High specificity nanosensors for glycobiology . This project aims to develop high specificity glycosensors for identifying and characterising carbohydrates. These glycosensors are expected to generate detailed information on carbohydrate stereochemical structure and how this controls protein-carbohydrate binding and other interactions fundamental to biochemical processes. This innovative nanotechnology aims to deliver a new capability for understanding cellular recognition and antigen binding me ....High specificity nanosensors for glycobiology . This project aims to develop high specificity glycosensors for identifying and characterising carbohydrates. These glycosensors are expected to generate detailed information on carbohydrate stereochemical structure and how this controls protein-carbohydrate binding and other interactions fundamental to biochemical processes. This innovative nanotechnology aims to deliver a new capability for understanding cellular recognition and antigen binding mechanisms. The expected outcomes are new tools for glycobiology and research into carbohydrate structure-function relationships, strengthening Australia’s global reputation in nanosensors with an incisive analytical technology for biomedical sciences and the many industries utilising carbohydrates.Read moreRead less
Homogenous Antibody-Metal Conjugates For Immuno-Mass Spectrometry Imaging. This project aims to use bespoke metal labels and high-resolution mass spectrometry imaging to address current shortcomings in approaches that visualise and measure proteins in cells and tissue. It expects to substantially increase the utility of immuno-mass spectrometry imaging technology to analyses that are refractory to current techniques and workflows. Expected outcomes include metal probes that facilitate the spatia ....Homogenous Antibody-Metal Conjugates For Immuno-Mass Spectrometry Imaging. This project aims to use bespoke metal labels and high-resolution mass spectrometry imaging to address current shortcomings in approaches that visualise and measure proteins in cells and tissue. It expects to substantially increase the utility of immuno-mass spectrometry imaging technology to analyses that are refractory to current techniques and workflows. Expected outcomes include metal probes that facilitate the spatial quantification of multiple biomolecules on a single histological section, providing significant benefits to bioscience laboratories that require complex workflows to visualise and obtain quantitative data on the expression of biomolecules.Read moreRead less
Unlocking the potential of poly(ionic liquids) for electrochemical sensing. This project aims to create new science that will enable the development of low-cost, miniaturised electrochemical sensors based on poly-ionic liquids. The chemistry of the materials will be tuned to selectively detect hazardous pollutants to enable trace concentration detection at analytically relevant levels. Fundamental behaviour of gases and solid contaminants dissolved in poly-ionic liquid/ionic liquid membranes wil ....Unlocking the potential of poly(ionic liquids) for electrochemical sensing. This project aims to create new science that will enable the development of low-cost, miniaturised electrochemical sensors based on poly-ionic liquids. The chemistry of the materials will be tuned to selectively detect hazardous pollutants to enable trace concentration detection at analytically relevant levels. Fundamental behaviour of gases and solid contaminants dissolved in poly-ionic liquid/ionic liquid membranes will be uncovered, and their performance for sensing in real environments will be examined. It is expected that these advances will transform detection methods by taking sensing out of the lab and in to the hands of the everyday person, giving rapid and accurate knowledge about the concentration of hazards in the environment.Read moreRead less