Cardiovascular disease is the one of most important diseases for human in the developed countries and is responsible for millions of deaths and disabilities every year. In cardiovascular biomechanics, the fluid-structure interaction within large blood vessel is required to understand the aortic wall tear, aortic dissection and so on. Strongly-coupled methods yield the resolution of a nonlinear problem on the fluid-structure interface, which may be very time-consuming. A loosely coupled method was used to study the complex mechanical interaction under steady flow and pulsatile flow in a three-layered aortic arch model. The results showed the impact of steady flow and pulsatile flow, the variations of wall stress along arch portion, and wall ...
Curvatures, junctions and bifurcations of the large and medium arteries are severely affected by ath...
Heart disease is the leading cause of death globally. Aorta is extremely important because of its cr...
Numerical modeling can provide detailed and quantitative information on aortic root (AR) biomechanic...
Abstract Background Many cardiovascular diseases, such as aortic dissection, frequently occur on the...
A three-dimensional computer model of human aortic arch with three branches is reproduced to study t...
The aortic arch is at risk of several cardiovascular diseases, such as aortic dissection. Many of th...
Interest in patient-specific blood-flow circulation modeling has increased substantially in recent y...
Spiral blood flow in the aorta is helpful in maintaining the stability of flow, reduction in lateral...
Interest in patient-specific blood-flow circulation modeling has increased substantially in recent y...
The numerical tools to simulate blood flow in the cardiovascular system are constantly developing du...
The numerical tools to simulate blood flow in the cardiovascular system are constantly developing du...
The ascending branch of the aorta is one of the most stressed organ of the arterial system. We aim t...
The ascending branch of the aorta is one of the most stressed organ of the arterial system. We aim t...
Cardiovascular diseases are the first cause of death in industrialized countries. It is now widely e...
The present study investigates effects of surrounding tissues and non-uniform wall thickness on the ...
Curvatures, junctions and bifurcations of the large and medium arteries are severely affected by ath...
Heart disease is the leading cause of death globally. Aorta is extremely important because of its cr...
Numerical modeling can provide detailed and quantitative information on aortic root (AR) biomechanic...
Abstract Background Many cardiovascular diseases, such as aortic dissection, frequently occur on the...
A three-dimensional computer model of human aortic arch with three branches is reproduced to study t...
The aortic arch is at risk of several cardiovascular diseases, such as aortic dissection. Many of th...
Interest in patient-specific blood-flow circulation modeling has increased substantially in recent y...
Spiral blood flow in the aorta is helpful in maintaining the stability of flow, reduction in lateral...
Interest in patient-specific blood-flow circulation modeling has increased substantially in recent y...
The numerical tools to simulate blood flow in the cardiovascular system are constantly developing du...
The numerical tools to simulate blood flow in the cardiovascular system are constantly developing du...
The ascending branch of the aorta is one of the most stressed organ of the arterial system. We aim t...
The ascending branch of the aorta is one of the most stressed organ of the arterial system. We aim t...
Cardiovascular diseases are the first cause of death in industrialized countries. It is now widely e...
The present study investigates effects of surrounding tissues and non-uniform wall thickness on the ...
Curvatures, junctions and bifurcations of the large and medium arteries are severely affected by ath...
Heart disease is the leading cause of death globally. Aorta is extremely important because of its cr...
Numerical modeling can provide detailed and quantitative information on aortic root (AR) biomechanic...