Elimination of the transplant waiting list is the ultimate goal of research into pigto-human xenotransplantation. The prospect of success has been improved recently by refinements in technology used to introduce genetic modifications in the pig, although the genes that will need to be expressed or deleted are still undecided. What is clear is that intravascular thrombosis, a critical mediator of rejection of pig xenografts, must be overcome. This project aims to investigate the use of anticoagul ....Elimination of the transplant waiting list is the ultimate goal of research into pigto-human xenotransplantation. The prospect of success has been improved recently by refinements in technology used to introduce genetic modifications in the pig, although the genes that will need to be expressed or deleted are still undecided. What is clear is that intravascular thrombosis, a critical mediator of rejection of pig xenografts, must be overcome. This project aims to investigate the use of anticoagulant gene expression to prevent intravascular thrombosis associated with xenograft rejection.Read moreRead less
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.
Role Of Ferroptosis In The Lipid Metabolism Of Cancer Cells
Funder
National Health and Medical Research Council
Funding Amount
$238,792.00
Summary
Conventional cancer treatments are becoming increasingly ineffective as cancers mutate to protect cells from drug-activated death. To combat this, new ways to selectively kill cancer cells must be found and therapeutically exploited. This research will study how ferroptosis, a recently discovered form of cell death that is distinct from other killing mechanisms, can be used to target cancer and provide avenues for next-generation cancer treatments.