New Polymers for Cellulose-based Bioplastics. We will design new cellulose derivatives by combining carefully engineered synthetic polymers to cellulose. We will explore the fundamental science underpinning the manufacture of these bioplastics, and apply the concept to the design of two new materials, with (super)hydrophobic and antibacterial properties. These materials have the potential to replace synthetic plastics, which comprise one of the major outputs of the chemical industry worldwide. P ....New Polymers for Cellulose-based Bioplastics. We will design new cellulose derivatives by combining carefully engineered synthetic polymers to cellulose. We will explore the fundamental science underpinning the manufacture of these bioplastics, and apply the concept to the design of two new materials, with (super)hydrophobic and antibacterial properties. These materials have the potential to replace synthetic plastics, which comprise one of the major outputs of the chemical industry worldwide. Plastic is present everywhere in human life, but its manufacture and disposal have a strong negative impact on the environment; the new materials manufactured in this project are viable alternatives to plastics, and are sustainable from a production and disposal point of view.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100096
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
A unique soft matter high-performance scanning probe microscopy (HP-SPM) facility. Soft matter research touches every aspect of our lives as it covers materials from the range of plastics found in cars, television sets and other mass-manufactured products, to new medical materials for tissue engineering and sensors. The proposed facility will enable Australia's leading scientists in this area to understand better how soft matter, including both biological and new advanced soft materials, behave ....A unique soft matter high-performance scanning probe microscopy (HP-SPM) facility. Soft matter research touches every aspect of our lives as it covers materials from the range of plastics found in cars, television sets and other mass-manufactured products, to new medical materials for tissue engineering and sensors. The proposed facility will enable Australia's leading scientists in this area to understand better how soft matter, including both biological and new advanced soft materials, behaves on the nano-scale level. This will put Australian researchers and engineers in a leading position for developing new treatments against cancer and other diseases, as well as harnessing the power of biology for application in areas such as waste treatment and energy production.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100142
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
An integrated liquid chromatography mass spectrometry nuclear magnetic resonance (LC-MS-NMR) facility for applications in proteomics and organic chemistry. This application completes the requested liquid chromatography mass spectrometry nuclear magnetic resonance (LCMS-NMR) facility and will allow the training of over 150 researchers, significantly enhancing their research productivity and translation of outcomes in areas of national importance. New breakthroughs in drug development, smart mate ....An integrated liquid chromatography mass spectrometry nuclear magnetic resonance (LC-MS-NMR) facility for applications in proteomics and organic chemistry. This application completes the requested liquid chromatography mass spectrometry nuclear magnetic resonance (LCMS-NMR) facility and will allow the training of over 150 researchers, significantly enhancing their research productivity and translation of outcomes in areas of national importance. New breakthroughs in drug development, smart materials, organic electronic materials and biomedical research require routine access to cutting edge technology. The LCMS-NMR augments the capabilities of our research teams at the forefront of these efforts. These include understanding the impact of the environment on plant and animal development, pest animal control, development of new biotechnology tools, new drugs and new methods for the detection of narcotics and explosives.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668374
Funder
Australian Research Council
Funding Amount
$470,000.00
Summary
State-of-the-art NMR Facilities. This proposal will significantly enhance the NMR research capability and capacities at UoW and ANU. These schools have internationally recognised strengths in fundamentals of synthetic organic chemistry, therapeutic drug design and synthesis, protein chemistry and structural biology. This equipment will enhance the productivity of these researchers, increase their collaborative and scientific outputs and allow for training of students in the latest technologies ....State-of-the-art NMR Facilities. This proposal will significantly enhance the NMR research capability and capacities at UoW and ANU. These schools have internationally recognised strengths in fundamentals of synthetic organic chemistry, therapeutic drug design and synthesis, protein chemistry and structural biology. This equipment will enhance the productivity of these researchers, increase their collaborative and scientific outputs and allow for training of students in the latest technologies and importantly, contribute to Australia's development as a knowledge-based economy.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882576
