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
Putting an end to hospital-borne infection with micronebulisation of lung-safe disinfectants. Dangerous infections are unfortunately common in hospitals, established and retransmitted via surfaces and handheld items, representing a leading contributor to death worldwide, and potentially a far more serious problem to come as antimicrobial resistance worsens. The project aims to exploit a newly discovered and unique low power nebulisation technology to nebulise a strongly antiviral, antibacterial ....Putting an end to hospital-borne infection with micronebulisation of lung-safe disinfectants. Dangerous infections are unfortunately common in hospitals, established and retransmitted via surfaces and handheld items, representing a leading contributor to death worldwide, and potentially a far more serious problem to come as antimicrobial resistance worsens. The project aims to exploit a newly discovered and unique low power nebulisation technology to nebulise a strongly antiviral, antibacterial and antifungal agent, triethylene glycol that is too viscous to do so by any other known method. Through refinement and engineering of the technology via this project, handheld and room-based continuously operating nebulisers will produce continuous microdroplet mists of these pathogen-killing agents that deposit on surfaces throughout a hospital.Read moreRead less
Bridging the gap between global mechanics and regional imaging in the lungs. The detailed mechanics of breathing are not well understood, due to a lack of regional lung measurement techniques. This project aims to develop a powerful analysis tool to image in vivo mechanical properties of the lungs. The expected outcome of this project is a novel platform for investigation and understanding of lung function, enabling information previously only available for the whole lung to be calculated for lo ....Bridging the gap between global mechanics and regional imaging in the lungs. The detailed mechanics of breathing are not well understood, due to a lack of regional lung measurement techniques. This project aims to develop a powerful analysis tool to image in vivo mechanical properties of the lungs. The expected outcome of this project is a novel platform for investigation and understanding of lung function, enabling information previously only available for the whole lung to be calculated for local lung regions within the body. The image analysis methods developed are intended to enable respiratory researchers to investigate lung function in unprecedented detail, leading to new insights into the workings of this complicated and vital organ. Read moreRead less
Hybrid imaging/modelling: A new paradigm for understanding the lung. Our lungs are essential to sustain our lives, yet the details of lung biomechanics are barely understood because the available tools, imaging, modelling and simulation have significant limitations. Imaging is largely limited to providing structural information; simulation is severely restricted by a lack of validation; and inverse modelling is critically hampered by a lack of spatially resolved inputs. The project’s multidiscip ....Hybrid imaging/modelling: A new paradigm for understanding the lung. Our lungs are essential to sustain our lives, yet the details of lung biomechanics are barely understood because the available tools, imaging, modelling and simulation have significant limitations. Imaging is largely limited to providing structural information; simulation is severely restricted by a lack of validation; and inverse modelling is critically hampered by a lack of spatially resolved inputs. The project’s multidisciplinary team is uniquely positioned to explore these problems through the hybridisation of world-leading functional lung imaging technology with state-of-the-art modelling. This project aims to provide, perhaps for the first time, the capacity to see details with the resolution of imaging, richness of modelling and reliability of the finest measurements.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101133
Funder
Australian Research Council
Funding Amount
$358,551.00
Summary
Linking structure and function: a new approach for understanding the lung. This project aims to develop a powerful analysis tool to measure gas transport and mixing within lungs. This project will study the mechanical workings of the lungs, using an innovative approach for analysis of lung images. The expected outcome of this project is a novel platform for investigation and understanding of lung function. It is anticipated that application of the project outcomes to medical challenges in the lo ....Linking structure and function: a new approach for understanding the lung. This project aims to develop a powerful analysis tool to measure gas transport and mixing within lungs. This project will study the mechanical workings of the lungs, using an innovative approach for analysis of lung images. The expected outcome of this project is a novel platform for investigation and understanding of lung function. It is anticipated that application of the project outcomes to medical challenges in the long-term will lead to improved diagnostics and treatments for lung diseases.Read moreRead less
Understanding surface acoustic wave atomisation for pulmonary delivery of drug aerosols in personalised medicine. Delivering drugs via the lung is hampered by development costs and inadequate technology. This project will provide an understanding of atomisation in our unique respire system, enabling not only the delivery of new vaccines and drugs but also the rapid and cost effective development of new disease treatments personalised to the patient.
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
Industrial Transformation Research Hubs - Grant ID: IH150100028
Funder
Australian Research Council
Funding Amount
$3,708,510.00
Summary
ARC Research Hub for Integrated Device for End-user Analysis at Low-levels. ARC Research Hub for Integrated Device for End-user Analysis at Low-levels. This hub aims to improve detection of biological materials by building a portable device for rapid, time-critical detection of low-abundance molecular and cellular analytes. It is expected that the resulting technologies would be used at medical points of care, ordinary workplaces and centres of activity to test for tiny levels of targeted molecu ....ARC Research Hub for Integrated Device for End-user Analysis at Low-levels. ARC Research Hub for Integrated Device for End-user Analysis at Low-levels. This hub aims to improve detection of biological materials by building a portable device for rapid, time-critical detection of low-abundance molecular and cellular analytes. It is expected that the resulting technologies would be used at medical points of care, ordinary workplaces and centres of activity to test for tiny levels of targeted molecules. The initial focus would be early diagnosis of disease and point-of-care drug testing for humans and animals, but the technology platform could be used to sample food and environmental toxins. The hub expects these disruptive technologies will make Australian biotechnology, diagnostics, veterinary, agribusiness and manufacturing firms globally competitive.Read moreRead less
Acoustic single cell traps: Understanding the woods by examining the trees. This project aims to define the underlying physics behind the manipulation of individual cells in a microfluidic chip using acoustic forces. The technology investigated would offer biomedical researchers a unique capability: that of tracking individual cell responses. It is known for example that drug resistance and latency emerge from small sub-populations of cells, so crucial information is lost when cells are studied ....Acoustic single cell traps: Understanding the woods by examining the trees. This project aims to define the underlying physics behind the manipulation of individual cells in a microfluidic chip using acoustic forces. The technology investigated would offer biomedical researchers a unique capability: that of tracking individual cell responses. It is known for example that drug resistance and latency emerge from small sub-populations of cells, so crucial information is lost when cells are studied at a population level. To trap single cells, the acoustic wavelength excited must be reduced to the order of a cell diameter. By enabling the analysis of different responses due to subtle cell difference, information pertinent to infection pathways and drug response could be gathered.Read moreRead less
Biophysics-informed deep learning framework for magnetic resonance imaging. This project aims to bring about a paradigm shift from the conventional non-quantitative magnetic resonance imaging to ultra-fast, quantitative, and artefact free imaging. This project integrates biophysics and artificial intelligence, and it is expected to bring new knowledge in both fields. The expected outcomes of this project include next generation magnetic resonance imaging methods with a fundamental shift in the ....Biophysics-informed deep learning framework for magnetic resonance imaging. This project aims to bring about a paradigm shift from the conventional non-quantitative magnetic resonance imaging to ultra-fast, quantitative, and artefact free imaging. This project integrates biophysics and artificial intelligence, and it is expected to bring new knowledge in both fields. The expected outcomes of this project include next generation magnetic resonance imaging methods with a fundamental shift in the approach to image artefacts and image quantification. This project is expected to advance both single subject and population level biomedical imaging with greater accuracy and cost-effectiveness. This project also promotes explainable and generalisable artificial intelligence in medical imaging.Read moreRead less