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Sustainable surfactants from Australian oilseeds. This project aims to develop a new generation of sustainable surfactants utilising Australian-grown oilseed feedstocks. These molecules are designed to replace current materials made from petroleum and palm oil, to fulfil a key role as the next generation of bio-resourced detergents and emulsifiers. The work seek to develop a library of new molecules to better understand the relationship between molecular structure and performance, through cuttin ....Sustainable surfactants from Australian oilseeds. This project aims to develop a new generation of sustainable surfactants utilising Australian-grown oilseed feedstocks. These molecules are designed to replace current materials made from petroleum and palm oil, to fulfil a key role as the next generation of bio-resourced detergents and emulsifiers. The work seek to develop a library of new molecules to better understand the relationship between molecular structure and performance, through cutting edge lab testing and utilising national infrastructure, guiding the use of new components in formulating new products. It is anticipated that the surfactants generated will find uses in household cleaning and personal care products, providing high value chemicals from key Australian crops.Read moreRead less
Electrochemical sensors as early alert screening tools for water quality assessment. This project will impact on water safety assessment and provide better management tools for water pollutant control. It will address a real need to develop on-line detection technologies for application in the water industry and will demonstrate the potential broad applicability of this technology to a wide range of analytes of concern.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100087
Funder
Australian Research Council
Funding Amount
$410,000.00
Summary
Advanced Macromolecular Materials Characterisation Facility (AMMCF). Advanced macromolecular materials characterisation facility: The facility will allow precise characterisation of (bio)macromolecular materials, from chemical structures and composition as a function of size or biodistribution, to film thickness in multi-layer materials, to material hydrophobicity and permeability. Novel information derived from these state-of-the-art instruments is highly valuable in understanding structure-pro ....Advanced Macromolecular Materials Characterisation Facility (AMMCF). Advanced macromolecular materials characterisation facility: The facility will allow precise characterisation of (bio)macromolecular materials, from chemical structures and composition as a function of size or biodistribution, to film thickness in multi-layer materials, to material hydrophobicity and permeability. Novel information derived from these state-of-the-art instruments is highly valuable in understanding structure-property relationships, which are crucial for the development of the next generation of advanced materials with applications in electronics, optics, sensors, membranes, nanocoatings, biomaterials and polymer therapeutics. This facility underpins the efforts of the participating institutes in increasing the quality and quantity of research outcomes.Read moreRead less
Multi-drug dry powder inhalation systems for the effective treatment of chronic obstructive pulmonary disease. Utilising a combination of particle engineering, computer modeling, rapid prototyping and high-speed 3D imaging this project will develop a novel approach to treat chronic obstructive pulmonary disease. A multi-drug particle system whose surface is independent of the drugs incorporated will be optimised in a novel high efficiency inhalation device.
Surface modification of semiconducting organic charge transfer complexes with metal nanoparticles to create a new class of multifunctional materials. This project aims to deliver a facile and cheap method to produce a class of nanostructured composite materials to be used in applications which will have environmental and social benefits such as photocatalyst development for water purification, biosensing and the creation of antibacterial fabrics to prevent the spread of infection.
Characterisation of nanobubbles. Surprisingly, nano-sized bubbles have recently been found to exist in aqueous solutions. Classical theory tells us they should rapidly dissolve, yet they are stable for several days, a phenomenon which has only recently been explained. Despite this, nanobubbles are already used in cleaning processes and appear to have significant health benefits. They are being investigated in treatments for asthma and neurodegenerative diseases. In collaboration with a pharmaceu ....Characterisation of nanobubbles. Surprisingly, nano-sized bubbles have recently been found to exist in aqueous solutions. Classical theory tells us they should rapidly dissolve, yet they are stable for several days, a phenomenon which has only recently been explained. Despite this, nanobubbles are already used in cleaning processes and appear to have significant health benefits. They are being investigated in treatments for asthma and neurodegenerative diseases. In collaboration with a pharmaceutical company, the best means to produce and characterise nanobubbles will be investigated, as well as the conditions governing their stability. The project also aims to determine how the nanobubbles interact with surfaces in order to better control their properties and achieve a better understanding of these bubbles.Read moreRead less
Ionic lquids for scalable production of monolayer two-dimensional materials. This project aims to produce stable solutions of high quality, two-dimensional materials (2DMs, exemplified by graphene) in ionic liquids by spontaneous exfoliation. The project will develop processes for producing significant quantities of high quality 2DMs for use in a diverse range of technologies, and train graduate students in experimental and computational chemistry techniques.
Lab-on-a-chip mass spectrometry tools for testing illicit drugs. This project aims to develop fit-for-purpose mass spectrometry tools for roadside and workplace testing of illicit drugs. The technology will be based on nanostructured semiconductor chips that are surface-functionalised to enable molecular capture without extensive sample processing and subsequent detection by a novel combination of techniques. The technology is expected to be applicable to saliva, sweat and urine samples.
Magnetic liquid marbles: a new droplet manipulation technique for channel-free microfluidics. The project will explore the feasibility of developing a new droplet-manipulation strategy by using magnetically responsive liquid marbles capable of hosting various liquid droplets. It will significantly advance the development of a new generation of microfluidic devices: magnetic field-actuated channel-free droplet microfluidics.
Discovery Early Career Researcher Award - Grant ID: DE160101281
Funder
Australian Research Council
Funding Amount
$300,036.00
Summary
Biomimetic lipidic self-assembly materials for protein encapsulation. This project intends to improve understanding of the interactions between proteins and lipidic materials to guide the development of new biomaterials. Proteins and peptides play an increasingly important role as drugs, vaccines and diagnostics. However, these fragile, often large, macromolecules come with challenges for drug delivery. Lipid-based materials are ideal matrices for encapsulation of functionally active proteins. T ....Biomimetic lipidic self-assembly materials for protein encapsulation. This project intends to improve understanding of the interactions between proteins and lipidic materials to guide the development of new biomaterials. Proteins and peptides play an increasingly important role as drugs, vaccines and diagnostics. However, these fragile, often large, macromolecules come with challenges for drug delivery. Lipid-based materials are ideal matrices for encapsulation of functionally active proteins. They also offer advantages as drug delivery vehicles including controlled release properties. The combination of strategies creates an ideal delivery system for protein therapeutics. The project aims to characterise the physicochemical interactions between the protein and the lipid matrix. This may guide the development of novel lipidic materials for the encapsulation and controlled release of protein therapeutics.Read moreRead less