Funder
Australian Research Council
Funding Amount
$588,000.00
Summary
Polymer Characterization Facility (PCF). Future development of macromolecular and biotechnologies have the potential to revolutionize everyday life. Current applications include plastics for engineering, diagnostic devices for biochemical analysis, polymer therapeutics for drug delivery and prosthesis with specific functions. The proposed facility will provide the analytical tools required to probe and develop advanced materials with application in medicine, agriculture, composites, cosmetics, ....Polymer Characterization Facility (PCF). Future development of macromolecular and biotechnologies have the potential to revolutionize everyday life. Current applications include plastics for engineering, diagnostic devices for biochemical analysis, polymer therapeutics for drug delivery and prosthesis with specific functions. The proposed facility will provide the analytical tools required to probe and develop advanced materials with application in medicine, agriculture, composites, cosmetics, communications and electronics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0237664
Funder
Australian Research Council
Funding Amount
$900,000.00
Summary
High Resolution Mass Spectrometer for (MS)n Chemical Characterisation. A Fourier transform ion cyclotron resonance ("FT-ICR") mass spectrometer equipped with electrospray ionisation (ESI) plus a "benchtop" matrix assisted laser desorption ionisation time of flight (MALDI-TOF) mass spectrometer are required to support the research of ca 28 research groups, including 44 postdoctoral fellows, and 138 honours and postgraduate students. By means of its high resolution and (MS)n capabilities, the FT- ....High Resolution Mass Spectrometer for (MS)n Chemical Characterisation. A Fourier transform ion cyclotron resonance ("FT-ICR") mass spectrometer equipped with electrospray ionisation (ESI) plus a "benchtop" matrix assisted laser desorption ionisation time of flight (MALDI-TOF) mass spectrometer are required to support the research of ca 28 research groups, including 44 postdoctoral fellows, and 138 honours and postgraduate students. By means of its high resolution and (MS)n capabilities, the FT-ICR-MS will provide key structural information on a wide range of synthetic and natural chemical substances, including sequence (e.g. peptides) and fragmentation patterns, while the MALDI-TOF instrument will be used primarily for high through-put proteomic analyses.Read moreRead less
Preparation of Photo-Affinity Molecular Probes for the Identification of Gibberellin Receptors. Bioactive gibberellins affect numerous processes during plant growth and development, including seed germination, leaf expansion, stem elongation, flowering and fruit development. However, only very limited information is available regarding their mode of action at the molecular level. The central aim of the project is to prepare a family of photo-affinity molecular probes based on the gibberellin m ....Preparation of Photo-Affinity Molecular Probes for the Identification of Gibberellin Receptors. Bioactive gibberellins affect numerous processes during plant growth and development, including seed germination, leaf expansion, stem elongation, flowering and fruit development. However, only very limited information is available regarding their mode of action at the molecular level. The central aim of the project is to prepare a family of photo-affinity molecular probes based on the gibberellin molecule that will be designed to provide critical information on the location and structure of gibberellin receptors. Screening of the probes for potential effectiveness will be determined initially by the measurement of alpha-amylase produced in a standard barley aleurone assay.Read moreRead less
Surface Forces in Aqueous Electrolytes. This project studies the force between two nearby colloidal particles or macromolecules in aqueous electrolyte solutions. Although such forces control the approach and binding of particles in electrolytes and hence have large practical significance they are poorly known. In recent work I established a rigorous scheme for calculation of the electrostatic contribution to the force and proved its feasibility. In order to realise practical applications, such a ....Surface Forces in Aqueous Electrolytes. This project studies the force between two nearby colloidal particles or macromolecules in aqueous electrolyte solutions. Although such forces control the approach and binding of particles in electrolytes and hence have large practical significance they are poorly known. In recent work I established a rigorous scheme for calculation of the electrostatic contribution to the force and proved its feasibility. In order to realise practical applications, such as in drug design, we must know the mean force between an ion and a surface or functional surface group. Here I propose to perform the required simulations and explore the analytical simplifications.Read moreRead less