A miniaturised laser manipulator for ultra-precise and pain-free dentistry. This project aims to develop a miniaturized high-precision laser robotic device that can fit comfortably in the mouth to perform pain-free, vibration-free dental operations by utilising silicon-carbide on silicon technology to create a millimetre-sized two-axis controllable, highly-reflective mirror robust to high-power ultra-short laser pulses. This project expects to generate new knowledge in micro-mirror control using ....A miniaturised laser manipulator for ultra-precise and pain-free dentistry. This project aims to develop a miniaturized high-precision laser robotic device that can fit comfortably in the mouth to perform pain-free, vibration-free dental operations by utilising silicon-carbide on silicon technology to create a millimetre-sized two-axis controllable, highly-reflective mirror robust to high-power ultra-short laser pulses. This project expects to generate new knowledge in micro-mirror control using optically excited piezo-resistive sensors, and cold femtosecond laser ablation of hard dental tissue. Expected outcomes include a working prototype for laser removal of tooth materials at speeds exceeding dental drills, providing benefits in miniaturized laser devices and ultimately removing pain from dental procedures. Read moreRead less
Diamond lasers for precision applications. Diamond lasers for precision applications. The project aims to create single mode lasers of ultrahigh spectral brightness. Single-mode lasers could improve many areas of science and technology, but existing technologies do not meet all performance requirements. This project will harness the intrinsic properties of diamond Raman lasers to increase the wavelength reach, power and stability of single mode lasers. The expected outcome is laser technology th ....Diamond lasers for precision applications. Diamond lasers for precision applications. The project aims to create single mode lasers of ultrahigh spectral brightness. Single-mode lasers could improve many areas of science and technology, but existing technologies do not meet all performance requirements. This project will harness the intrinsic properties of diamond Raman lasers to increase the wavelength reach, power and stability of single mode lasers. The expected outcome is laser technology that satisfies the needs of emerging markets, for example in gas sensing and atom cooling.Read moreRead less
Chip liquid chromatography-inductively coupled plasma-mass spectrometry: a new hyphenated microfluidic instrument for metallomics. An alliance of two Australian universities and a world-leading scientific instrument company will develop innovative technology that will enable new reliable, sensitive and patient-specific medical tests, as well as being used to probe causes of significant diseases that appear to involve trace levels of metals in the body.
In vivo molecular imaging using engineered affinity reagents and fluorescent laser scanning confocal endomicroscopy. The goal of this project is to develop laser scanning confocal endomicroscopy as a tool for basic scientific discovery and rapid detection of disease biomarkers. The cutting-edge instrument and associated technologies will provide scientists with unprecedented access to dynamic biological processes as they occur in real-time. In addition, it will enable the development of virtual ....In vivo molecular imaging using engineered affinity reagents and fluorescent laser scanning confocal endomicroscopy. The goal of this project is to develop laser scanning confocal endomicroscopy as a tool for basic scientific discovery and rapid detection of disease biomarkers. The cutting-edge instrument and associated technologies will provide scientists with unprecedented access to dynamic biological processes as they occur in real-time. In addition, it will enable the development of virtual biopsies and instant diagnosis without the need for costly and time-consuming histopathological reports. Thus, it will not only drive transformative research but also transform health care delivery. It will also be a major boost to the Australian biotechnology industry with potential for enormous economic benefits.Read moreRead less
Development of mock circulatory system for complex haemodynamic modelling. This project aims to develop a unique mock experimental system to study blood flow dynamics in anatomically realistic coronary artery phantoms. The field of cardiology involves complex fluid dynamic problems, which require the expertise of the fluid dynamics engineer to understand the hemodynamics. Significant innovation in manufacturing and experimental measurement methodologies will be required to develop accurate model ....Development of mock circulatory system for complex haemodynamic modelling. This project aims to develop a unique mock experimental system to study blood flow dynamics in anatomically realistic coronary artery phantoms. The field of cardiology involves complex fluid dynamic problems, which require the expertise of the fluid dynamics engineer to understand the hemodynamics. Significant innovation in manufacturing and experimental measurement methodologies will be required to develop accurate models, which will be designed to allow the partner organisation to undertake further hemodynamic research.Read moreRead less
Combined optical and electrical stimulation of auditory neurons. The bionic ear, which has now helped to improve the hearing of over 200,000 people worldwide, is a great example of Australian innovation success. This project aims to develop the fundamental technology that will underpin the next generation of these devices using a combination of infrared light and electrical signals to stimulate auditory nerves.
