Developing innovative contact lens designs and materials for effective and safe corneal refractive reshaping. Despite the increasing prevalence of refractive errors, there are limited options available for refractive error correction. Current contact lens designs for orthokeratology, a corneal reshaping technique which temporarily reduces refractive error, are effective for correcting only low to moderate myopia (short-sightedness). In this project, we will use innovative lens design approache ....Developing innovative contact lens designs and materials for effective and safe corneal refractive reshaping. Despite the increasing prevalence of refractive errors, there are limited options available for refractive error correction. Current contact lens designs for orthokeratology, a corneal reshaping technique which temporarily reduces refractive error, are effective for correcting only low to moderate myopia (short-sightedness). In this project, we will use innovative lens design approaches that harness the fluid forces generated in the post-lens tear film, and modulation of the corneal tissue response to these pressures, to develop novel contact lens designs in appropriate lens materials for effective and safe corneal reshaping to correct a wide range of refractive errors.Read moreRead less
The future of corneal refractive reshaping: can we control myopia or is the risk of corneal compromise too great? Refinement of corneal reshaping lens designs, optimised for visual outcomes through manipulation of aberrations, will significantly benefit local contact lens manufacturing and export by expanding the existing market base. This research will also strategically position Australian lens manufacturing to capitalise on the market for myopia-control contact lenses, particularly in the As ....The future of corneal refractive reshaping: can we control myopia or is the risk of corneal compromise too great? Refinement of corneal reshaping lens designs, optimised for visual outcomes through manipulation of aberrations, will significantly benefit local contact lens manufacturing and export by expanding the existing market base. This research will also strategically position Australian lens manufacturing to capitalise on the market for myopia-control contact lenses, particularly in the Asian region. Significant intellectual property will be generated for Australia in terms of enhanced understanding of the role of manipulation of corneal shape in modulating progressive myopia. Outcomes from this project will enhance the international reputation of the UNSW research group, keeping Australian science at the forefront of this area of research.Read moreRead less
Harnessing contact lens design to optimise optics and vision through corneal refractive reshaping. Development of innovative OK lens designs to correct presbyopia and astigmatism, optimised for visual performance through manipulation of optical aberrations, will place Australian rigid contact lens manufacturing at the international forefront of OK lens production. Lens designs to control myopia progression will strategically position Australian lens manufacturing to capitalise on the potential m ....Harnessing contact lens design to optimise optics and vision through corneal refractive reshaping. Development of innovative OK lens designs to correct presbyopia and astigmatism, optimised for visual performance through manipulation of optical aberrations, will place Australian rigid contact lens manufacturing at the international forefront of OK lens production. Lens designs to control myopia progression will strategically position Australian lens manufacturing to capitalise on the potential market in Asia, where myopia is prevalent. Significant intellectual property will be generated for Australia through greater understanding of OK lens design manipulation to optimise visual outcomes. This project promises to enhance the international reputation of UNSW researchers, keeping Australian science at the forefront of this research area.Read moreRead less
Adopting innovative strategies to manipulate and refine desirable optical outcomes from contact lens wear and corneal refractive reshaping. Corneal refractive reshaping is a contact lens-based technique that moulds the front surface of the eye to correct refractive errors. The corneal reshaping process is slow, making research in this area inefficient. This project will reshape the front surface of large diameter rigid lenses, allowing immediate evaluation of optical outcomes.
Antimicrobial contact lens cases. Contamination of contact lens cases is now recognised as a major risk factor driving the incidence of corneal infections during contact lens wear. This project will develop novel antimicrobial materials for manufacture of lens cases for the prevention of infections associated with contact lens wear.
