Special Research Initiatives - Grant ID: SR0354494
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
BRAINnet:
Brain Research And Integrative Neuroscience Network. The brain is the ultimate frontier of science, and its complexity requires an integrative approach to neuroscience. This initiative will facilitate a unique integration of disciplines (biological, physical, computational) and scales of focus (single neurons to networks to whole-brain), within a high profile Network of Australian and international players. The Network will be harnessed by a centralized hub for sharing of data and tec ....BRAINnet:
Brain Research And Integrative Neuroscience Network. The brain is the ultimate frontier of science, and its complexity requires an integrative approach to neuroscience. This initiative will facilitate a unique integration of disciplines (biological, physical, computational) and scales of focus (single neurons to networks to whole-brain), within a high profile Network of Australian and international players. The Network will be harnessed by a centralized hub for sharing of data and techniques, and mentoring of early career researchers. The principal socio-economic and discovery outcomes will flow from the exceptionally strong foundations in fundamental and applied science, established collaboration, and demonstrated capacity for development and commercialization of frontier biotechnologies.Read moreRead less
Visual processing in a unique modular system - how can a simple cognitive architecture be used to solve complex visual tasks? The proposed interdisciplinary study of the visual system of jumping spiders will provide novel insights into how a simple cognitive architecture can be used to solve complex visual tasks. This will be the first comprehensive study of motion sensitivity in a spider. The insights obtained will be important for the development of artificial intelligence systems. We will pro ....Visual processing in a unique modular system - how can a simple cognitive architecture be used to solve complex visual tasks? The proposed interdisciplinary study of the visual system of jumping spiders will provide novel insights into how a simple cognitive architecture can be used to solve complex visual tasks. This will be the first comprehensive study of motion sensitivity in a spider. The insights obtained will be important for the development of artificial intelligence systems. We will provide a stimulating environment to train a postdoctoral fellow with state-of-art skills ranging from single-cell neurophysiology through to using 3D animation for sophisticated behavioural assays. The proposed work is a hot topic and will attract considerable attention, raise the profile of Australian science, and support postgraduate students. Read moreRead less
Sensory Coding Mechanisms in Rat Somatosensory System; A Combined Behavioural and Electrophysiological Approach. This inter-disciplinary project spans behavioural sciences, neurophysiology and computational neuroscience. It investigates fundamental questions such as how different aspects of stimuli are presented in sensory areas of the brain and how the animal interprets the neuronal activity in such areas to generate the relevant behaviour. A major problem with making prosthetic sensory devices ....Sensory Coding Mechanisms in Rat Somatosensory System; A Combined Behavioural and Electrophysiological Approach. This inter-disciplinary project spans behavioural sciences, neurophysiology and computational neuroscience. It investigates fundamental questions such as how different aspects of stimuli are presented in sensory areas of the brain and how the animal interprets the neuronal activity in such areas to generate the relevant behaviour. A major problem with making prosthetic sensory devices is the way by which these devices can communicate with the brain. Research into the coding of different features of simple stimuli will provide basic knowledge which can be implemented in prosthetic sensory devices. Read moreRead less
Complex Motion Processing in Primate Visual Cortex. As we move through the world, a dynamic visual image is projected onto our retinas. The pattern of movement in the retinal image contains information about three-dimensional structure in the environment and the time of impending collisions. Our visual systems are expert at exploiting this information, enabling us to navigate through complex visual environments at a level far beyond the most sophisticated artificial systems. We plan to investiga ....Complex Motion Processing in Primate Visual Cortex. As we move through the world, a dynamic visual image is projected onto our retinas. The pattern of movement in the retinal image contains information about three-dimensional structure in the environment and the time of impending collisions. Our visual systems are expert at exploiting this information, enabling us to navigate through complex visual environments at a level far beyond the most sophisticated artificial systems. We plan to investigate complex motion processing in the primate brain by recording the responses of neurons in identified regions of the visual cortex of macaque monkeys to a range of behaviourally relevant motion stimuli.Read moreRead less
