Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882701
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Establishment of a confocal/multiphoton microscope for imaging of living systems. This facility will allow us to study the dynamic changes in living systems, from the smallest unicellular organisms in the ocean through to the sophisticated neural networks of the living brain. Not only will this imaging facility allow us to understand how living systems work, we will also be able to explore the dynamic changes that underlie human disease and injury.
Involvement of cell coupling in vascular function: Development of a computational model. Gap junctions are intercellular channels which enable the production of coordinated responses in multicellular tissues and organs. Blood vessels are comprised of endothelial cells surrounded by smooth muscle cells and gap junctions exist within and between these layers. The present proposal will determine the fundamental role of gap junctions in regulating blood flow and blood pressure. Our data will enable ....Involvement of cell coupling in vascular function: Development of a computational model. Gap junctions are intercellular channels which enable the production of coordinated responses in multicellular tissues and organs. Blood vessels are comprised of endothelial cells surrounded by smooth muscle cells and gap junctions exist within and between these layers. The present proposal will determine the fundamental role of gap junctions in regulating blood flow and blood pressure. Our data will enable us to develop a computational model of the vascular wall and so predict how changes in electrical properties, as occur during pressure changes, can influence blood flow. Since ageing is accompanied by an increase in blood pressure, our results will contribute to a better understanding of blood flow regulation in our ageing population.Read moreRead less
Self-Powered Wireless Sensor Networks, Enabling an Intelligent Agricultural Environment. Most animal production enterprises could be considerably more productive if the physiological status of each animal were to be continuously monitored, and the appropriate adjustments were made in real time. The proposed project will develop technologies that will enable continuous, real-time monitoring resulting in more efficient use of Australia's resources. Furthermore, research on wireless sensor network ....Self-Powered Wireless Sensor Networks, Enabling an Intelligent Agricultural Environment. Most animal production enterprises could be considerably more productive if the physiological status of each animal were to be continuously monitored, and the appropriate adjustments were made in real time. The proposed project will develop technologies that will enable continuous, real-time monitoring resulting in more efficient use of Australia's resources. Furthermore, research on wireless sensor networks, or ambient intelligence as it is sometimes called, is at the forefront of wireless communications and indeed ICT technology. This project will benefit Australia's ICT community both by training new professional and research leaders in this area, and by developing technologies that will further enable this rapidly growing field.Read moreRead less
Cellular and network basis of information processing in the mammalian visual system. The project aims to discover the strategies by which cells in the brain interact with each other to code the sensory input efficiently. It is expected that simultaneous recording of the activity of many neurones from the visual cortex of anaesthetised cats during visual stimulation will reveal how the biophysics of synaptic integration combined with excitatory and inhibitory inputs from different sources sculpt ....Cellular and network basis of information processing in the mammalian visual system. The project aims to discover the strategies by which cells in the brain interact with each other to code the sensory input efficiently. It is expected that simultaneous recording of the activity of many neurones from the visual cortex of anaesthetised cats during visual stimulation will reveal how the biophysics of synaptic integration combined with excitatory and inhibitory inputs from different sources sculpts the output of individual neurones. The experiments will be extended to the study of possible interactions between different areas of the brain and the study of mechanisms by which the cortical network and higher cognitive factors such as attention and memory might influence the coding of sensory information in awake animals.Read moreRead less