directly affected by mechanical loads such as blood pr...
A novel framework for simulating growth and remodelling (G&R) of a fibre-reinforced artery, incl...
International audienceThe goal of this paper is to study computationally how blood vessels adapt whe...
Recent experimental and computational studies have shown that transmurally heterogeneous material pr...
We sophisticate a fluid–solid growth computational framework for modelling aneurysm evolution. A rea...
Experimental and computational studies suggest a substantial variation in the mechanical responses a...
Long-term adaptation of soft tissues is realized through growth and remodeling (G&R). Mathematical m...
We propose a novel thick-walled fluid–solid-growth (FSG) computational framework for modeling vascul...
Arterial growth and remodelling (GandR) is mediated by vascular cells in response to their chemical ...
International audienceIn its permanent quest of mechanobiological homeostasis, our vascula-ture sign...
A fluid–solid-growth (FSG) model of saccular cerebral aneurysm evolution is developed. It utilises a...
An intracranial aneurysm (IA) is a balloon-like focal lesion on the cerebral arterial wall. IAs are ...
In silico models of intracranial aneurysm (IA) evolution aim to reliably represent the mechanical bl...
Background Cardiovascular system is directly affected by mechanical loads such as blood pr...
A novel framework for simulating growth and remodelling (G&R) of a fibre-reinforced artery, incl...
International audienceThe goal of this paper is to study computationally how blood vessels adapt whe...
Recent experimental and computational studies have shown that transmurally heterogeneous material pr...
We sophisticate a fluid–solid growth computational framework for modelling aneurysm evolution. A rea...
Experimental and computational studies suggest a substantial variation in the mechanical responses a...
Long-term adaptation of soft tissues is realized through growth and remodeling (G&R). Mathematical m...
We propose a novel thick-walled fluid–solid-growth (FSG) computational framework for modeling vascul...
Arterial growth and remodelling (GandR) is mediated by vascular cells in response to their chemical ...
International audienceIn its permanent quest of mechanobiological homeostasis, our vascula-ture sign...
A fluid–solid-growth (FSG) model of saccular cerebral aneurysm evolution is developed. It utilises a...
An intracranial aneurysm (IA) is a balloon-like focal lesion on the cerebral arterial wall. IAs are ...
In silico models of intracranial aneurysm (IA) evolution aim to reliably represent the mechanical bl...
Background Cardiovascular system is directly affected by mechanical loads such as blood pr...
A novel framework for simulating growth and remodelling (G&R) of a fibre-reinforced artery, incl...
International audienceThe goal of this paper is to study computationally how blood vessels adapt whe...