The emerging interdisciplinary field, mechanobiology, is focused on understanding how cells sense their surroundings and transfer biomechanical signals to initiate cellular changes. I aim to develop hydrogel platforms with differential stiffness patterns to study cellular mechanotransduction and to generate heart muscle cells. The findings have the potential to greatly improve the clinical outcomes where more than 10 clinical trials failed to show successful regeneration after heart attack.
Understanding The Mechanisms Underlying Airway Remodelling
Funder
National Health and Medical Research Council
Funding Amount
$451,716.00
Summary
Changes in the structure of the lung contribute to the development of disease, but are not responsive to our current therapies. I have found two key structural proteins that are altered in asthma. This research will characterise the regulation and role of these proteins in the disease process. In addition, it will determine if these proteins also contribute to the development of other serious fibrotic diseases, for which there are no current treatments.
Investigating The Mechanism And Consequences Of Cytotoxic Lymphocyte Detachment
Funder
National Health and Medical Research Council
Funding Amount
$419,180.00
Summary
Killer cells are white blood cells that destroy cancerous cells. To move to their next target they must quickly detach from a dying target. Failure of detachment results in excessive inflammation and tumour escape. This project will discover the detachment signals required to ‘release’ a locked-on killer cell. This will lead to a deeper understanding of immune pathology and new ways of treating cancer.
Improving Patient Outcomes In Leukaemia By Targeting Cancer Stem Cells
Funder
National Health and Medical Research Council
Funding Amount
$294,763.00
Summary
Blood cancers such as acute myeloid leukaemia (AML) are among the most deadly types of cancer and new treatments are desperately needed to improve patient’s survival in these diseases. AML cancer-causing stem cells survive by turning on immortalization programs and we hope to specifically kill these AML stem cells by blocking these crucial pathways. This includes things that control the way the cells divide and the way they respond to genetic damage as well as other novel pathways.
Using Human 3D Engineered Heart Tissue For Discovery Of Novel Biology And Novel Therapeutics
Funder
National Health and Medical Research Council
Funding Amount
$425,048.00
Summary
The goal of this project is to develop a model of miniaturised 3D human heart tissue for research into cardiac biology and also drug discovery applications. This will hopefully result in better, cheaper drugs in the future with less reliance on animal testing.