Scaling manufacture of three-dimensional microstructures for the medical devices industry. Scaling manufacture of three-dimensional microstructures for the medical devices industry. This project aims to transform microscale three-dimensional prototyping into a cheap high volume manufacturing process through a novel soft embossing process. Although three-dimensional printing has been hailed as a disruptive technology, because it can print complex shapes directly from drawings, it is too slow at m ....Scaling manufacture of three-dimensional microstructures for the medical devices industry. Scaling manufacture of three-dimensional microstructures for the medical devices industry. This project aims to transform microscale three-dimensional prototyping into a cheap high volume manufacturing process through a novel soft embossing process. Although three-dimensional printing has been hailed as a disruptive technology, because it can print complex shapes directly from drawings, it is too slow at microscale for high volume manufacture. This research will develop microdevices for painless collection of blood, its analysis, and drug delivery. Cost-effective manufacture of these microdevices is expected to tap into the large medical devices industry, leading to establishing new businesses in the point-of-care and drug delivery markets.Read moreRead less
A gold-coated magnetic nanoparticle biosensor for detecting microRNA. The project aims to develop a biosensor for detecting short sequences of RNA, called microRNA (miRNA) in blood. There are about 100 miRNA sequences that are involved in most biological processes. Changes in the levels of some miRNA sequences can serve as a biomarker for many diseases including cancers. The miRNA will be detected using gold-coated magnetic nanoparticles modified with DNA sequences complementary to the miRNA of ....A gold-coated magnetic nanoparticle biosensor for detecting microRNA. The project aims to develop a biosensor for detecting short sequences of RNA, called microRNA (miRNA) in blood. There are about 100 miRNA sequences that are involved in most biological processes. Changes in the levels of some miRNA sequences can serve as a biomarker for many diseases including cancers. The miRNA will be detected using gold-coated magnetic nanoparticles modified with DNA sequences complementary to the miRNA of interest to capture the miRNA. Application of a magnetic field allows the levels of miRNA to be detected electrochemically. The expected outcome is a commercialisable biosensor for miRNA both as a diagnostic early detection device and a prognostic device for a range of miRNA biomarkers.Read moreRead less
Noise-free Cryogenic Wavefront Sensing. This project aims to optimise the prototype adaptive optics technology for the Giant Magellan Telescope (GMT) by leveraging past investment in adaptive optics instrumentation and shortwave infrared detector systems. This project expects to generate significant improvements in GMT performance, with ten times greater image resolution than the Hubble Space Telescope and current estimates of >90% sky coverage, compared with ~50% coverage for current technology ....Noise-free Cryogenic Wavefront Sensing. This project aims to optimise the prototype adaptive optics technology for the Giant Magellan Telescope (GMT) by leveraging past investment in adaptive optics instrumentation and shortwave infrared detector systems. This project expects to generate significant improvements in GMT performance, with ten times greater image resolution than the Hubble Space Telescope and current estimates of >90% sky coverage, compared with ~50% coverage for current technology. Expected outcomes of this project include the development of a highly trained workforce and continued international collaboration in the field of high-technology sensor systems. This contribution to the GMT will provide significant benefits—it will change the way we view the Universe.Read moreRead less
Scaling microfluidics for cell manufacture. Scaling microfluidics for cell manufacture. This project aims to scale microfluidic devices for cell manufacture. Large-scale cell manufacturing processes (cell selection, gene transfer and culture expansion) are expensive, multistep and labour-intensive processes. Lab-on-a-chip devices can automate and integrate these complex processes at microscale. This project will evaluate a prototype bioreactor. This research is expected to make cell therapies ch ....Scaling microfluidics for cell manufacture. Scaling microfluidics for cell manufacture. This project aims to scale microfluidic devices for cell manufacture. Large-scale cell manufacturing processes (cell selection, gene transfer and culture expansion) are expensive, multistep and labour-intensive processes. Lab-on-a-chip devices can automate and integrate these complex processes at microscale. This project will evaluate a prototype bioreactor. This research is expected to make cell therapies cheap enough to become standard treatment, which would benefit patients with diseases that are incurable by conventional therapies (surgery and drug treatments). It should also benefit the Australian advanced manufacturing sector, particularly biopharmaceutical and cell therapy industries.Read moreRead less