Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100043
Funder
Australian Research Council
Funding Amount
$435,279.00
Summary
High-throughput portable and wearable device fabrication facility. This project aims to establish a fabrication and characterisation facility for high-throughput production of portable, wearable and stretchable biomedical devices to accelerate the design–fabrication–evaluation process and save ‘trial-and-error’ costs during optimisation turnaround. It will apply computer-aided design for the programmable synthesis of hybrid materials for high-throughput screening of disease biomarkers, and super ....High-throughput portable and wearable device fabrication facility. This project aims to establish a fabrication and characterisation facility for high-throughput production of portable, wearable and stretchable biomedical devices to accelerate the design–fabrication–evaluation process and save ‘trial-and-error’ costs during optimisation turnaround. It will apply computer-aided design for the programmable synthesis of hybrid materials for high-throughput screening of disease biomarkers, and super-solution imaging of single molecules in live cells. This facility will provide capability for researchers pursuing industry transformation and other initiatives in the development of advanced materials, biomolecular sciences, nanotechnology, photonics and device engineering.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.
A novel scintillating optical fibre array for cancer imaging and therapy. This project aims to realise a next-generation detector technology that delivers the first fully integrated solution to the X-ray imaging and dose measurement needs of cancer radiation therapy. It is planned that this will be achieved by optimising an experimental prototype device employing a scintillating optical fibre array to generate an optical signal that preserves a tissue-equivalent detector response. The acquired d ....A novel scintillating optical fibre array for cancer imaging and therapy. This project aims to realise a next-generation detector technology that delivers the first fully integrated solution to the X-ray imaging and dose measurement needs of cancer radiation therapy. It is planned that this will be achieved by optimising an experimental prototype device employing a scintillating optical fibre array to generate an optical signal that preserves a tissue-equivalent detector response. The acquired digital image can thus be used to simultaneously verify geometric accuracy (correct patient positioning) and dosimetric accuracy (correct dose distribution). This is not currently possible with existing X-ray detector technology and offers an improvement in treatment accuracy.Read moreRead less
Complete blood fractionation using a low-cost microfluidic system. This project aims to understand particle focusing in inertial microfluidic systems to design efficient devices for cell sorting. The field of microfluidics could ultimately advance medical research but device design is primitive. Microfluidic particle separations are not thoroughly simulated before fabrication to predict performance. This project is expected to accelerate progress in design of efficient microfluidic devices. The ....Complete blood fractionation using a low-cost microfluidic system. This project aims to understand particle focusing in inertial microfluidic systems to design efficient devices for cell sorting. The field of microfluidics could ultimately advance medical research but device design is primitive. Microfluidic particle separations are not thoroughly simulated before fabrication to predict performance. This project is expected to accelerate progress in design of efficient microfluidic devices. The knowledge and models developed in this project should help design and develop a microfluidic device for efficient fractionation of complex fluids into valuable components.Read moreRead less
Novel technologies for motion-compensated simultaneous Magnetic Resonance Imaging (MRI) and Positron Emission Tomography (PET) imaging. The aim of this work is to develop motion tracking and motion correction techniques for an emerging hybrid imaging technology, MR-PET. The MR-PET scanner simultaneously acquires structural MR images and functional PET images. The work will provide clearer images without the effects of motion blur for both research and clinical applications.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100177
Funder
Australian Research Council
Funding Amount
$440,000.00
Summary
