An integrated nano-bioengineered chip for enhanced molecular evolution. This project aims to develop a novel molecular evolution platform technology for the rapid selection of high value target binding molecules from diverse molecular libraries using an electrically activated nanofluidic chip coated with target. Significant outcomes from the project is the controlled selection of target binding molecules that is not possible with current methods and improved understanding of nanoforce driven mol ....An integrated nano-bioengineered chip for enhanced molecular evolution. This project aims to develop a novel molecular evolution platform technology for the rapid selection of high value target binding molecules from diverse molecular libraries using an electrically activated nanofluidic chip coated with target. Significant outcomes from the project is the controlled selection of target binding molecules that is not possible with current methods and improved understanding of nanoforce driven molecular collisions on nano-bioengineered surfaces. This provides significant benefits, creating new knowledge in nanomaterials and advanced manufacturing of nanofabricated devices, creating commercial interest and positioning Australia at the forefront of molecular discovery technology, a highly valuable global market.
Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100092
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
X-ray induced photoacoustic nanoprobe: Break depth dependency of bioimaging. This project aims to develop a nanoprobe using an X-ray excited luminescence “nanolaser” as the local light source to activate coupled responsive photoacoustic sensors. In-situ imaging of specific biomarkers at the molecular level is key to understanding their roles in physiological and pathological processes, but current imaging techniques using fluorescent probes cannot detect biomarkers in deep tissues due to shallow ....X-ray induced photoacoustic nanoprobe: Break depth dependency of bioimaging. This project aims to develop a nanoprobe using an X-ray excited luminescence “nanolaser” as the local light source to activate coupled responsive photoacoustic sensors. In-situ imaging of specific biomarkers at the molecular level is key to understanding their roles in physiological and pathological processes, but current imaging techniques using fluorescent probes cannot detect biomarkers in deep tissues due to shallow light penetration. By capitalising on the tissue penetrating property of X-rays and acoustic waves and collecting acoustic waves as the read-out signal, real-time monitoring of biomarkers in deep tissues could be achieved, advancing detection technology for deep-tissue biomarkers.Read moreRead less
Integrated Nanoplatform for Multiomics Analysis of Cell-to-Cell Interaction. This project aims to develop an integrated nanoplatform for analysis of exosomes produced by host-pathogen interaction at the single cell level. This will be accomplished by engineering an innovative device involving plasmonic nanoparticles to probe exosomes molecular profiles over time. The intended outcome is a generic and robust platform for detailed molecular analysis of the consequences of cell-to-cell interactions ....Integrated Nanoplatform for Multiomics Analysis of Cell-to-Cell Interaction. This project aims to develop an integrated nanoplatform for analysis of exosomes produced by host-pathogen interaction at the single cell level. This will be accomplished by engineering an innovative device involving plasmonic nanoparticles to probe exosomes molecular profiles over time. The intended outcome is a generic and robust platform for detailed molecular analysis of the consequences of cell-to-cell interactions. Single cell scale will greatly improve detection accuracy for heterogeneous cell populations. Benefits will include new knowledge of cell-to-cell communication and intellectual property in manufacturing, which will foster collaborations across institutions and Australian industry by providing new technological solutions.Read moreRead less
Next-generation epigenetic analysis: direct reading of DNA methylation. This project aims to develop a new molecular tool to directly and dynamically read chemical modifications on genomic DNA (epigenetics) by utilizing advanced nanomaterials with the unique features of Raman spectroscopy. Epigenetics affects cellular processes and controls genetic programs by turning them “on” and “off" but there is currently no direct method to measure modifications on DNA. A new technology will be designed to ....Next-generation epigenetic analysis: direct reading of DNA methylation. This project aims to develop a new molecular tool to directly and dynamically read chemical modifications on genomic DNA (epigenetics) by utilizing advanced nanomaterials with the unique features of Raman spectroscopy. Epigenetics affects cellular processes and controls genetic programs by turning them “on” and “off" but there is currently no direct method to measure modifications on DNA. A new technology will be designed to avoid complicated procedures/chemistry for DNA epigenetic analysis providing a specific molecular fingerprint. The anticipated outcomes include a new technique and advanced knowledge in nanomaterials and DNA functions, thus strengthening the economic viability of Australian manufacturing and biotechnology sectors.Read moreRead less
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
