Nitroxide-containing scaffolds for controlling biofilm-related infections. Bacterial biofilms are a major problem in healthcare systems around the world as they cause persistent and chronic infections, including those associated with medical implants and cystic fibrosis. This project aims to develop new chemical approaches to deliver nitroxides at surface interfaces and in microparticles to facilitate long term control over biofilm growth. It is expected that these functionalised scaffolds will ....Nitroxide-containing scaffolds for controlling biofilm-related infections. Bacterial biofilms are a major problem in healthcare systems around the world as they cause persistent and chronic infections, including those associated with medical implants and cystic fibrosis. This project aims to develop new chemical approaches to deliver nitroxides at surface interfaces and in microparticles to facilitate long term control over biofilm growth. It is expected that these functionalised scaffolds will represent a breakthrough in the field and will have a profound impact by reducing infection rates associated with medical devices and improving airway clearance in cystic fibrosis patients.Read moreRead less
Radio-magnetic nanoparticles as bimodal positron emission tomography/magnetic resonance imaging contrast agents for dendritic cell tracking. Biomedical imaging is limited by a lack of commercial dual-mode contrast agents, which may be simultaneously used for magnetic resonance (MR) and positron emission tomography (PET) imaging. This project will develop a nanotechnology-based biocompatible dual-mode contrast agent for simultaneous PET and MR imaging, reducing associated side effects.
Discovery Early Career Researcher Award - Grant ID: DE180100294
Funder
Australian Research Council
Funding Amount
$368,446.00
Summary
Topochemical conversion of layers of graphene into diamond-like thin films. This project aims to experimentally convert layers of graphene into diamond-like thin films via novel chemical hydrogenation and fluorination approaches. Unconventional diamond-like thin films that possess remarkable physicochemical properties will be produced to trigger significant theoretical and technological interests in nano-carbon research. The project expects to impact the fundamental understanding of this new cla ....Topochemical conversion of layers of graphene into diamond-like thin films. This project aims to experimentally convert layers of graphene into diamond-like thin films via novel chemical hydrogenation and fluorination approaches. Unconventional diamond-like thin films that possess remarkable physicochemical properties will be produced to trigger significant theoretical and technological interests in nano-carbon research. The project expects to impact the fundamental understanding of this new class of graphene-derived materials whilst driving cutting-edge technological advances in electrochemical applications, membrane technologies and quantum computing.Read moreRead less
Advanced bio-inspired polymer assembly: tools for diagnostics, imaging and therapies. ‘Smart’ polymeric materials have the potential to make a significant impact in areas such as healthcare. However, to do this effectively the materials will need to respond intelligently to biological signals. This project will involve the synthesis and application of ‘smart’ polymer films and particles, which mimic biological behaviour.
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
High performance inks for solution based organic light emitting diodes manufacturing. This project aims to introduce an advanced solution processing and printing technique for organic light emitting diode (OLED) fabrication based on a set of innovative macromolecular chemistries. These proceed either photochemically or thermally, exploiting precision macromolecular designs of the polymer precursor materials, which contain advanced emitter systems developed by Cynora. Solution fabrication of OLED ....High performance inks for solution based organic light emitting diodes manufacturing. This project aims to introduce an advanced solution processing and printing technique for organic light emitting diode (OLED) fabrication based on a set of innovative macromolecular chemistries. These proceed either photochemically or thermally, exploiting precision macromolecular designs of the polymer precursor materials, which contain advanced emitter systems developed by Cynora. Solution fabrication of OLED is a challenging, yet ultimately powerful, process with key advantages over current vacuum processing systems, especially with regard to production flexibility, cost and OLED size. The project will provide a functioning technology platform for solution OLED fabrication.Read moreRead less
Smart magnetic resonance imaging (MRI) contrast agents: from early detection to assessment of drug delivery mechanisms. 'Smart' contrast agents will be developed for enhancing the performance of magnetic resonance imaging (MRI) of diseases such as cancer by designing them to be triggered by biochemical markers for disease. This has the potential to aid in early detection which can lead to lower mortality rates and consequently a lower burden on the health system.
Traceable theranostics: tools for visualising drug delivery and therapeutic benefit in vivo. Forty-three thousand people died from cancer in Australia in 2010. The aim of this project is to advance the concept of 'personalised-therapy' through the development of novel imaging devices based on polymers that can 'switch-on' and deliver drugs in specific tissues, allowing more sensitive and earlier detection and monitoring of diseases and therapies.
Force-mediated dynamic chemistry in hydrogels. This project aims to develop a new class of biomimetic material, where applied force modulates the chemistry and mechanics by incorporating mechanochemical responsive linkages in hydrogel networks. This work intends to generate new knowledge in the chemistry and mechanical properties of soft materials using an interdisciplinary approach involving synthesis, computational modelling, and mechanical analysis. Expected outcomes include novel hydrogel ma ....Force-mediated dynamic chemistry in hydrogels. This project aims to develop a new class of biomimetic material, where applied force modulates the chemistry and mechanics by incorporating mechanochemical responsive linkages in hydrogel networks. This work intends to generate new knowledge in the chemistry and mechanical properties of soft materials using an interdisciplinary approach involving synthesis, computational modelling, and mechanical analysis. Expected outcomes include novel hydrogel materials that are mechanochemically active, tough, and fatigue resistant, along with design criteria for force-activated molecule immobilisation and release expected to provide significant benefit forbiomedical applications, additive manufacturing, soft robotics and flexible electronics.Read moreRead less
Nanoarchitectured multifunctional porous superparamagnetic nanoparticles. This project aims to develop a method for the direct detection of biomarkers based on a new class of highly porous superparamagnetic nanoparticles with peroxidase-like activity. The particles will be used as dispersible capture agents for isolating specific targets in biological samples, and electrocatalytic nanozymes for naked-eye evaluation and electrochemical detection. The project is expected to develop simple, low-cos ....Nanoarchitectured multifunctional porous superparamagnetic nanoparticles. This project aims to develop a method for the direct detection of biomarkers based on a new class of highly porous superparamagnetic nanoparticles with peroxidase-like activity. The particles will be used as dispersible capture agents for isolating specific targets in biological samples, and electrocatalytic nanozymes for naked-eye evaluation and electrochemical detection. The project is expected to develop simple, low-cost, portable devices for the analysis of exosomes and exosomal miRNA in biological samples. The future development of this technology into diagnostic devices will improve patient outcomes by enabling earlier disease diagnosis and improved monitoring of treatment.Read moreRead less