We propose a novel thick-walled fluid–solid-growth (FSG) computational framework for modeling vascular disease evolution. The arterial wall is modeled as a thick-walled nonlinearly elastic cylindrical tube consisting of two layers corresponding to the media-intima and adventitia, where each layer is treated as a fiber-reinforced material with the fibers corresponding to the collagenous component. Blood is modeled as a Newtonian fluid with constant density and viscosity; no slip and no-flux conditions are applied at the arterial wall. Disease progression is simulated by growth and remodeling (G&R) of the load bearing constituents of the wall. Adaptions of the natural reference configurations and mass densities of constituents are driven ...
Arterial diseases affect more than 1 in 20 adults in the world. However, our current knowledge in th...
Recent experimental and computational studies have shown that transmurally heterogeneous material pr...
An intracranial aneurysm (IA) is a balloon-like focal lesion on the cerebral arterial wall. IAs are ...
We propose a novel thick-walled fluid–solid-growth (FSG) computational framework for modeling vascul...
We sophisticate a fluid–solid growth computational framework for modelling aneurysm evolution. A rea...
(1) Background: Vascular tissue seems to adapt towards stable homeostatic mechanical conditions, how...
We present the first mathematical model to account for the evolution of the abdominal aortic aneurys...
Modeling the soft tissue volumetric growth has received considerable attention in the literature.How...
A fluid–solid-growth (FSG) model of saccular cerebral aneurysm evolution is developed. It utilises a...
The novel three-dimensional (3D) mathematical model for the development of abdominal aortic aneurysm...
The novel three-dimensional (3D) mathematical model for the development of abdominal aortic aneurysm...
International audienceIn its permanent quest of mechanobiological homeostasis, our vascula-ture sign...
Arterial growth and remodelling (GandR) is mediated by vascular cells in response to their chemical ...
(1) Background: Vascular tissue seems to adapt towards stable homeostatic mechanical conditions, how...
In silico models of intracranial aneurysm (IA) evolution aim to reliably represent the mechanical bl...
Arterial diseases affect more than 1 in 20 adults in the world. However, our current knowledge in th...
Recent experimental and computational studies have shown that transmurally heterogeneous material pr...
An intracranial aneurysm (IA) is a balloon-like focal lesion on the cerebral arterial wall. IAs are ...
We propose a novel thick-walled fluid–solid-growth (FSG) computational framework for modeling vascul...
We sophisticate a fluid–solid growth computational framework for modelling aneurysm evolution. A rea...
(1) Background: Vascular tissue seems to adapt towards stable homeostatic mechanical conditions, how...
We present the first mathematical model to account for the evolution of the abdominal aortic aneurys...
Modeling the soft tissue volumetric growth has received considerable attention in the literature.How...
A fluid–solid-growth (FSG) model of saccular cerebral aneurysm evolution is developed. It utilises a...
The novel three-dimensional (3D) mathematical model for the development of abdominal aortic aneurysm...
The novel three-dimensional (3D) mathematical model for the development of abdominal aortic aneurysm...
International audienceIn its permanent quest of mechanobiological homeostasis, our vascula-ture sign...
Arterial growth and remodelling (GandR) is mediated by vascular cells in response to their chemical ...
(1) Background: Vascular tissue seems to adapt towards stable homeostatic mechanical conditions, how...
In silico models of intracranial aneurysm (IA) evolution aim to reliably represent the mechanical bl...
Arterial diseases affect more than 1 in 20 adults in the world. However, our current knowledge in th...
Recent experimental and computational studies have shown that transmurally heterogeneous material pr...
An intracranial aneurysm (IA) is a balloon-like focal lesion on the cerebral arterial wall. IAs are ...