Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453630
Funder
Australian Research Council
Funding Amount
$274,692.00
Summary
High-Speed Confocal Microscope Live Cell Recording System. The high-speed confocal microscope live cell recording system we are establishing represents new generation equipment. It allows quality imaging of selected subcellular regions of live cells combined with simultaneous electrophysiological recording at rates and sensitivity hitherto not possible. This equipment provides a window of opportunity for major research advances in that it allows real-time two and three-dimensional imaging of fun ....High-Speed Confocal Microscope Live Cell Recording System. The high-speed confocal microscope live cell recording system we are establishing represents new generation equipment. It allows quality imaging of selected subcellular regions of live cells combined with simultaneous electrophysiological recording at rates and sensitivity hitherto not possible. This equipment provides a window of opportunity for major research advances in that it allows real-time two and three-dimensional imaging of fundamental cellular activities that previously could not be viewed. It will allow major advances in priority health-related research and will provide an ideal research tool to introduce young scientists and students to cutting edge research.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100775
Funder
Australian Research Council
Funding Amount
$368,446.00
Summary
Using nanostructured scaffolds to understand and engineer neuronal circuits. This project aims to understand the formation of neuronal circuits in the brain. While the role of biochemical features in the brain is well understood, it is not clear how the biophysical properties of the brain affect circuit formation. The outcomes of this project will improve our understanding of neuronal circuit formation as well as provide design rules for creating scaffolds to repair neuronal circuits after brain ....Using nanostructured scaffolds to understand and engineer neuronal circuits. This project aims to understand the formation of neuronal circuits in the brain. While the role of biochemical features in the brain is well understood, it is not clear how the biophysical properties of the brain affect circuit formation. The outcomes of this project will improve our understanding of neuronal circuit formation as well as provide design rules for creating scaffolds to repair neuronal circuits after brain damage. This project will integrate Australia’s strengths in nanotechnology and neurosciences, bringing Australian research at the forefront of neural engineering.Read moreRead less
Using light to probe brain activity in three dimensions. The project aims to understand information flow in the mammalian brain using simultaneous projection of multiple light probes directed into living brain tissues to manipulate and record brain activity.
Improving neuronal cell function with cell permeable copper complexes. Metal-based drugs offer an exciting new approach to treatment of neurodegeneration. However, little is known about how cells metabolise these drugs and this information is critical for further drug development. This project will determine how metal-based drugs are metabolised by neuronal cells and how this may result in therapeutic benefit.
Four-dimensional analysis of information processing in brain circuits. Analysing how neurons process information could provide us with knowledge of the basic function of the brain as well as insights to neuropsychiatric disorders. The aim is to understand how does a single neuron process its synaptic inputs to arrive at an output response. To achieve this, the project will follow two approaches: it will study single neurons via in vitro experiments, where spatiotemporal patterns of light stimuli ....Four-dimensional analysis of information processing in brain circuits. Analysing how neurons process information could provide us with knowledge of the basic function of the brain as well as insights to neuropsychiatric disorders. The aim is to understand how does a single neuron process its synaptic inputs to arrive at an output response. To achieve this, the project will follow two approaches: it will study single neurons via in vitro experiments, where spatiotemporal patterns of light stimuli mimic physiological synaptic inputs; and, it will build a unique in vivo microscope to map sensory inputs to neuronal circuits in the intact brain. The first approach provides an accurate analysis of neuronal circuits while the second creates an overall map of cortical processing of sensory inputs from a live animal.Read moreRead less
Dynamic Trafficking Of Amino Acid Transporters At Synapses And Their Role In Regulating Neurotransmission
Funder
National Health and Medical Research Council
Funding Amount
$421,219.00
Summary
Brain cells release chemical neurotransmitters to activate their neighbours. The most abundant neurotransmitter is glutamate, which mediates most of the communication in the brain. Following release, this neurotransmitter must be rapidly recycled to prevent levels being depleted and neurotransmission failing. The subject of this grant is to understand what molecules and pathways are used to recycle glutamate in the brain, and how its supply is controlled to sustain continual brain activation.