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
Special Research Initiatives - Grant ID: SR0354500
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
ARC Research Network in Microarray Technology. The primary aim of this proposal is to transform the premier genomic technology into a standard research tool; microarrays are now a priority for anyone studying the genetics underlying key biological processes. A principal challenge for the Australian research community is to capture all aspects of microarray technology and make them readily available. We will address these needs by developing a network to:
-establish regular research meetings,
- ....ARC Research Network in Microarray Technology. The primary aim of this proposal is to transform the premier genomic technology into a standard research tool; microarrays are now a priority for anyone studying the genetics underlying key biological processes. A principal challenge for the Australian research community is to capture all aspects of microarray technology and make them readily available. We will address these needs by developing a network to:
-establish regular research meetings,
-facilitate training in array methodologies and bioinformatics,
-co-ordinate innovation of technologies,-provide centralised data warehousing,
-provide access to automated high-level gene annotation,
-provide data mining tools,
-set standards for data management and exchangeRead moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453608
Funder
Australian Research Council
Funding Amount
$579,230.00
Summary
Multifunctional confocal laser scanning microscope with time resolved and two photon imaging and fluorescence correlation capabilities. We seek to establish an Australian first confocal laser scanning microscope with time resolved imaging and fluorescence correlation spectroscopy capabilities. Its advantages include ultrasensitive detection of weak fluorescent emissions against high autofluorescent background by using fluorescence lifetime signatures, with over three orders of magnitude discrimi ....Multifunctional confocal laser scanning microscope with time resolved and two photon imaging and fluorescence correlation capabilities. We seek to establish an Australian first confocal laser scanning microscope with time resolved imaging and fluorescence correlation spectroscopy capabilities. Its advantages include ultrasensitive detection of weak fluorescent emissions against high autofluorescent background by using fluorescence lifetime signatures, with over three orders of magnitude discrimination improvement. The system will also be able to monitor binding of single molecules. These techniques will open new and exciting avenues for interdisciplinary research at the frontier between biological and physical sciences. The microscope will operate within an existing multi-user Optical Characterisation Facility supporting research of an established network of scientists in the Sydney area.Read moreRead less
Development of dense gas technology platforms for the formulation of oral vaccines. This project will aim to develop a technology platform that enables the formulation of vaccines that can be delivered orally and this research has the potential to radically change existing vaccination regimens. The availability of needle-free vaccination also has potential for considerable societal and economic impact in developing countries.
Development of a light detection system for enhanced scanning electron microscopy imaging of fully hydrated biological specimens at room temperature. This project aims to develop instrumentation and techniques to image fully hydrated cellS for prolonged periods at room temperature in an environmental scanning electron microscope. Multiple fluorescent nano-particle labels will be used to image complex cellular structure and dynamics at ultra high spatial resolution. This innovative bio-imaging te ....Development of a light detection system for enhanced scanning electron microscopy imaging of fully hydrated biological specimens at room temperature. This project aims to develop instrumentation and techniques to image fully hydrated cellS for prolonged periods at room temperature in an environmental scanning electron microscope. Multiple fluorescent nano-particle labels will be used to image complex cellular structure and dynamics at ultra high spatial resolution. This innovative bio-imaging technique will be facilitated by the construction of a high speed light collection system that can efficiently operate at the pressures required to stablise water within the cell. Applications for this new bio-imaging technique will also be explored.Read moreRead less
Efficient Operation of Bioreactors using Nonlinear Dynamical Systems Theory. Current methods of determining optimal operating conditions in bioreactors have recently been shown to be inefficient, resulting in serious omissions of crucial parameter regions. We will use mathematical techniques from dynamical systems theory to establish a general framework by which bioreactor systems can be efficiently and systematically investigated to improve reactor performance. By communicating these results at ....Efficient Operation of Bioreactors using Nonlinear Dynamical Systems Theory. Current methods of determining optimal operating conditions in bioreactors have recently been shown to be inefficient, resulting in serious omissions of crucial parameter regions. We will use mathematical techniques from dynamical systems theory to establish a general framework by which bioreactor systems can be efficiently and systematically investigated to improve reactor performance. By communicating these results at relevant fora, we will increase the awareness within the Australian and international engineering communities of the advantages of modern mathematical techniques. Although this proposal focuses on bioreactors, the techniques can be easily adapted to improve the performances of other chemical processes.
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Targeting particulate carriers to epithelial M cells. This project aims to develop and validate an advanced in vitro model of the human intestinal epithelium. The intestine-on-chip model should enable mechanistic studies of the uptake of nano- and micron-size particles by intestinal cells and deliver new insights into the way particulate carriers can be specifically targeted and transported across the intestinal epithelium. Project knowledge and technology are anticipated to generate new commerc ....Targeting particulate carriers to epithelial M cells. This project aims to develop and validate an advanced in vitro model of the human intestinal epithelium. The intestine-on-chip model should enable mechanistic studies of the uptake of nano- and micron-size particles by intestinal cells and deliver new insights into the way particulate carriers can be specifically targeted and transported across the intestinal epithelium. Project knowledge and technology are anticipated to generate new commercialisation opportunities in the oral delivery industry and ultimately, should drive the development of efficient oral formulations for biologics. The model should also reduce the need for animal studies.Read moreRead less
Bacterial detection and infection control using tethered membranes. This project will develop a rapid diagnostic tool to detect live bacteria, which will subsequently reduce risk of infection, increase efficiencies in patient care and hospital management, and produce savings in health care budgets. It also has the potential to save lives through addressing the serious and growing problem of antibiotic resistance.
Manipulation of Biological Particles Using Dielectrophoresis. Dielectrophoretic manipulation and separation of particles has numerous biological and medical applications, e.g. identification and characterisation of individual cells, purification of cell subpopulations from mixture suspensions, etc. This research project aims to develop a high-efficiency and low-cost DEP device for bio-particle manipulation. It will contribute significantly to the advancements in the field of biological Micro-Ele ....Manipulation of Biological Particles Using Dielectrophoresis. Dielectrophoretic manipulation and separation of particles has numerous biological and medical applications, e.g. identification and characterisation of individual cells, purification of cell subpopulations from mixture suspensions, etc. This research project aims to develop a high-efficiency and low-cost DEP device for bio-particle manipulation. It will contribute significantly to the advancements in the field of biological Micro-Electrical-Mechanical-Systems (MEMS) and nanotechnology. Industry will benefit from the expertise on micro/nano-structures and micro/nano-manufacturing achieved by this project.Read moreRead less
Benign fabrication of microfluidic hydrogel for improved artificial vasculature in bone implants. We will create a benign technology for synthesising microfluidic hydrogels to generate artificial vascultures in bone implants. It is a critical step to enable the use of tissue-engineered vital organs, such as bone, heart and kidney in patients with end-stage organ failure. Thicker scaffolds will be possible, as the vasculature will provide nutrients and oxygen for cells to grow into 3D scaffolds. ....Benign fabrication of microfluidic hydrogel for improved artificial vasculature in bone implants. We will create a benign technology for synthesising microfluidic hydrogels to generate artificial vascultures in bone implants. It is a critical step to enable the use of tissue-engineered vital organs, such as bone, heart and kidney in patients with end-stage organ failure. Thicker scaffolds will be possible, as the vasculature will provide nutrients and oxygen for cells to grow into 3D scaffolds. It will promote capacity of Australia for manufacturing global biomaterial products for tissue engineering. We will also develop in-situ imaging analytical protocols for the rapid analysis of broad arrays of functional molecules, with significant bearing on BioMEMS design to develop methods for diagnosis of fatal diseases.Read moreRead less