Preventing Stroke From Arteriovenous Malformations Using Precision Thrombosis
Funder
National Health and Medical Research Council
Funding Amount
$993,866.00
Summary
Brain arteriovenous malformations are rupture-prone blood vessels that cause stroke in children and young adults. One third of patients have no current treatment options. We aim to develop new medicines that cause blockage of the abnormal vessels, thus preventing them from bleeding and causing stroke. Focused radiation is used to produce molecular changes in the abnormal vessels; these molecules are then the target for the new medicines. We will develop several new drugs for clinical testing.
Targeting Neurovascular Communication As A Novel Way Of Reducing Vision Loss In Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$986,663.00
Summary
Diabetes is a leading cause of blindness. Here, we evaluate whether diabetes causes changes in the way neurons signal to blood vessels, and whether blocking some of the signals from neurons reduces blood vessel abormalities. Overall, this information is critical to our understanding of the early changes that occur during diabetes and whether novel treatments used early in diabetes can prevent long term changes and vision loss.
Epigenetic Reprogramming Of Calcified Vascular Smooth Muscle Cells As A Treatment For Vascular Calcification
Funder
National Health and Medical Research Council
Funding Amount
$1,285,195.00
Summary
Pathological hardening of blood vessels, or vascular calcification, is a frequent and deadly complication of many cardiovascular disorders. It is caused by the irreversible change in mature vascular smooth muscle cells (the main cell type in the blood vessel walls) to a bone-forming cell type. We have now identified a new gene that can potentially revert calcified vascular cells back to their physiological state. This represents a promising new approach for treatment of vascular calcification.
Influenza A Viral Infection And Pregnancy Complications
Funder
National Health and Medical Research Council
Funding Amount
$1,346,858.00
Summary
Pregnant women who contract influenza are 5 times more likely to be hospitalised than the general population. Babies of mothers with influenza are also associated with increased perinatal mortality rates. We hypothesise that influenza infection in pregnancy significantly impairs the maternal vascular system resulting in maternal and foetal morbidity. Outcomes from this research may change current treatment modalities to improve maternal and foetal outcomes complicated by influenza infection.
Developing An In Vitro Model Of A Human Blastocyst
Funder
National Health and Medical Research Council
Funding Amount
$890,062.00
Summary
Using novel cellular and molecular technologies we propose to develop an artificial model of an early human blastocyst. This will allow us to study the first initial steps in human development without the use of real embryos. Such a model will not only help us decipher the first steps in human development, but we anticipate it will be essential to study how gene mutations and the environment affect this initial step in human development.
Vaccine To Prevent Influenza Virus And Bacterial Super-infection.
Funder
National Health and Medical Research Council
Funding Amount
$707,717.00
Summary
Influenza viruses have the ability to pre-dispose infected hosts toward secondary bacterial complications. The mortality of viral infections that are complicated by a concurrent, or subsequent, bacterial infection (known as a super-infection), is often greater than that of either the virus or the bacteria alone. We will develop a novel multi-pathogen vaccine candidate against the major upper respiratory tract pathogens - Influenza A and Streptococcus pyogenes to prevent super-infections.
Growth Factor Directed Developmental And Pathological Lymphangiogenesis
Funder
National Health and Medical Research Council
Funding Amount
$1,048,507.00
Summary
The formation of new lymphatic vessels occurs in normal development and in diseased tissues in cancer and cardiovascular disease. We have developed an understanding of how lymphatics form in development but we understand far less about how they form in disease. This project will apply multidisciplinary approaches, including genetics and computational biology, to compare how lymphatics form in development and disease. We hope to uncover new ways to manipulate this process for therapeutic gain.
Relaxin Receptor Structural Determination To Aid Therapeutic Development
Funder
National Health and Medical Research Council
Funding Amount
$1,249,114.00
Summary
The receptor for the peptide hormone relaxin, RXFP1, is being targeted by numerous drug companies for the treatment of cardiovascular disease. However, the lack of molecular detail of how relaxin binds and activates RXFP1 is hindering new drug development. We will determine the structure of the complex of relaxin bound to RXFP1 and the mechanism by which this activates cells. The knowledge gained will aid in the design of new drugs targeting RXFP1 for the treatment of cardiovascular disease.
Harnessing The Benefits Of Autonomous Vehicles For Health
Funder
National Health and Medical Research Council
Funding Amount
$738,596.00
Summary
The arrival of autonomous vehicles (AVs) will have huge implications for health behaviours, including physical activity and diet. It is critical that appropriate planning processes are undertaken as early as possible to prevent cities of the future being designed around AVs rather than people, thereby losing the potential for this new technology to be harnessed as a means of enhancing health. This project will facilitate the inclusion of health considerations in AV implementation processes.
Reprogramming Human Fibroblasts Into Induced Trophoblast Stem Cells
Funder
National Health and Medical Research Council
Funding Amount
$889,064.00
Summary
We have been able to generate artificial human trophectoderm which is the tissue that creates the placenta. This will allow us to do research in how the genes control the fate of these cells without the need of human embryos or placenta. We anticipate that the derivation and characterising these cells will revolutionise placenta research, which in turn will contribute to the establishment of new therapies for placenta disease and infertility.