Are there advantages in having a lateralized brain? Specialisation of the left and right hemispheres of the brain to process different information and to control different responses is not, as once thought, unique to humans but common to all vertebrates. In fact, the same general pattern of lateralization occurs in amphibians, reptiles, birds and mammals. Until now, it has been important to document the presence and nature of lateralization in different species. Now it is important to discover t ....Are there advantages in having a lateralized brain? Specialisation of the left and right hemispheres of the brain to process different information and to control different responses is not, as once thought, unique to humans but common to all vertebrates. In fact, the same general pattern of lateralization occurs in amphibians, reptiles, birds and mammals. Until now, it has been important to document the presence and nature of lateralization in different species. Now it is important to discover the advantages (and disadvantages) of having a lateralized brain. This project will do so using two model species, the chick and the marmoset, and new techniques to measure behaviour.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0452971
Funder
Australian Research Council
Funding Amount
$102,900.00
Summary
Optical imaging of brain activity: Studies of the neural basis of sensory perception, plasticity and behaviour. Basic to the understanding of the brain is to know how the overall architecture of the nervous system relates to its function. We propose to study this by directly visualising the regions that are functionally active in the living brains of animals, down to resolution limits of less than 100 micrometres. Such "optical imaging" will be done by recording light reflected from the surfac ....Optical imaging of brain activity: Studies of the neural basis of sensory perception, plasticity and behaviour. Basic to the understanding of the brain is to know how the overall architecture of the nervous system relates to its function. We propose to study this by directly visualising the regions that are functionally active in the living brains of animals, down to resolution limits of less than 100 micrometres. Such "optical imaging" will be done by recording light reflected from the surface of the brain, which in turn depends upon activity-dependent intrinsic signals (eg. degree of oxygenation of haemoglobin). These signals will be recorded by a special camera and amplified using the requested system.Read moreRead less
Force from lipids: the role of the lipid bilayer in mechanosensory transduction. The proposed research will significantly contribute to a better understanding of the wide range of physiological processes underlying mechanosensory transduction in living cells. The direct benefit for Australian science consists of: (i) strengthening international links with leading overseas laboratories, and (ii) accessing the state-of-the-art expertise not available in Australia. The acquired knowledge will aid i ....Force from lipids: the role of the lipid bilayer in mechanosensory transduction. The proposed research will significantly contribute to a better understanding of the wide range of physiological processes underlying mechanosensory transduction in living cells. The direct benefit for Australian science consists of: (i) strengthening international links with leading overseas laboratories, and (ii) accessing the state-of-the-art expertise not available in Australia. The acquired knowledge will aid in developing and designing artificial tactile sensors inspired by their biological models studied in this project. Long-term, the project is expected to make an original contribution towards developing new technologies and novel medical applications, both of which promise to be of great national benefit.Read moreRead less
Novel insecticidal neurotoxins from Australian spider venoms. Insecticidal toxins have considerable potential as novel biopesticides to combat the evolution of widespread insect resistance to classical chemical pesticides. This problem is increasing both in Australia and internationally. This study aims to isolate and pharmacologically characterise potent and selective insecticidal neurotoxins from Australian arachnids. Our laboratories will isolate neurotoxins from spider venoms, determine thei ....Novel insecticidal neurotoxins from Australian spider venoms. Insecticidal toxins have considerable potential as novel biopesticides to combat the evolution of widespread insect resistance to classical chemical pesticides. This problem is increasing both in Australia and internationally. This study aims to isolate and pharmacologically characterise potent and selective insecticidal neurotoxins from Australian arachnids. Our laboratories will isolate neurotoxins from spider venoms, determine their selectivity in insect and mammal bioassays, determine their primary and tertiary structures, and investigate their structure-function relationships by electrophysiological techniques. These functional and structural data will allow the future engineering, by molecular or synthetic procedures, of viral biopesticide analogues with increased potency, stability and selectivity.Read moreRead less