Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668382
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
e-Research Infrastructure for the Molecular and Materials Structure Sciences. Understanding molecular and materials structure in atomic detail is vital to a knowledge-based economy and a healthy society. The development of smart materials, nanotechnological devices, hydrogen storage materials, molecular switches, magnets and sensors, for example, depends on knowledge of three-dimensional atomic structure. Cures for illnesses such as SARS, AIDS and Alzheimer's disease and understanding the aging ....e-Research Infrastructure for the Molecular and Materials Structure Sciences. Understanding molecular and materials structure in atomic detail is vital to a knowledge-based economy and a healthy society. The development of smart materials, nanotechnological devices, hydrogen storage materials, molecular switches, magnets and sensors, for example, depends on knowledge of three-dimensional atomic structure. Cures for illnesses such as SARS, AIDS and Alzheimer's disease and understanding the aging process depends on knowledge of biomolecular structure. The deployment and development of automation-enhanced remote access to structural instruments through the web will greatly enhance Australian structure-based research, and make this science accessible to the public. Read moreRead less
DEVELOPMENT OF A NOVEL BIOMATERIAL FOR BONE TISSUE ENGINEERING. Tissue engineering of bone is emerging as a viable therapy for treating large defects in load-bearing bone. We wish to develop methods for combining novel heparan sulphate molecules (known to deliver growth factors to cell surfaces and thereby cause changes in bone cell phenotype) with load-bearing, macro-porous, biodegradable mineral/polymer biomaterials. Through the study of release profiles, protein adsorption and cell responses ....DEVELOPMENT OF A NOVEL BIOMATERIAL FOR BONE TISSUE ENGINEERING. Tissue engineering of bone is emerging as a viable therapy for treating large defects in load-bearing bone. We wish to develop methods for combining novel heparan sulphate molecules (known to deliver growth factors to cell surfaces and thereby cause changes in bone cell phenotype) with load-bearing, macro-porous, biodegradable mineral/polymer biomaterials. Through the study of release profiles, protein adsorption and cell responses to these derivatised biomaterials, a novel approach to bone replacement materials can be developed.Read moreRead less
Multiplexed Molecular Reading of Protein Associations via Nanoscaled Devices. Current developments in Nanoscience and Nanotechnology hold many promises in terms of revolutionising our industrial base, transforming biology, medical science and practice. This project strives to achieve some of these goals by, for the first time, building and testing nano-scaled devices with the capability to rapidly ?read? information about complex protein associations. With the recent completion of the Human Ge ....Multiplexed Molecular Reading of Protein Associations via Nanoscaled Devices. Current developments in Nanoscience and Nanotechnology hold many promises in terms of revolutionising our industrial base, transforming biology, medical science and practice. This project strives to achieve some of these goals by, for the first time, building and testing nano-scaled devices with the capability to rapidly ?read? information about complex protein associations. With the recent completion of the Human Genome project, major opportunities exist to provide spectacular advances in human health care (eg, via novel diagnostics) provided that appropriate high-throughput biological reading devices can be developed. In developing such devices, this project also aims to catalyse the Australian Nanotechnology/Biotechnology industry.Read moreRead less
Beyond Microarrays: Nano-Scaled Devices for High Throughput Biomolecular Sensing. Current developments in Nanoscience and Nanotechnology hold many promises in terms of revolutionising our industrial base, transforming biology, medical science and practice. This project strives to achieve some of these aims by, for the first time, building and testing nano-scaled devices with the capability to 'read' massive amounts of biological information. With the recent completion of the Human Genome proje ....Beyond Microarrays: Nano-Scaled Devices for High Throughput Biomolecular Sensing. Current developments in Nanoscience and Nanotechnology hold many promises in terms of revolutionising our industrial base, transforming biology, medical science and practice. This project strives to achieve some of these aims by, for the first time, building and testing nano-scaled devices with the capability to 'read' massive amounts of biological information. With the recent completion of the Human Genome project, major opportunities exist to provide spectacular advances in human health care (eg, via personalised medicine) provided that appropriate high-throughput biological reading devices can be developed. In developing such devices, this project also aims to substantially catalyse the Australian Nanotechnology/Biotechnology industry.Read moreRead less
Myofibroblast differentiation: from haemopoietic cells to smooth muscle. Until very recently the ability of adult cells with specific differentiated functions to re-differentiate for another function was thought to be extremely limited. However we have shown that cells ultimately derived from the bone marrow can differentiate into fibroblasts, then into myofibroblasts and then into smooth muscle cells. This project will build on these unique findings and determine the molecular mechanisms cont ....Myofibroblast differentiation: from haemopoietic cells to smooth muscle. Until very recently the ability of adult cells with specific differentiated functions to re-differentiate for another function was thought to be extremely limited. However we have shown that cells ultimately derived from the bone marrow can differentiate into fibroblasts, then into myofibroblasts and then into smooth muscle cells. This project will build on these unique findings and determine the molecular mechanisms controlling this process. We hypothesise that the local environment of a cell is critical and will involve a combination of particular extracellular matrix and growth factors as well as mechanical tension and the presence of other cell types.Read moreRead less
CX3C chemokine signalling in the olfactory epithelium and its role in the self regeneration of the olfactory system. The current proposal will explore new venues in adult neural stem cell research and contribute to the further development of molecular biology and neuroscience research in Western Australia and Australia. The use of neural stem cells holds therapeutic promise for the treatment of a wide variety of neurological conditions, including neurotrauma and stroke. The proposed research wil ....CX3C chemokine signalling in the olfactory epithelium and its role in the self regeneration of the olfactory system. The current proposal will explore new venues in adult neural stem cell research and contribute to the further development of molecular biology and neuroscience research in Western Australia and Australia. The use of neural stem cells holds therapeutic promise for the treatment of a wide variety of neurological conditions, including neurotrauma and stroke. The proposed research will provide new data on the fundamental cellular and molecular events that are required to trigger the birth, differentiation and conditions for growth of new neurons in the adult nervous system. The generation of such insights will be critical for any translational research.
