Improved cryopreservation protocols for long term storage of platelets. The aim of this project is to characterise human blood platelet deterioration during cold storage and cryopreservation, and accelerate the development of improved long-term storage options. The project expects to generate important new knowledge about how platelets deteriorate during storage, and how such deterioration can be minimized. The expected outcomes are improved methods for long term platelet storage. This should be ....Improved cryopreservation protocols for long term storage of platelets. The aim of this project is to characterise human blood platelet deterioration during cold storage and cryopreservation, and accelerate the development of improved long-term storage options. The project expects to generate important new knowledge about how platelets deteriorate during storage, and how such deterioration can be minimized. The expected outcomes are improved methods for long term platelet storage. This should benefit blood donation services and hospitals by improving platelet delivery to remote locations, reducing wasted blood and the number of donations required, leading to significant financial savings.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101635
Funder
Australian Research Council
Funding Amount
$343,450.00
Summary
DNA origami functionalised nanoscale surfaces. This project aims to combine the strengths of top-down and bottom-up nanofabrication to build hybrid structures. In traditional top-down nanofabrication, large systems pattern a semiconductor substrate to build up sophisticated devices. In contrast, in the emerging field of bottom-up nanotechnology, clever design of molecular interactions drives the self-assembly of smaller building blocks into more complex structures, with smaller features. This pr ....DNA origami functionalised nanoscale surfaces. This project aims to combine the strengths of top-down and bottom-up nanofabrication to build hybrid structures. In traditional top-down nanofabrication, large systems pattern a semiconductor substrate to build up sophisticated devices. In contrast, in the emerging field of bottom-up nanotechnology, clever design of molecular interactions drives the self-assembly of smaller building blocks into more complex structures, with smaller features. This project aims to bridge the gap between these two technologies to build functional devices. These devices will be applied, for example, to understand biological problems such as why blood clots form on implanted medical devices - their main cause of failure.Read moreRead less