On-fibre separation science with ambient ionisation mass spectrometry. This project aims to combine fibre-based electrofluidics and ambient ionisation mass spectrometry. Fibre-based electrophoresis is a separation technology which is cheaper, simpler and faster than pre-MS analyses. This project will use the fibre simultaneously as the ionisation platform for ambient mass spectrometry, combining the processes of separation and ionisation in a portable and flexible platform. The developed technol ....On-fibre separation science with ambient ionisation mass spectrometry. This project aims to combine fibre-based electrofluidics and ambient ionisation mass spectrometry. Fibre-based electrophoresis is a separation technology which is cheaper, simpler and faster than pre-MS analyses. This project will use the fibre simultaneously as the ionisation platform for ambient mass spectrometry, combining the processes of separation and ionisation in a portable and flexible platform. The developed technology is expected to provide new capability in bioanalysis, proteomics and rapid clinical diagnostics. Future benefits may include new commercial fibre based technologies which could be applied within industrial and clinical laboratories within the next ten years.Read moreRead less
Microfluidic Separation Science: Innovative Technology for Characterising Complex Chemical Systems. At present there is a need for fast and detailed chemical analysis of complex samples, such as those important to biomedical diagnostics and forensic science. Innovative technology will be developed here in order to reduce analysis time whilst maintaining the integrity of the chemical information contained within the sample. This step change in separation science will directly aid biomedical diagn ....Microfluidic Separation Science: Innovative Technology for Characterising Complex Chemical Systems. At present there is a need for fast and detailed chemical analysis of complex samples, such as those important to biomedical diagnostics and forensic science. Innovative technology will be developed here in order to reduce analysis time whilst maintaining the integrity of the chemical information contained within the sample. This step change in separation science will directly aid biomedical diagnostics, forensic sample determination and industrial process monitoring through decreased analysis time with an increase in the chemical information gained. By performing chemical separations on a microfluidic scale a reduction in both the cost of analysis and impact of solvent waste on the environment will be achieved.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100986
Funder
Australian Research Council
Funding Amount
$401,000.00
Summary
High-performance, portable ion-mobility surface-acoustic wave spectrometry. This project aims to develop a high-performance, cost-effective, palm-portable differential ion mobility spectrometer for universal chemical analysis that operates at atmospheric pressure and consumes minimal power. A significant problem in current analytical chemistry is the lack of rapid and cost-effective methods that can be used in the field for analysis of many different chemical species of environmental and biologi ....High-performance, portable ion-mobility surface-acoustic wave spectrometry. This project aims to develop a high-performance, cost-effective, palm-portable differential ion mobility spectrometer for universal chemical analysis that operates at atmospheric pressure and consumes minimal power. A significant problem in current analytical chemistry is the lack of rapid and cost-effective methods that can be used in the field for analysis of many different chemical species of environmental and biological importance. The project expects to enable the rapid and simultaneous separation and detection of many different ions from complex mixtures with high selectivity and sensitivity. The spectrometer can be implemented in the field for various applications such as atmospheric monitoring, disease diagnosis and chemical weapons detection.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101056
Funder
Australian Research Council
Funding Amount
$380,156.00
Summary
Rational Design of Plasmonic Nanoassemblies for Rapid and Multiplexed Point-of-Care Diagnosis by Surface-enhanced Raman Spectroscopy (SERS). The central aim of this project is to develop a novel technology/sensor platform for rapid, quantitative, multiplexed and highly sensitive point-of-care diagnostics using surface-enhanced Raman spectroscopy (SERS) as the read-out approach. Three-dimensional plasmonic superstructures as novel SERS labels will be synthesised and characterised at single-partic ....Rational Design of Plasmonic Nanoassemblies for Rapid and Multiplexed Point-of-Care Diagnosis by Surface-enhanced Raman Spectroscopy (SERS). The central aim of this project is to develop a novel technology/sensor platform for rapid, quantitative, multiplexed and highly sensitive point-of-care diagnostics using surface-enhanced Raman spectroscopy (SERS) as the read-out approach. Three-dimensional plasmonic superstructures as novel SERS labels will be synthesised and characterised at single-particle level and the choice of optimal SERS-active three-dimensional superstructures for use will be guided by empirical structure-activity correlations in combination with computer simulations. Tumour biomarkers for breast cancer will be employed as the model target for establishing the detection platform in a portable configuration for point-of-care diagnostics.Read moreRead less
Nanoscale liquid interfaces: properties and molecular sensitivity. Challenges facing society in health and environment need new molecular measurements that are accurate, sensitive and fast. By use of nanoscale oil-water junctions, the project will develop new chemical and biological sensors that hold great promise for solving molecular measurement problems, including the ability to detect single molecules.