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Decoding miRNA regulated genetic circuits. This project will aim to develop a much better understanding of how the process of making proteins from genes is regulated, and will develop scientific software capable of predicting how a cell will respond to changes in this regulation. The results will have widespread use, including assistance in deciding the best treatments for genetic diseases.
Single-molecule optofluidics: streamlining high-throughput engineering and analysis of proteins and protein assemblies. This project aims at creating novel technologies for high-throughput engineering and analysis of proteins with single-molecule sensitivity. The platform will considerably accelerate the generation of protein-based diagnostics, new vaccines and therapeutics; it will foster collaborations with industry putting Australia at the forefront of protein research.
RNA-based analysis for prediction of islet death in diabetes. Death of insulin-producing cells is a common feature in diabetes. Presently, a blood glucose test remains the only blunt instrument to diagnose diabetes. The RNA-based analysis for prediction of islet death in diabetes (RAPID) study links with eight clinical trials to test this newly developed non-invasive assay for predicting diabetes. Early diagnosis will help to reduce diabetic complications in later life.
Optomechanical metrology: pushing optical sensing to its limit. This project aims to pioneer technologies to observe and control the microscopic world with unprecedented precision, and apply them to realise practical sensors with unrivalled performance. Nano- and micro-scale sensors will be developed that resolve motion smaller than an atomic nucleus, in a classical spin-off from international efforts to study quantum physics at the nanoscale. Record precision will be achieved in thermometry and ....Optomechanical metrology: pushing optical sensing to its limit. This project aims to pioneer technologies to observe and control the microscopic world with unprecedented precision, and apply them to realise practical sensors with unrivalled performance. Nano- and micro-scale sensors will be developed that resolve motion smaller than an atomic nucleus, in a classical spin-off from international efforts to study quantum physics at the nanoscale. Record precision will be achieved in thermometry and magnetometry. New tools will be developed for lab-on-a-chip medical diagnosis and thermal imaging, that in future could allow femtolitre diagnosis of blood diseases such as malaria, on-chip genomic analysis, more efficient airport screening, and more precise satellite maps of global and atmospheric temperature.Read moreRead less
Smart magnetic resonance imaging (MRI) contrast agents: from early detection to assessment of drug delivery mechanisms. 'Smart' contrast agents will be developed for enhancing the performance of magnetic resonance imaging (MRI) of diseases such as cancer by designing them to be triggered by biochemical markers for disease. This has the potential to aid in early detection which can lead to lower mortality rates and consequently a lower burden on the health system.
Traceable theranostics: tools for visualising drug delivery and therapeutic benefit in vivo. Forty-three thousand people died from cancer in Australia in 2010. The aim of this project is to advance the concept of 'personalised-therapy' through the development of novel imaging devices based on polymers that can 'switch-on' and deliver drugs in specific tissues, allowing more sensitive and earlier detection and monitoring of diseases and therapies.
Improved decoding of human brain activity using advanced functional magnetic resonance imaging at ultra-high field strength. Using advanced MRI methods at ultra-high field, this project aims to enable the decoding and reconstruction of visual stimuli, as well as imagined ones from small functional units (layers and columns) in the human brain in vivo. This will be made possible by the use of a new functional MRI method, concurrent high temporal and spatial resolution and whole brain coverage as ....Improved decoding of human brain activity using advanced functional magnetic resonance imaging at ultra-high field strength. Using advanced MRI methods at ultra-high field, this project aims to enable the decoding and reconstruction of visual stimuli, as well as imagined ones from small functional units (layers and columns) in the human brain in vivo. This will be made possible by the use of a new functional MRI method, concurrent high temporal and spatial resolution and whole brain coverage as well as high sensitivity and specificity. Additionally, it will advance the development of functional connectomics and the aid the parcellation of the human cortex.Read moreRead less