Targeting the undruggable: epitope mapping using Phylomers peptides to modulate activity of Transcription Factors. This project aims at expanding the pool of drug targets, by extending drug screening to protein-protein interaction networks. This project aims to assemble a novel technical platform to detect binding between proteins, using a combination of cell-free protein expression, AlphaScreen and single-molecule fluorescence. This pipeline has great potential to accelerate the exploration of ....Targeting the undruggable: epitope mapping using Phylomers peptides to modulate activity of Transcription Factors. This project aims at expanding the pool of drug targets, by extending drug screening to protein-protein interaction networks. This project aims to assemble a novel technical platform to detect binding between proteins, using a combination of cell-free protein expression, AlphaScreen and single-molecule fluorescence. This pipeline has great potential to accelerate the exploration of protein networks, and provides also a generic platform for drug screening on difficult targets. The project intends to screen Phylogica's libraries of peptides called Phylomers to discover tight binders to a Transcription Factor, Sox18. The objective of this project is to determine which Phylomers can disrupt specific interactions between Sox18 and its binding partners involved in lymphangiogenesis.Read moreRead less
A microfluidic array of phylomers for rapid discovery of peptide probes and biomarkers. This project, through an alliance with Phylogica, aims at exploiting a unique source of structural diversity for drug discovery, harvesting the creativity of nature in its most exotic places. The project will develop a novel approach to validate design and validate drug candidates, by gathering them on a single screening chip for a powerful discovery platform.
The colour of cellular aging: a deep probe of cellular processes. Understanding why we age and whether aging is preventable are profound research challenges, which must be first tackled at a cellular level. Building on our advances in non-invasive colour monitoring of cell function, this project aims to uncover intimate links between cellular processes and aging in cells that must survive for many decades such as oocytes and neurons. We will explore the tantalising possibility to rejuvenate such ....The colour of cellular aging: a deep probe of cellular processes. Understanding why we age and whether aging is preventable are profound research challenges, which must be first tackled at a cellular level. Building on our advances in non-invasive colour monitoring of cell function, this project aims to uncover intimate links between cellular processes and aging in cells that must survive for many decades such as oocytes and neurons. We will explore the tantalising possibility to rejuvenate such aged cells by interfering with molecular master switches of aging. A unique machine learning approach will be applied for finding the most effective interventions. The results will have broad impact beyond the science of aging, in the areas of female fertility, neurodegeneration and immunity.
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Rejuvenating adult stem cells. This project aims to uncover intimate links between metabolic regulation and longevity in adult stem cells, the source of all cells in the body. Understanding why we age and whether ageing is preventable are research challenges which must be first attacked at a cellular level. This project will try to rejuvenate aged stem cells by interfering with a prospective molecular master switch of aging and also develop an approach to identify and select youthful stem cells. ....Rejuvenating adult stem cells. This project aims to uncover intimate links between metabolic regulation and longevity in adult stem cells, the source of all cells in the body. Understanding why we age and whether ageing is preventable are research challenges which must be first attacked at a cellular level. This project will try to rejuvenate aged stem cells by interfering with a prospective molecular master switch of aging and also develop an approach to identify and select youthful stem cells. The results are expected to be important beyond informing the science of ageing, in the areas of tissue engineering, wound healing, embryology and cancer.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100174
Funder
Australian Research Council
Funding Amount
$800,000.00
Summary
Innovative synchrotron science - program for access to the Australian National Beamline Facility and cutting-edge beamlines at international synchrotrons. Synchrotron science dramatically affects the community through the innovative scientific, engineering and medical research outcomes it produces. This program for access to synchrotron beamlines is aimed at enhancing Australia's high international standing in synchrotron science and will have many flow-on effects in areas such as health and ind ....Innovative synchrotron science - program for access to the Australian National Beamline Facility and cutting-edge beamlines at international synchrotrons. Synchrotron science dramatically affects the community through the innovative scientific, engineering and medical research outcomes it produces. This program for access to synchrotron beamlines is aimed at enhancing Australia's high international standing in synchrotron science and will have many flow-on effects in areas such as health and industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100036
