Identification Of A New Thrombosis Mechanism Triggered By Dying Platelets
Funder
National Health and Medical Research Council
Funding Amount
$608,742.00
Summary
A severe reduction in blood flow (ischemia) to the intestines can trigger blood clot formation (thrombosis) in multiple organs, including the lungs. We have identified a new thrombosis mechanism that is triggered by the clumping of white blood cells in the intestines, leading to widespread thrombosis in the lung. Here we will investigate the mechanisms triggering this thrombosis mechanism with the ultimate aim of identifying more effective antithrombotic approaches.
Heparin Induced Thrombocytopenia (HIT): Further Characterization Of Disease Mechanism Will Improve Patient Treatment
Funder
National Health and Medical Research Council
Funding Amount
$456,484.00
Summary
Thrombus formation occurs as a side effect of heparin treatment in many patients. This condition is called Heparin Induced Thrombocytopenia (HIT). The clots may be stabilised by secretions from cells called neutrophils. In this project we will study this possibility using a mouse model of HIT and will explore therapeutic approaches to inhibit clot stabilisation.
Investigation Into The Intervention Of Arterial Thrombosis And Atherosclerosis Using Shear Sensitive Nanoparticle Drug Delivery
Funder
National Health and Medical Research Council
Funding Amount
$462,601.00
Summary
In this project we aim to provide a targeted therapy that inhibits atherosclerosis, in-stent restenosis and thrombosis; pathologies characterized by high shear stress due to a reduction in the vessel lumen. We will apply microfluidic technology to characterize lipid nano-capsules that are tagged with antibodies against activated platelets or VCAM-1, loaded with anti-platelet or immune suppressive drugs and are prone to rupture specifically under high shear stress conditions.
Investigation Of A New Leukocyte Recruitment Mechanism At Sites Of Vascular Injury
Funder
National Health and Medical Research Council
Funding Amount
$547,216.00
Summary
Blood clots formed at sites of small vessel injury can cause damage of vital organs by obstructing blood flow and promoting a proinflammatory response by efficiently recruiting and activating leukocytes. The molecular mechanisms responsible for the latter event are poorly defined. We have established a new mouse model, gained novel insights into the leukocyte recruitment by blood clots, and aim to define the precise mechanism for this process in this application.
Congenital brain vascular malformations are a common cause of stroke and death in young patients. This project aims to develop a new treatment for these lesions that does not require surgery. We will use focussed radiation to change the cells lining the abnormal vessels so that they can be targeted with a new treatment that causes blockage of the vessels and prevents haemorrhage.
Development Of Novel Anticoagulants Inspired By Nature For Improved Ischaemic Stroke Therapy
Funder
National Health and Medical Research Council
Funding Amount
$716,396.00
Summary
Ischaemic stroke, caused by clots that obstruct blood flow to the brain, is the third most common cause of mortality and the leading cause of disability globally. Unfortunately, the only approved therapeutic option is ineffective for a significant proportion of stroke sufferers. This project will develop novel anticoagulants, inspired by molecules produced by blood feeding organisms, for use in more effective and safe ischaemic stroke therapy.
Antiphospholipid Syndrome Related Thrombosis: Understanding The Disease Pathogenic Mechanisms Is The Key To Better Diagnosis And Treatment
Funder
National Health and Medical Research Council
Funding Amount
$607,497.00
Summary
Patients with the Antiphospholipid Syndrome develop thrombosis at a young age. It requires long-term treatment with blood thinning medications, which have risks of severe bleeding. Methods are needed to decide which patients require long term treatment, avoiding unnecessary treatment in low risk patients. Such methods do not currently exist. In this study we explore how useful two novel assays developed by us are in identifying which of these patients are at high risk of thrombosis.
Understanding The Mechanisms Of Bleeding And Clotting Complications For Children On Extracorporeal Circuits.
Funder
National Health and Medical Research Council
Funding Amount
$1,113,385.00
Summary
Extracorporeal Membrane Oxygenation (ECMO) is advanced life support, which can save critically ill children. Significant bleeding occurs in 39%; clotting in 31% of children on ECMO; stroke in 12%. The biggest barrier to reducing these complications is the lack of understanding of how the bleeding/clotting system works in ECMO. This unique proposal uses the largest paediatric ECMO population in Australia and a multidisplinary expert team to develop a mechanistic understanding of these issues.
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.
Investigating The Link Between Oxidative Stress And Biomechanical Integrin Activation In Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$653,742.00
Summary
Diabetes represents a serious healthcare problem globally. A large proportion of deaths associated with diabetes can be attributed to the development of blood clots in the circulation of the heart and brain (heart attack/stroke). The blood clotting mechanism is ‘hyperactive’ in diabetes, although the reason for this is not well defined. In this proposal we will investigate a new mechanism promoting blood clots, and will investigate innovative approaches to reduce this clotting mechanism.