National Live Cell Scanning Platform for Nanoparticle Tracking. National live cell scanning platform for nanoparticle tracking: The aim of the project is to establish a multi-disciplinary, multi-user, self-correlated scanning facility to reach a new level of temporal and spatial precision for real-time tracking and quantification of biomolecules and nanoparticles within large populations of living cells. The facility will consist of a live-cell spinning-disc confocal microscope, a correlated bio ....National Live Cell Scanning Platform for Nanoparticle Tracking. National live cell scanning platform for nanoparticle tracking: The aim of the project is to establish a multi-disciplinary, multi-user, self-correlated scanning facility to reach a new level of temporal and spatial precision for real-time tracking and quantification of biomolecules and nanoparticles within large populations of living cells. The facility will consist of a live-cell spinning-disc confocal microscope, a correlated biological atomic force microscope, and remote access facilities. It is expected that with superior optical characterisation and mechanical manipulation, the automated orthogonal scanning facility will open new avenues to reveal unprecedented information from biological and pathological processes. The collaborative facility will support world-class researchers in the multi-disciplinary areas of physical, material and life sciences, placing Australia at the forefront of nanoscale biophotonics.Read moreRead less
Advanced Hybrid Fibres for Functional Biomedical Imaging. This project expects to develop new techniques and devices for biomedical imaging. Biomedical imaging is widely used for medical diagnosis and treatment, with different types of imaging providing different information. This project aims to develop techniques that will allow imaging using safer nonionising terahertz radiation, with better resolution than ever before. It plans to combine this with optical, visible and infrared imaging to gi ....Advanced Hybrid Fibres for Functional Biomedical Imaging. This project expects to develop new techniques and devices for biomedical imaging. Biomedical imaging is widely used for medical diagnosis and treatment, with different types of imaging providing different information. This project aims to develop techniques that will allow imaging using safer nonionising terahertz radiation, with better resolution than ever before. It plans to combine this with optical, visible and infrared imaging to give very broad spectral information. It also aims to develop probes for direct interfacing to tissue to collect and deliver electrical signals, light and fluids, and to image neural activity. The intended outcome of the project is to allow single cancer cells within tissue to be identified to allow early stage cancer detection, and to develop implantable devices for neuroscience research and pain management.Read moreRead less
Development of class-leading bioluminescence resonance energy transfer technologies for real-time monitoring of molecular interactions. The purpose of this project is to develop improved technologies for identifying and developing pharmaceuticals with fewer side effects. The expected outcome is the development of technologies that provide a level of sensitivity and data quality that enables adoption by the biotechnology and pharmaceutical industries.
Discovery Early Career Researcher Award - Grant ID: DE220100311
Funder
Australian Research Council
Funding Amount
$383,982.00
Summary
Shining nanoparticles for single microRNA detection in microfluidics. This project aims to extensively study the interface between nanoparticles and nucleic acids. It sets out to produce a novel ultrasensitive high-performance biosensing platform that will combine luminescent nanoparticles with microfluidics in a digital assay. This portable platform will detect biological fingerprints, or microRNAs, at a single-molecule level, delivering unprecedented levels of sensitivity and specificity. The ....Shining nanoparticles for single microRNA detection in microfluidics. This project aims to extensively study the interface between nanoparticles and nucleic acids. It sets out to produce a novel ultrasensitive high-performance biosensing platform that will combine luminescent nanoparticles with microfluidics in a digital assay. This portable platform will detect biological fingerprints, or microRNAs, at a single-molecule level, delivering unprecedented levels of sensitivity and specificity. The multiplexed platform has the potential to benefit the biomedical research of microRNAs and opens up a genuine commercialisation potential for portable biosensing of nucleic acids.Read moreRead less
Interrogating protein hydration by terahertz time-domain spectroscopy. Interrogating protein hydration by terahertz time-domain spectroscopy. This project aims to develop advanced terahertz time-domain spectroscopy (THz-TDS) techniques to understand how a protein’s interaction with excipients in solution can alter the hydration layers around them and how this affects properties such as viscosity and stability. THz-TDS can detect overlapping extended hydration layers around proteins, revealing ne ....Interrogating protein hydration by terahertz time-domain spectroscopy. Interrogating protein hydration by terahertz time-domain spectroscopy. This project aims to develop advanced terahertz time-domain spectroscopy (THz-TDS) techniques to understand how a protein’s interaction with excipients in solution can alter the hydration layers around them and how this affects properties such as viscosity and stability. THz-TDS can detect overlapping extended hydration layers around proteins, revealing new knowledge in protein-protein interactions and protein behaviour in an aqueous environment. The intended outcome is to use THz-TDS to better understand how proteins such as monoclonal antibodies interact in high concentration solutions, and in doing so make better medicines.Read moreRead less