Multimodal polymeric nanocarriers designed for the controlled and site specific delivery of nitric oxide. Nitric oxide (NO) plays a key role in the development of different diseases. The chronic deficiency of NO results in severe problems such as cardiovascular diseases, liver fibrosis, diabetes, cancer, Alzheimer’s diseases, etc. This project will describe a new method to deliver specifically nitric oxide using macromolecules.
Naturally derived photoinitiators for biocompatible 3D printing. This project aims to develop an environmentally-friendly approach to naturally derived photoinitiators which are applicable to 3D printing through low-energy, visible light-induced polymerisation, and explore their application in the fabrication of biocompatible polymeric materials. Traditional polymer manufacturing processes such as thermopolymerisation employ hazardous chemicals which present health and environmental risks. This ....Naturally derived photoinitiators for biocompatible 3D printing. This project aims to develop an environmentally-friendly approach to naturally derived photoinitiators which are applicable to 3D printing through low-energy, visible light-induced polymerisation, and explore their application in the fabrication of biocompatible polymeric materials. Traditional polymer manufacturing processes such as thermopolymerisation employ hazardous chemicals which present health and environmental risks. This project expects to expand fundamental scientific knowledge of photochemistry, polymer chemistry and biology through the development of a novel, economical, clean, commercially-relevant platform (3D printing) for the fabrication of polymeric materials.Read moreRead less
Design of multimodal polymeric nanoparticles as targeted carriers for the co-delivery of therapeutic molecules. This project will greatly enhance the tools available to oncologists by providing new treatment options, minimising side-effects to conventional chemotherapy approaches. In this project, the design of next generation of drug delivery will be developed using the most recent advances in materials sciences.
Dyes and Pigments as Building Blocks for Novel High Performance Organic Semiconductors. Natural dyes and pigments are well known for their bright colours, photochemical and thermal stability, and cheap cost. Recently, the necessity of high performing materials in the organic electronics has stimulated a renaissance of these historical molecules and their subsequent derivatives into new families of ?-conjugated building blocks used to construct new donor-acceptor semiconductors. The aim of this p ....Dyes and Pigments as Building Blocks for Novel High Performance Organic Semiconductors. Natural dyes and pigments are well known for their bright colours, photochemical and thermal stability, and cheap cost. Recently, the necessity of high performing materials in the organic electronics has stimulated a renaissance of these historical molecules and their subsequent derivatives into new families of ?-conjugated building blocks used to construct new donor-acceptor semiconductors. The aim of this project is to explore various novel dyes, pigments and their derivatives for constructing outstanding materials for future organic electronics.Read moreRead less
Atomic scale precision engineering of cell-material interfaces. This project aims to determine the molecular structure of the interface between novel peptide self-assemblies and cell membranes through x-ray diffraction and molecular simulation. The project will generate knowledge to enable atomic scale engineering of peptide nanomaterials, and exploitation of these materials to modulate cell responses. Expected outcomes include designed peptide nanostructures with specific chemical and physical ....Atomic scale precision engineering of cell-material interfaces. This project aims to determine the molecular structure of the interface between novel peptide self-assemblies and cell membranes through x-ray diffraction and molecular simulation. The project will generate knowledge to enable atomic scale engineering of peptide nanomaterials, and exploitation of these materials to modulate cell responses. Expected outcomes include designed peptide nanostructures with specific chemical and physical cues to promote sustainable growth of desired cells, whilst inhibiting undesirable responses. These outcomes should provide benefits in terms of a practical toolkit for tailoring structure and function of peptide nanostructures and open up a new era in molecular design of smart biomaterials. This easily scalable, new materials platform will contribute to emerging high-value manufacturing industries in Australia.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.
