Probing Anaesthetic Effects with New Functional Imaging Paradigms. This project seeks new insights into the effects of anaesthetics on brain function and repair. Anaesthesia is used in small-animal imaging to immobilise the animal, but in many cases the anaesthesia itself affects the neurophysiological parameters under study. It has also been shown that many anaesthetics enhance recovery after brain injury in small animals. This project plans to exploit a novel functional brain-imaging technique ....Probing Anaesthetic Effects with New Functional Imaging Paradigms. This project seeks new insights into the effects of anaesthetics on brain function and repair. Anaesthesia is used in small-animal imaging to immobilise the animal, but in many cases the anaesthesia itself affects the neurophysiological parameters under study. It has also been shown that many anaesthetics enhance recovery after brain injury in small animals. This project plans to exploit a novel functional brain-imaging technique for conscious animals to gain new insights into the effects of anaesthetics on brain function and recovery from injury. The knowledge gained is expected to improve knowledge of anaesthetic action, guide future anaesthetic use in small animal imaging to improve the accuracy of image-derived research data, and help to clarify how anaesthetics confer neuroprotective effects in brain injury.Read moreRead less
Functional magnetic resonance imaging: Decoding the palimpsest. This project aims to model the dynamics of functional magnetic resonance imaging (fMRI) to image new physiology and attain higher resolution. This will enable new aspects of brain dynamics to be imaged, achieving higher resolution and improving interpretation. This project is expected to improve the use and power of fMRI, unlock new avenues for probing brain function and save experimental costs. This will have many uses in neuroscie ....Functional magnetic resonance imaging: Decoding the palimpsest. This project aims to model the dynamics of functional magnetic resonance imaging (fMRI) to image new physiology and attain higher resolution. This will enable new aspects of brain dynamics to be imaged, achieving higher resolution and improving interpretation. This project is expected to improve the use and power of fMRI, unlock new avenues for probing brain function and save experimental costs. This will have many uses in neuroscience, brain imaging technology and fMRI analysis software.Read moreRead less
In vivo molecular imaging using engineered affinity reagents and fluorescent laser scanning confocal endomicroscopy. The goal of this project is to develop laser scanning confocal endomicroscopy as a tool for basic scientific discovery and rapid detection of disease biomarkers. The cutting-edge instrument and associated technologies will provide scientists with unprecedented access to dynamic biological processes as they occur in real-time. In addition, it will enable the development of virtual ....In vivo molecular imaging using engineered affinity reagents and fluorescent laser scanning confocal endomicroscopy. The goal of this project is to develop laser scanning confocal endomicroscopy as a tool for basic scientific discovery and rapid detection of disease biomarkers. The cutting-edge instrument and associated technologies will provide scientists with unprecedented access to dynamic biological processes as they occur in real-time. In addition, it will enable the development of virtual biopsies and instant diagnosis without the need for costly and time-consuming histopathological reports. Thus, it will not only drive transformative research but also transform health care delivery. It will also be a major boost to the Australian biotechnology industry with potential for enormous economic benefits.Read moreRead less
The acoustics of a wide-range autonomous oscillator: how do brass players do it? While brass instruments are well understood, the complexities of the interaction with the player are not. This study will analyse how the player's lips and vocal tract interact with the instrument, leading to an understanding not only of the interesting physics involved, but to insight that will benefit players, teachers and students.
Visualising chaperones disentangle and refold proteins - one molecule at a time. Chaperones are enzymes that maintain the proper function of proteins in the cell. This research aims to visualise, at the single molecule level, how chaperones facilitate the folding of individual proteins and how they can disentangle proteins that have aggregated as a result of cell stress.
