Vortex fluidic mediated chemical transformations. This project aims to develop a continuous flow vortex fluidic device (VFD) for chemical and biochemical transformations. Vortex fluidic devices should lead to cleaner and faster ways of preparing complex molecules. Depending on the VFD’s operating parameters, including applying field effects such as Faraday waves, plasmas and light sources, reactions could have higher yields and selectivity than traditional batch processing. This will be translat ....Vortex fluidic mediated chemical transformations. This project aims to develop a continuous flow vortex fluidic device (VFD) for chemical and biochemical transformations. Vortex fluidic devices should lead to cleaner and faster ways of preparing complex molecules. Depending on the VFD’s operating parameters, including applying field effects such as Faraday waves, plasmas and light sources, reactions could have higher yields and selectivity than traditional batch processing. This will be translated into molecular assembly line syntheses in a single unit or a series. Such syntheses should provide a versatile toolbox for molecular transformations, under continuous flow conditions where scalability is addressed upfront. This will be attractive to industry and minimise effects on the environment.Read moreRead less
Modular Vortex Fluidic Mediated Molecular Transformations. The project aims to develop the use of electric and magnetic fields to control chemical and biochemical reactions in high shear thin films under readily scalable continuous flow conditions to then be able to precisely build complex functional molecules. Depending on the orientation, strength and frequency of external electric and magnetic fields, and novel shear stress induced electric fields in solution, rates of reactions can be enhanc ....Modular Vortex Fluidic Mediated Molecular Transformations. The project aims to develop the use of electric and magnetic fields to control chemical and biochemical reactions in high shear thin films under readily scalable continuous flow conditions to then be able to precisely build complex functional molecules. Depending on the orientation, strength and frequency of external electric and magnetic fields, and novel shear stress induced electric fields in solution, rates of reactions can be enhanced, with higher yields and tunable selectivity, and reduced waste and energy usage, which is not possible using traditional batch processing. This will be translated into molecular assembly line processing and the development of a new synthetic toolbox, with applications in preparing pharmaceuticals.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100192
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
Deep Protein Sequencing, Structure and Quantification Facility. This project aims to establish state-of-the-art complementary mass spectrometers to help research into molecular structure and interactions, post-translational modifications, compound stability and availability within complex biological samples. The facility’s complementary mass spectrometers combine high specificity with high sensitivity and ultrafast scanning, and are expected to rapidly discover, identify and characterise biomole ....Deep Protein Sequencing, Structure and Quantification Facility. This project aims to establish state-of-the-art complementary mass spectrometers to help research into molecular structure and interactions, post-translational modifications, compound stability and availability within complex biological samples. The facility’s complementary mass spectrometers combine high specificity with high sensitivity and ultrafast scanning, and are expected to rapidly discover, identify and characterise biomolecules including peptides, proteins and small molecules. The discovery of unknown compounds is expected to improve fundamental understanding of molecular structure and function, provide opportunities for new bio-industries in health and the environment, and generate commercial opportunities through spin-off companies, patents and licensing.Read moreRead less
ARC Centre of Excellence for Innovations in Peptide and Protein Science. The ARC Centre of Excellence for Innovations in Peptide and Protein Science (CIPPS) strives to build a critical understanding of peptides and proteins in order to unleash the potential of these biomolecules for human benefit. We will discover nature’s untapped reservoir of peptides and proteins, decode their structures and functions, and
develop enhanced synthetic technologies to address biology’s next grand challenge—the d ....ARC Centre of Excellence for Innovations in Peptide and Protein Science. The ARC Centre of Excellence for Innovations in Peptide and Protein Science (CIPPS) strives to build a critical understanding of peptides and proteins in order to unleash the potential of these biomolecules for human benefit. We will discover nature’s untapped reservoir of peptides and proteins, decode their structures and functions, and
develop enhanced synthetic technologies to address biology’s next grand challenge—the design of peptides and proteins for targeted scientific, agricultural, biotechnology, animal health and pharmaceutical applications. CIPPS will assemble leading researchers from diverse disciplines to create a sustainable national entity that will drive new Australian industries and train next generation researchers.Read moreRead less