Enhancing sunscreen DNA and photo-ageing protection. Skin damage from UV exposure is costly for individuals and the community, particularly in Australia, where the population has predominantly fair skin. While public campaigns to persuade the population to use sun protection and avoidance have been useful, this project will be the first to extend this approach to deliver a way to reduce sun damage from any UV exposure that does nevertheless occur, by incorporating the active agents into topical ....Enhancing sunscreen DNA and photo-ageing protection. Skin damage from UV exposure is costly for individuals and the community, particularly in Australia, where the population has predominantly fair skin. While public campaigns to persuade the population to use sun protection and avoidance have been useful, this project will be the first to extend this approach to deliver a way to reduce sun damage from any UV exposure that does nevertheless occur, by incorporating the active agents into topical sunscreens or creams for after-sun use. The project will also build infrastructure for translational research on photo-damage, combining world-class facilities for this research with advanced formulation and manufacturing operations.Read moreRead less
ARC Research Network for Advanced Materials. Materials science/engineering is decidedly interdisciplinary, covering all science and impacting on all manufacturing industry. This network will promote interactions that do not usually occur between materials researchers and students across Australia and internationally from diverse disciplines. The scope is broadly based on advanced materials production, processing and properties but focused in four areas, involving: i) innovative structural/functi ....ARC Research Network for Advanced Materials. Materials science/engineering is decidedly interdisciplinary, covering all science and impacting on all manufacturing industry. This network will promote interactions that do not usually occur between materials researchers and students across Australia and internationally from diverse disciplines. The scope is broadly based on advanced materials production, processing and properties but focused in four areas, involving: i) innovative structural/functional materials, ii) high-tech IT/communications/sensing materials, iii) materials solutions for manufacturing, iv) materials for a sustainable Australia, and v) emerging materials technologies. Key programs will promote interdisciplinary workshops and early career researcher interactions.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100894
Funder
Australian Research Council
Funding Amount
$361,140.00
Summary
Nanolamps: unlocking targeted gene silencing in deep tissue with nanoparticle-based light sources. In order to better understand the function of genes, this project will develop a new method of tightly targeted gene silencing deep inside of the body by nanoscale light sources. This will shed new light on the nervous system and, in the first instance, help to elucidate the role of the PACAP neurons in blood pressure regulation.
Special Research Initiatives - Grant ID: SR0354512
Funder
Australian Research Council
Funding Amount
$30,000.00
Summary
Network Asia: Maximizing Australia's National Capacity in Inter-Disciplinary Research on Asia. Australia has an international reputation for innovative and high impact research into the states, societies, and economies of Asia.
The Initiative will survey the volume, range, impact, and international status of Asian area research in Australia, identify themes with high potential for achieving significant outcomes through transnational research and research-training, and develop a strategy for m ....Network Asia: Maximizing Australia's National Capacity in Inter-Disciplinary Research on Asia. Australia has an international reputation for innovative and high impact research into the states, societies, and economies of Asia.
The Initiative will survey the volume, range, impact, and international status of Asian area research in Australia, identify themes with high potential for achieving significant outcomes through transnational research and research-training, and develop a strategy for maximizing national research capacity in targeted areas through a national inter-disciplinary network for Asia-area research - Network Asia.
Outcomes include a published report on the state of the field and a strategic plan for a viable and sustainable research network.
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Discovery Early Career Researcher Award - Grant ID: DE170100952
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A chemical looping process for carbon fibre production from plastics. This project aims to develop Mineral Looping Plastic Reforming (MLPR), a chemical looping reforming process for tonnage production of carbon nanofibers from plastic waste. This efficient process uses naturally occurring minerals (limestone, dolomite and ilmenite) to convert plastic waste to carbon nanofibers. The project will research the inner working of the MLPR process and the reforming reactions of plastics in the presence ....A chemical looping process for carbon fibre production from plastics. This project aims to develop Mineral Looping Plastic Reforming (MLPR), a chemical looping reforming process for tonnage production of carbon nanofibers from plastic waste. This efficient process uses naturally occurring minerals (limestone, dolomite and ilmenite) to convert plastic waste to carbon nanofibers. The project will research the inner working of the MLPR process and the reforming reactions of plastics in the presence of naturally occurring mineral mixtures. This project is expected to make Australia a leader in waste use, facilitate the uptake of abundant waste streams to produce high value products, and resolve sustainability, energy and environmental issues in Australia.Read moreRead less