The hemodynamic functionality of heart valves strongly depends on the distribution of collagen fibers, which are their main load-bearing constituents. It is known that collagen networks remodel in response to mechanical stimuli. Yet, the complex interplay between external load and collagen remodeling is poorly understood. In this study, we adopted a computational approach to simulate collagen remodeling occurring in native fetal and pediatric heart valves. The computational model accounted for several biological phenomena: cellular (re)orientation in response to both mechanical stimuli and topographical cues provided by collagen fibers; collagen deposition and traction forces along the main cellular direction; collagen degradation decreasin...
\u3cp\u3eAdherent cells are generally able to reorient in response to cyclic strain. In three-dimens...
When implanted inside the body, bioprosthetic heart valve leaflets experience a variety of cyclic me...
Understanding collagen fiber remodeling is desired to optimize the mechanical conditioning protocols...
The hemodynamic functionality of heart valves strongly depends on the distribution of collagen fiber...
\u3cp\u3eIn order to create tissue-engineered heart valves with long-term functionality, it is essen...
Living tissues show an adaptive response to mechanical loading by changing their internal structure ...
Commonly, heart valve replacements consist of non-living materials lacking the ability to grow, repa...
To optimize the mechanical properties and integrity of tissue-engineered aortic heart valves, it is ...
One of the most critical problems in heart valve tissue engineering is the progressive development o...
AbstractOne of the most critical problems in heart valve tissue engineering is the progressive devel...
Creating autologous tissues with on-demand and native-like biomechanical properties is the ultimate ...
The tricuspid valve (TV) is composed of three leaflets that coapt during systole to prevent deoxygen...
\u3cp\u3eAdherent cells are generally able to reorient in response to cyclic strain. In three-dimens...
When implanted inside the body, bioprosthetic heart valve leaflets experience a variety of cyclic me...
Understanding collagen fiber remodeling is desired to optimize the mechanical conditioning protocols...
The hemodynamic functionality of heart valves strongly depends on the distribution of collagen fiber...
\u3cp\u3eIn order to create tissue-engineered heart valves with long-term functionality, it is essen...
Living tissues show an adaptive response to mechanical loading by changing their internal structure ...
Commonly, heart valve replacements consist of non-living materials lacking the ability to grow, repa...
To optimize the mechanical properties and integrity of tissue-engineered aortic heart valves, it is ...
One of the most critical problems in heart valve tissue engineering is the progressive development o...
AbstractOne of the most critical problems in heart valve tissue engineering is the progressive devel...
Creating autologous tissues with on-demand and native-like biomechanical properties is the ultimate ...
The tricuspid valve (TV) is composed of three leaflets that coapt during systole to prevent deoxygen...
\u3cp\u3eAdherent cells are generally able to reorient in response to cyclic strain. In three-dimens...
When implanted inside the body, bioprosthetic heart valve leaflets experience a variety of cyclic me...
Understanding collagen fiber remodeling is desired to optimize the mechanical conditioning protocols...