Regulation of DNA synthesis and host evasion by Lentivirus Capsids. This project aims to investigate how a type of virus, exemplified by HIV, can synthesise DNA in the cytoplasm of a host cell, without triggering the cell’s innate immunity when DNA is detected outside the nucleus. It expects to advance understanding of the role of the virus’ protein shell in regulating DNA synthesis during infection. The project outcomes should include enhanced capacity for fundamental virus and cell biology re ....Regulation of DNA synthesis and host evasion by Lentivirus Capsids. This project aims to investigate how a type of virus, exemplified by HIV, can synthesise DNA in the cytoplasm of a host cell, without triggering the cell’s innate immunity when DNA is detected outside the nucleus. It expects to advance understanding of the role of the virus’ protein shell in regulating DNA synthesis during infection. The project outcomes should include enhanced capacity for fundamental virus and cell biology research in Australia. The project anticipates contributing to new tools for delivering genes to cells, benefiting therapeutic and biotechnology applications.Read moreRead less
The control of archaeal cell structure by tubulin-family proteins. The objective of this project is to deliver new insights into the evolution and diversity of cell structure and function. Cell theory has been a cornerstone of biology for over 150 years. Yet how early cells developed into modern forms is still a mystery. The primitive and poorly understood third domain of life, Archaea, could hold clues. Recently, proteins were discovered in archaea that are related to the tubulin proteins of al ....The control of archaeal cell structure by tubulin-family proteins. The objective of this project is to deliver new insights into the evolution and diversity of cell structure and function. Cell theory has been a cornerstone of biology for over 150 years. Yet how early cells developed into modern forms is still a mystery. The primitive and poorly understood third domain of life, Archaea, could hold clues. Recently, proteins were discovered in archaea that are related to the tubulin proteins of all higher organisms, which provide the structural framework of cells essential for survival. This project aims to reveal the basis of how the archaeal tubulin proteins control cell shape in response to environmental change, and to develop a new paradigm for archaeal cell biology. This may find application in Australia's biotechnology industries.Read moreRead less
Sequence-defined polymers and green chemistry. This project aims to synthesise polymers that have precise chemical structure and mimic the biological activities of natural biopolymers like peptides and proteins. Monomer sequence regulation in these natural biopolymers is important in biology and necessary for crucial features of life, such as molecular recognition, self-replication and catalysis. Current artificial techniques for biopolymer synthesis are time consuming and present low yields at ....Sequence-defined polymers and green chemistry. This project aims to synthesise polymers that have precise chemical structure and mimic the biological activities of natural biopolymers like peptides and proteins. Monomer sequence regulation in these natural biopolymers is important in biology and necessary for crucial features of life, such as molecular recognition, self-replication and catalysis. Current artificial techniques for biopolymer synthesis are time consuming and present low yields at high costs. This project expects its new materials will increase manufacturing sustainability, chemical diversity and industrial viability; produce health benefits for Australia by improving chemotherapy and diagnosis for diseases; and benefit the Australian economy.Read moreRead less
Multifunctional and Multimodal Theranostics: Manipulating Material Properties for Advanced Diagnostics. The utilisation of polymers in nanomedicine requires a bottom-up approach, where the fundamental chemistry is well-established and understood before it enables an application. This project develops branched polymers as new nanomaterials for theranostics; imaging modalities that “switch-on” when miRNA is released will quantify how much nanomaterial gets to a specific site, while a built-in sens ....Multifunctional and Multimodal Theranostics: Manipulating Material Properties for Advanced Diagnostics. The utilisation of polymers in nanomedicine requires a bottom-up approach, where the fundamental chemistry is well-established and understood before it enables an application. This project develops branched polymers as new nanomaterials for theranostics; imaging modalities that “switch-on” when miRNA is released will quantify how much nanomaterial gets to a specific site, while a built-in sensor based on physical changes in the nanomaterial will measure the onset and progression of necrosis. The aim is to develop a fundamental understanding of how polymer architecture and functionality can be utilised to drive device performance, providing a platform to probe new technology and methodologies for development of next generation theranostics.Read moreRead less