Funder
Australian Research Council
Funding Amount
$771,000.00
Summary
Nuclear magnetic resonance spectroscopy facilities - Advancing cutting-edge chemical, biological, energy and materials research in Western Australia. Nuclear magnetic resonance spectroscopy facilities: advancing cutting-edge chemical, biological, energy and materials research: This project will establish new nuclear magnetic resonance spectroscopy facilities supporting high-throughput metabolite detection, diffusion measurement, and small-volume sample identification. The project will support re ....Nuclear magnetic resonance spectroscopy facilities - Advancing cutting-edge chemical, biological, energy and materials research in Western Australia. Nuclear magnetic resonance spectroscopy facilities: advancing cutting-edge chemical, biological, energy and materials research: This project will establish new nuclear magnetic resonance spectroscopy facilities supporting high-throughput metabolite detection, diffusion measurement, and small-volume sample identification. The project will support research across diverse priorities including: energy and minerals; ecology, evolution and the environment; and medicine and health. The project will open new opportunities for areas such as metabolomics and oil and gas processing, and greatly expand capacity to meet strongly increasing demand.Read moreRead less
Dielectric contrast imaging for 7 Tesla magnetic resonance applications. This project aims to develop novel radio-frequency (RF) technology, ensuring that the benefits of high-field magnetic resonance imaging (MRI) are available for a broader range of applications. This project will develop a new contrast mechanism directly related to the RF properties of individual tissue types, circumventing a limitation of intensity based imaging. This technology will enhance Australia’s global impact the dev ....Dielectric contrast imaging for 7 Tesla magnetic resonance applications. This project aims to develop novel radio-frequency (RF) technology, ensuring that the benefits of high-field magnetic resonance imaging (MRI) are available for a broader range of applications. This project will develop a new contrast mechanism directly related to the RF properties of individual tissue types, circumventing a limitation of intensity based imaging. This technology will enhance Australia’s global impact the development of imaging technology for healthcare, biomedical research and advanced diagnostics.Read moreRead less
Sampling and processing for diffusion magnetic resonance imaging. This project aims to develop optimal, efficient and robust signal processing methods for diffusion magnetic resonance imaging (dMRI) with reduced scan times. A child, possibly distressed, can only be motionless long enough to undergo a basic dMRI scan of the brain, but enhanced forms of dMRI need at least 60 minutes. The project’s processing methods will use spherical geometries, which encode information about white matter fibres ....Sampling and processing for diffusion magnetic resonance imaging. This project aims to develop optimal, efficient and robust signal processing methods for diffusion magnetic resonance imaging (dMRI) with reduced scan times. A child, possibly distressed, can only be motionless long enough to undergo a basic dMRI scan of the brain, but enhanced forms of dMRI need at least 60 minutes. The project’s processing methods will use spherical geometries, which encode information about white matter fibres in the brain, to collect and reconstruct images. The project is expected to reduce dMRI scan times and ultimately make non-invasive and inexpensive early detection of neurological disorders such as dementia feasible.Read moreRead less
Electric field effects on cochlear tissues. The project aims to solve the underlying biology of how electricity flows through the cochlear tissues, where and how electrical stimulation excites the auditory neurons, and what the effects of sustained electrical stimulation are on the nerve fibre growth and function. The research aims to show how electric fields can be controlled in the cochlea, and how auditory nerve fibres are affected at the cellular and molecular level. The long-term aim is to ....Electric field effects on cochlear tissues. The project aims to solve the underlying biology of how electricity flows through the cochlear tissues, where and how electrical stimulation excites the auditory neurons, and what the effects of sustained electrical stimulation are on the nerve fibre growth and function. The research aims to show how electric fields can be controlled in the cochlea, and how auditory nerve fibres are affected at the cellular and molecular level. The long-term aim is to utilise these findings to improve the control of neuronal excitability, for development of interfaces with the nervous system.Read moreRead less
Engineering the convergence of telecare and telehealth. This project will design a wrist-worn pendant that represents the convergence of telecare (fall detection and personal alarm pendants) and telehealth (remote management of chronic disease). The system has the potential to be retro-fitted to 100,000s of telecare systems deployed by an industry partner and to herald a new form of low-cost patient monitoring.