Background-free imaging of single membrane-receptors with nanophosphors. This project aims to develop nanophosphor beacons and real-time, ultrahigh-sensitivity functional imaging to provide a picture of the brain. Time-gated detection microscopy will give these nanophosphors a superior optical contrast. The nanophosphors’ antibody-targeting will image single AMPA membrane receptors in their full biological context, crucial to understanding neuronal signalling. Simultaneous imaging of receptor tr ....Background-free imaging of single membrane-receptors with nanophosphors. This project aims to develop nanophosphor beacons and real-time, ultrahigh-sensitivity functional imaging to provide a picture of the brain. Time-gated detection microscopy will give these nanophosphors a superior optical contrast. The nanophosphors’ antibody-targeting will image single AMPA membrane receptors in their full biological context, crucial to understanding neuronal signalling. Simultaneous imaging of receptor trafficking and activity in neurons will help to uncover details of the dynamic activity in the brain. This technology is expected to help understand the inner workings of the brain and provide insights into its functioning.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100127
Funder
Australian Research Council
Funding Amount
$355,000.00
Summary
Superresolution fluorescence imaging in microbiology. Superresolution fluorescence imaging in microbiology:
This project involves the purchase of new, and upgrade of existing, fluorescence imaging tools to facilitate the study of intracellular processes in microbial systems at significantly higher spatial and temporal resolutions than hitherto possible. Visualisation of the structure and dynamics of intracellular molecular assemblies at maximal resolution is required to understand protein funct ....Superresolution fluorescence imaging in microbiology. Superresolution fluorescence imaging in microbiology:
This project involves the purchase of new, and upgrade of existing, fluorescence imaging tools to facilitate the study of intracellular processes in microbial systems at significantly higher spatial and temporal resolutions than hitherto possible. Visualisation of the structure and dynamics of intracellular molecular assemblies at maximal resolution is required to understand protein function inside living cells. The new equipment is designed to provide a fast super-resolution imaging system to study the intracellular dynamics of proteins in vitro and a super-resolution microscope to visualise structures and assemblies inside microbes with a resolution of tens of nanometres, putting in vitro biochemistry into the context of a living cell. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100066
Funder
Australian Research Council
Funding Amount
$443,311.00
Summary
Electrophysiology facility for cell phenotyping and drug discovery. This project aims to establish a high-throughput, automated patch clamp facility to enable research at the forefront of cell phenotyping and drug discovery. Ion channels are membrane proteins that underlie cell function and are therefore important drug targets. The patch clamp technique is the most powerful tool available to functionally characterise cells and study the function of ion channels. The significant advance provided ....Electrophysiology facility for cell phenotyping and drug discovery. This project aims to establish a high-throughput, automated patch clamp facility to enable research at the forefront of cell phenotyping and drug discovery. Ion channels are membrane proteins that underlie cell function and are therefore important drug targets. The patch clamp technique is the most powerful tool available to functionally characterise cells and study the function of ion channels. The significant advance provided by the high-throughput, automated patch clamp system is that it allows up to 384 cells to be recorded simultaneously. This project expects to enhance capacity to automate and standardise the quality of recordings, substantially increase the rate of data production, and enable greater access to patch clamp technology.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL140100025
Funder
Australian Research Council
Funding Amount
$2,617,462.00
Summary
The physical brain: emergent, multiscale, nonlinear, and critical dynamics. The physical brain: emergent, multiscale, nonlinear, and critical dynamics. This project aims to transform the understanding of the structure and function of the brain as a complex physical system. It aims to reveal and unify new aspects of information processing, transitions in conscious state, and nonlinear brain interactions by translating and applying concepts and methods from physics and mathematics. It will treat b ....The physical brain: emergent, multiscale, nonlinear, and critical dynamics. The physical brain: emergent, multiscale, nonlinear, and critical dynamics. This project aims to transform the understanding of the structure and function of the brain as a complex physical system. It aims to reveal and unify new aspects of information processing, transitions in conscious state, and nonlinear brain interactions by translating and applying concepts and methods from physics and mathematics. It will treat brain structure and dynamics together to address emergent phenomena like waves and patterns on multiple scales, treating waves as equal participants alongside neurons. Innovative predictions of brain phenomena will aim to be verified against data and used to understand brain networks, dynamics, and the physical phenomena underlying information processing and consciousness.Read moreRead less
PET imaging of learning-related plasticity in awake behaving rats. The objective of the project is to combine an investigation of basic learning paradigms with functional Positron emission tomography (PET) imaging in rats in order to answer critical questions about the neurobiological basis of learning and decision-making in the brain. MicroPET technology provides PET images without the confounds induced by anaesthesia. Using this technology, the project intends to observe whole-brain changes in ....PET imaging of learning-related plasticity in awake behaving rats. The objective of the project is to combine an investigation of basic learning paradigms with functional Positron emission tomography (PET) imaging in rats in order to answer critical questions about the neurobiological basis of learning and decision-making in the brain. MicroPET technology provides PET images without the confounds induced by anaesthesia. Using this technology, the project intends to observe whole-brain changes in dopamine neurotransmission in awake, behaving rats while they learn to predict motivationally relevant outcomes based on environmental cues and on their own actions (ie during Pavlovian and instrumental conditioning, respectively). The outcomes of this research may improve our understanding of the neural changes responsible for debilitating disorders of the brain and mind.Read moreRead less