We provide a computational comparison of the performance of stentless and stented aortic prostheses, in terms of aortic root displacements and internal stresses. To this aim, we consider three real patients; for each of them we draw the two prostheses configurations, which are characterized by different mechanical properties. Moreover, for each patient, we consider also the native configuration. For each scenario, we solve the fluid-structure interaction problem arising between blood and aortic root, through Finite Elements. The results show a better agreement between stentless and native displacements and stresses, with respect to the stented case
Bio-inspired polymeric heart valves (PHVs) are excellent candidates to mimic the structural and the ...
Two different aortic prostheses can be used for performing the Bentall procedure: a standard straigh...
The natural aortic valve is able to outlast almost any man-made valve known to date and is a marvell...
We provide a computational comparison of the performance of stentless and stented aortic prostheses,...
The importance of the aortic root compliance in the aortic valve performancehas most frequently been...
Improving artificial valve design is of paramount importance considering that bio-prosthetic aortic ...
In this paper the fluid structure interaction in stentless aortic heart valve during acceleration ph...
In some cases of aortic valve leaflet disease, the implant of a stentless biological prosthesis repr...
In some cases of aortic valve leaflet disease, the implant of a stentless biological prosthesis repr...
The aortic valve is a complex and dynamic structure, which, with age, degenerative disease, or gene...
Valvular heart disorders represent a remarkable contribution to cardiovascular diseases; in fact, mo...
Failure of bioprosthetic and synthetic three-leaflet valves has been shown to occur as a consequence...
An established therapy for aortic valve stenosis and insufficiency is the transcatheter aortic valve...
Background. Finite element models of the aortic heart valve have been successfully used in the past ...
Numerical modeling can provide detailed and quantitative information on aortic root (AR) biomechanic...
Bio-inspired polymeric heart valves (PHVs) are excellent candidates to mimic the structural and the ...
Two different aortic prostheses can be used for performing the Bentall procedure: a standard straigh...
The natural aortic valve is able to outlast almost any man-made valve known to date and is a marvell...
We provide a computational comparison of the performance of stentless and stented aortic prostheses,...
The importance of the aortic root compliance in the aortic valve performancehas most frequently been...
Improving artificial valve design is of paramount importance considering that bio-prosthetic aortic ...
In this paper the fluid structure interaction in stentless aortic heart valve during acceleration ph...
In some cases of aortic valve leaflet disease, the implant of a stentless biological prosthesis repr...
In some cases of aortic valve leaflet disease, the implant of a stentless biological prosthesis repr...
The aortic valve is a complex and dynamic structure, which, with age, degenerative disease, or gene...
Valvular heart disorders represent a remarkable contribution to cardiovascular diseases; in fact, mo...
Failure of bioprosthetic and synthetic three-leaflet valves has been shown to occur as a consequence...
An established therapy for aortic valve stenosis and insufficiency is the transcatheter aortic valve...
Background. Finite element models of the aortic heart valve have been successfully used in the past ...
Numerical modeling can provide detailed and quantitative information on aortic root (AR) biomechanic...
Bio-inspired polymeric heart valves (PHVs) are excellent candidates to mimic the structural and the ...
Two different aortic prostheses can be used for performing the Bentall procedure: a standard straigh...
The natural aortic valve is able to outlast almost any man-made valve known to date and is a marvell...