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Understanding how the multiple roles of olfactory ensheathing cells guide the growth and regeneration of olfactory axons. The outcomes of this project will increase the understanding of how nerve cells develop and regenerate after injury. The research outcomes and the development of new innovative methodologies as part of the project will be of high significance for the neuroscience research community both within Australia and overseas. The findings will also pave the way for the development of ....Understanding how the multiple roles of olfactory ensheathing cells guide the growth and regeneration of olfactory axons. The outcomes of this project will increase the understanding of how nerve cells develop and regenerate after injury. The research outcomes and the development of new innovative methodologies as part of the project will be of high significance for the neuroscience research community both within Australia and overseas. The findings will also pave the way for the development of novel therapies that promote neuronal regeneration relevant for disorders such as spinal cord injury and Alzheimer's disease, which constitute a large socio-economic burden in Australia. Currently, 400 people contract spinal cord injury every year, corresponding to an annual cost of $1 billion, and more than 500 000 aging people suffer from Alzheimer's disease.Read moreRead less
Genetic analysis of cohesin function and regulation in Drosophila. In yeast, a multiprotein complex, called cohesin, holds newly replicated chromatids together until the cell is ready to partition each chromatid into its daughter cells. We and others have shown that cohesins are regulated differently in animal cells. We propose to combine classical genetic analyses with two new and innovative techniques, time-lapse confocal microscopy of fluorescent proteins in living cells and gene-specific kno ....Genetic analysis of cohesin function and regulation in Drosophila. In yeast, a multiprotein complex, called cohesin, holds newly replicated chromatids together until the cell is ready to partition each chromatid into its daughter cells. We and others have shown that cohesins are regulated differently in animal cells. We propose to combine classical genetic analyses with two new and innovative techniques, time-lapse confocal microscopy of fluorescent proteins in living cells and gene-specific knockout techniques to study key cohesin regulators in Drosophila. These studies will provide us with novel insights into how multicellular organisms regulate the structure and stability of their chromosomes.Read moreRead less
Combined genetic and cellular analysis of melanisation to study variation in human pigmentation. This investigation examines variations in the genes that are important determinants of human skin pigmentation and are likely to be associated with skin cancer risk. Our research program will form the basis of future diagnostics based on major genes that determine a persons skin type. Current skin cancer prevention strategies rely predominantly on broad spectrum campaigns that are aimed at increasi ....Combined genetic and cellular analysis of melanisation to study variation in human pigmentation. This investigation examines variations in the genes that are important determinants of human skin pigmentation and are likely to be associated with skin cancer risk. Our research program will form the basis of future diagnostics based on major genes that determine a persons skin type. Current skin cancer prevention strategies rely predominantly on broad spectrum campaigns that are aimed at increasing the general community awareness of the damaging effects of UV radiation. A better understanding of the genetic basis of UV-sensitive skin types will greatly enhance the targeting of such skin cancer-prevention campaigns, provide an understanding of changes that occur in skin pathology, and the mechanisms of sun induced tanning.Read moreRead less
Parallel genetic and cellular analysis of melanogensis: A new paradigm to study variation in pigmentation. This is the first attempt to characterise the differences in human pigmentation using a combined genetic and cellular analysis of melanogenesis. We have the ability to culture the pigmenting cells of the human epidermis and hair follicles called melanocytes from individuals of defined genotype. This will allow us to correlate mutations in melanosomal proteins with functional defects withi ....Parallel genetic and cellular analysis of melanogensis: A new paradigm to study variation in pigmentation. This is the first attempt to characterise the differences in human pigmentation using a combined genetic and cellular analysis of melanogenesis. We have the ability to culture the pigmenting cells of the human epidermis and hair follicles called melanocytes from individuals of defined genotype. This will allow us to correlate mutations in melanosomal proteins with functional defects within the cells in culture using live cell imaging, electron microscopy and biochemical analysis. This will provide a molecular basis to explain the pigmentary characteristics of individuals allowing prediction and diagnosis of their photosensitivity with important implications for skin cancer risk.Read moreRead less