Discovery Early Career Researcher Award - Grant ID: DE160101098
Funder
Australian Research Council
Funding Amount
$315,000.00
Summary
Novel modelling of fluid-structure interactions in biological flows. The objective of this project is to develop a novel method to model fluid-structure interactions and turbulence in cardiovascular systems. The cardiovascular system is essential in providing nutrient and waste transport throughout the body. Because blood vessels and red blood cells are flexible, they are subjected to large deformations with significant effects on physiological functions such as blood distribution and oxygen rel ....Novel modelling of fluid-structure interactions in biological flows. The objective of this project is to develop a novel method to model fluid-structure interactions and turbulence in cardiovascular systems. The cardiovascular system is essential in providing nutrient and waste transport throughout the body. Because blood vessels and red blood cells are flexible, they are subjected to large deformations with significant effects on physiological functions such as blood distribution and oxygen release. Fluid-structure interactions are critical for understanding the intricacies of such systems but it is still a challenge to model these systems realistically using numerical methods. Expected outcomes of the project include better simulations of three-dimensional fluid-structure interactions and improved understanding of the behaviours of biological systems.Read moreRead less
Optimising haemodynamics in complex stented arteries. This project aims to optimise the hemodynamics (blood flow) in coronary arteries with high curvatures and bifurcations. Experience has shown that the build-up of plaque — and the resulting occlusion of blood flow — tends to occur in these complex arterial regions. The most common therapeutic strategy is the insertion of a stent to prop open the artery. However, the nature of the geometry often leads to post-stenting complications such as rest ....Optimising haemodynamics in complex stented arteries. This project aims to optimise the hemodynamics (blood flow) in coronary arteries with high curvatures and bifurcations. Experience has shown that the build-up of plaque — and the resulting occlusion of blood flow — tends to occur in these complex arterial regions. The most common therapeutic strategy is the insertion of a stent to prop open the artery. However, the nature of the geometry often leads to post-stenting complications such as restenosis and thrombosis, ultimately resulting in negative outcomes. In this project, advanced research methods from fluid dynamics and optimisation and control will be used to potentially minimise these highly undesirable effects.Read moreRead less
Biotransport design for engineering microenvironment in scaffolds. Tissue engineering signifies an exciting opportunity to solve shortage of transplantable tissues. This project targets a critical issue in engineering thick tissue and aims to introduce computational structural optimisation to biotransport problems. The optimal scaffold is expected to create a more desirable microenvironment for better tissue growth.
Computational design for engineering micro/nanotopography. Micro/nanotopography and associated characteristics has major influences in several emerging areas of environmental, biomedical and energy engineering. This project will develop a new computational framework for topographical design and fabrication. It will create new research opportunities and technological innovation for the future development.