Understanding glycopolymer interactions with the extracellular matrix. This project aims to advance knowledge of the biochemical and biophysical structure of the endothelial glycocalyx, a dynamic cell surface extracellular matrix rich in proteoglycans and glycosaminoglycans. It will be the first to explore how charged glycopolymers interact with this dynamic interface with the goal to develop a model of the glycocalyx lifecycle. This project is expected to enable the transfer of skills, knowledg ....Understanding glycopolymer interactions with the extracellular matrix. This project aims to advance knowledge of the biochemical and biophysical structure of the endothelial glycocalyx, a dynamic cell surface extracellular matrix rich in proteoglycans and glycosaminoglycans. It will be the first to explore how charged glycopolymers interact with this dynamic interface with the goal to develop a model of the glycocalyx lifecycle. This project is expected to enable the transfer of skills, knowledge and ideas as well as advanced research and industrial training for young scientists. Knowledge derived from this project is expected to enable future innovation in molecules with tailored interactions with the glycocalyx with significant benefits for researchers, manufacturers and end users. Read moreRead less
Imaging-based fluid-structure interaction modelling of carotid atherosclerotic plaque. This project aims to combine computational modelling, magnetic resonance imaging (MRI), mechanical measurement and pathological analysis to investigate carotid plaque progression, and quantify the critical blood flow and plaque stress/strain conditions under which plaque rupture is likely to occur. MRI-based 3D computational models with multi-component plaque structures and their interaction with blood flow wi ....Imaging-based fluid-structure interaction modelling of carotid atherosclerotic plaque. This project aims to combine computational modelling, magnetic resonance imaging (MRI), mechanical measurement and pathological analysis to investigate carotid plaque progression, and quantify the critical blood flow and plaque stress/strain conditions under which plaque rupture is likely to occur. MRI-based 3D computational models with multi-component plaque structures and their interaction with blood flow will be developed and solved numerically to identify suitable plaque rupture risk indicators. Mechanical properties of plaque components will be measured ex-vivo and fibre orientation-based constitutive rules will be developed. This project aims to lead to quantitative understandings of plaque progression and rupture.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101302
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Lab-on-a-chip platforms for hemodynamics research: new approaches for the study of blood diseases. This project will use advanced microfluidic technologies to study how and why blood clotting occurs. New devices will be created that can precisely analyse the ability of blood to form clots and these will become powerful tools for the diagnosis of blood disorders and the research and validation of drugs for the treatment of these disorders.
Mechanisms of initiation and remodelling of intracranial aneurysms: a synthesis of hemodynamics and molecular biomarkers. Rupture of brain aneurysms can lead to severe disability and death. This project proposes novel ways of assessing risk of rupture using sophisticated mathematical models of blood flow in aneurysms and biochemical substances released in the blood. This will enhance basic understanding of aneurysm formation and improve treatment and management.
Novel biomimetic vascular biomaterials using extracellular matrix molecules. There is currently a pressing, unmet need for biodegradable, functional biomaterials that support endothelial cell interactions and vascular regeneration. Lack of sufficient vascular regeneration is the biggest obstacle in translating advances in biomaterials development to clinical, diagnostic and research applications. This project aims to address this need by developing novel biomaterial platforms that mimic the extr ....Novel biomimetic vascular biomaterials using extracellular matrix molecules. There is currently a pressing, unmet need for biodegradable, functional biomaterials that support endothelial cell interactions and vascular regeneration. Lack of sufficient vascular regeneration is the biggest obstacle in translating advances in biomaterials development to clinical, diagnostic and research applications. This project aims to address this need by developing novel biomaterial platforms that mimic the extracellular matrix of the vascular niche. We plan to utilise unique extracellular matrix domains and bioprinting techniques to control and guide endothelial cell functions. We could thus contribute to the knowledge base in vascular biology and bioengineering, forming the basis for vascular materials of the future.Read moreRead less
Haemodynamic investigation of flow diverter stents for the treatment of intracranial aneurysms. This project will explore the engineering of a flow diverter, an endovascular device for the treatment of brain aneurysms. The project will determine the optimal design of new types of flow diverters, which in turn could improve the effectiveness of treatments, thus reducing the associated costs of cerebral haemorrhage and stroke.
Real-time cardiac magnetic resonance imaging: a compressed-sensing framework incorporating sensor design and multidimensional signal reconstruction. Conventional Magnetic Resonance Imaging (MRI) technology is fundamentally constrained by slow scan speeds. Taking a new approach to cardiac imaging - which integrates MRI hardware design with a novel dynamic imaging method based on compressed sensing - this project enables faster and more accurate dynamic imaging for the diagnosis of heart disease.
Novel computational tools for the analysis of sympathetic nervous system activity. This project will investigate electrical signals from the heart, resulting in novel tools for the assessment of sympathetic nervous system activity. The findings will contribute to advancing Australia's international leading position in health technology and improve community health.
Structural design of third generation biomaterials. This project will design third generation biomaterials for heart valves, cartilage and bones that guide the formation of new tissue whilst being dissolved inside the human body. As a result, it is anticipated that painful and costly revision surgery will become obsolete. Major benefits will be achieved in paediatric health as implants will have the ability to grow with the child.
Biomaterials with multifaceted tunability and bio-specificity. Polyurethanes, a family of polymers with independently tunable mechanical and biodegradation properties, will be developed as a versatile platform material for biomedical implants. Novel energetic ion treatments that allow the coupling of bioactive agents to surfaces will eliminate adverse reactions and enable integration with surrounding tissue.