Additive manufacturing (AM) is a useful technology to produce artificial aortic models for the training of transcatheter aortic valve replacement (TAVR) surgery. With AM, the models can be tailored towards the individualized aortic anatomy of patients. Most of these reported models so far are manufactured using single rubber-like materials. However, such materials do not replicate the mechanical properties of natural aortic tissue, especially the stress–strain response in higher strain (>0.1) regions. This could be problematic for surgeons training for surgeries using a model which does not exhibit properties of the real aorta. To overcome this limitation, we developed a 3D-printed, mechanically representative aortic model comprising gelati...
Compliant phantoms of the human aortic arch can mimic patient specific cardiovascular dysfunctions i...
(1) Background: The realization of appropriate aortic replicas for in vitro experiments requires a s...
Background: The use of anatomical models produced by 3D printing technique (rapid prototyping, RP) i...
We design and manufacture a silicone model of the human aorta, able to mimic both the geometrical an...
We design and manufacture a silicone model of the human aorta, able to mimic both the geometrical an...
The present work deals with the producing of patient-specific aortic phantoms using an additive manu...
Patient specific surgical simulators can be effective training tools in cardiac surgery. There is cu...
Aortic stenosis is a serious cardiovascular disease that requires urgent attention and surgical inte...
Adequate in-vitro training in valved stents deployment as well as testing of the latter devices requ...
Le travail présenté dans ce manuscrit concerne la fabrication de fantômes d'aorte patient spécifique...
Heart valve diseases are among the leading causes of cardiac failure around the globe. Current advan...
(1) Background: The realization of appropriate aortic replicas for in vitro experiments requires a s...
Heart valve diseases are among the leading causes of cardiac failure around the globe. Current adva...
3D printing has multiple useful applications in aortic surgery. It can be used in anatomical educati...
Compliant phantoms of the human aortic arch can mimic patient specific cardiovascular dysfunctions i...
(1) Background: The realization of appropriate aortic replicas for in vitro experiments requires a s...
Background: The use of anatomical models produced by 3D printing technique (rapid prototyping, RP) i...
We design and manufacture a silicone model of the human aorta, able to mimic both the geometrical an...
We design and manufacture a silicone model of the human aorta, able to mimic both the geometrical an...
The present work deals with the producing of patient-specific aortic phantoms using an additive manu...
Patient specific surgical simulators can be effective training tools in cardiac surgery. There is cu...
Aortic stenosis is a serious cardiovascular disease that requires urgent attention and surgical inte...
Adequate in-vitro training in valved stents deployment as well as testing of the latter devices requ...
Le travail présenté dans ce manuscrit concerne la fabrication de fantômes d'aorte patient spécifique...
Heart valve diseases are among the leading causes of cardiac failure around the globe. Current advan...
(1) Background: The realization of appropriate aortic replicas for in vitro experiments requires a s...
Heart valve diseases are among the leading causes of cardiac failure around the globe. Current adva...
3D printing has multiple useful applications in aortic surgery. It can be used in anatomical educati...
Compliant phantoms of the human aortic arch can mimic patient specific cardiovascular dysfunctions i...
(1) Background: The realization of appropriate aortic replicas for in vitro experiments requires a s...
Background: The use of anatomical models produced by 3D printing technique (rapid prototyping, RP) i...