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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100043
Funder
Australian Research Council
Funding Amount
$389,000.00
Summary
Rapid Molecular (Bio)material Imaging by Infrared and Raman Microscopies. This project aims to undertake fast probe-free biochemical/chemical imaging of heterogeneity within cells and materials surfaces with new infrared and Raman imaging. It will generate new fundamental knowledge on: cell heterogeneity and dynamic processes; technologies for optimising cell printing; understanding toxicity of microplastics; and protocols for measuring materials of technological relevance. Expected outcomes inc ....Rapid Molecular (Bio)material Imaging by Infrared and Raman Microscopies. This project aims to undertake fast probe-free biochemical/chemical imaging of heterogeneity within cells and materials surfaces with new infrared and Raman imaging. It will generate new fundamental knowledge on: cell heterogeneity and dynamic processes; technologies for optimising cell printing; understanding toxicity of microplastics; and protocols for measuring materials of technological relevance. Expected outcomes include: interdisciplinary collaborations in new protocols for in-vitro drug development; cell printing technologies; environmental impacts of microplastics; and materials design. Expected benefits include innovative approaches to early stage drug design; improved environmental controls and advances in innovative materials.Read moreRead less