Intravascular Leukocyte Trafficking During Thromboinflammation
Funder
National Health and Medical Research Council
Funding Amount
$668,742.00
Summary
Unblocking blood vessels to treat heart attack and stroke can unfortunately cause a paradoxical worsening of organ damage, due to increased inflammation upon blood flow restoration. We have identified a novel way in which this side-effect is regulated by the small blood clotting cells platelets, and the protein fibrin. We will investigate ways to reduce the pro-inflammatory role for platelets, and define safer clot busting treatments.
Investigation Of A New Approach To Regulate Fibrin Clot Retraction And Arterial Thrombolysis
Funder
National Health and Medical Research Council
Funding Amount
$483,171.00
Summary
Pathological blood clots are removed in patients by administering clot dissolving drugs (fibrinolytics). However these drugs are quite often ineffective and cause bleeding. We have identified a new platelet-mediated pathway controlling contraction of blood clots, important for clot stability. In this proposal, we will examine the potential for inhibitors of this pathway to loosen blood clots, and facilitate the actions of fibrinolytics to promote clot dissolution.
The Role Of The Plasminogen Activators (PAs), Urokinase-PA And Tissue-type PA In Arthritis
Funder
National Health and Medical Research Council
Funding Amount
$481,500.00
Summary
Many diseases, such as rheumatoid arthritis (RA), are inflammatory by nature. Intra-articular fibrin deposition is an early and persistent hallmark of inflammatory responses, resulting from an altered balance between coagulation (the production of fibrin) and fibrinolysis (the breakdown of fibrin). This fibrin accumulation can have adverse effects in RA, including mediating and-or enhancing inflammation, and contributing to subsequent joint damage. The plasminogen activators (PA), urokinase PA ( ....Many diseases, such as rheumatoid arthritis (RA), are inflammatory by nature. Intra-articular fibrin deposition is an early and persistent hallmark of inflammatory responses, resulting from an altered balance between coagulation (the production of fibrin) and fibrinolysis (the breakdown of fibrin). This fibrin accumulation can have adverse effects in RA, including mediating and-or enhancing inflammation, and contributing to subsequent joint damage. The plasminogen activators (PA), urokinase PA (u-PA) and tissue-type PA (t-PA) convert plasminogen into plasmin which can then breakdown the accumulated fibrin. Their presence in RA patients would therefore be beneficial. However, u-PA is also implicated in cell migration leading to inflammatory cells accumulating in the joint, and cartilage destruction, both of which are detrimental to disease outcome. In the joints of RA patients there are high levels of u-PA and low levels of t-PA. We, and our collaborators, have found that in the absence of t-PA, disease is exacerbated, whilst in the absence of u-PA, the outcome depends on the type of disease, either exacerbating or ameliorating disease. This highlights the different roles u-PA can have. The current proposal aims to determine the role of u-PA in inflammation and arthritis, and whether enhancing t-PA can have beneficial outcomes with respect to disease severity. In addition, we will also study whether intra-articular fibrin deposition can, in fact, drive the inflammatory reaction and cartilage destruction seen in RA. The findings will be important for our understanding of the role of fibrin accumulation in the inflammatory and destructive processes that occur in RA, and the roles of u-PA and t-PA in enhancing and preventing them respectively. Information gained will provide clues for useful strategies for the treatment of human inflammatory diseases, including RA.Read moreRead less
I am a cardiorespiratory neuroscientist. My work aims to discover what determines central respiratory and sympathetic activity and how this controls breathing and the circulation in health and disease
Discovery Early Career Researcher Award - Grant ID: DE200100326
Funder
Australian Research Council
Funding Amount
$425,231.00
Summary
Mass transfer enhancement for hydrate based carbon capture and cold storage. This project aims to generate the knowledge and techniques required to increase carbon dioxide (CO2) uptake in hydrate based carbon capture from current levels of 15.4% to up to 90% of its rated capacity. This marked improvement stems from identification of the mechanism of CO2-water mass transfer in CO2 hydrate formation and engineering of structurally modified porous hydrogels as the substrate of CO2 hydrates. Encapsu ....Mass transfer enhancement for hydrate based carbon capture and cold storage. This project aims to generate the knowledge and techniques required to increase carbon dioxide (CO2) uptake in hydrate based carbon capture from current levels of 15.4% to up to 90% of its rated capacity. This marked improvement stems from identification of the mechanism of CO2-water mass transfer in CO2 hydrate formation and engineering of structurally modified porous hydrogels as the substrate of CO2 hydrates. Encapsulation will be developed in a way that CO2 may be transported by CO2 hydrates in a concentrated form. Successful completion of the project will offer technical evaluation of a novel CO2 capture and transport solution with lower operational energy consumption and capital cost than incumbent carbon capture technologies.Read moreRead less