Polymer-functionalised nanotubes: controlled formation by self-assembly. This project will develop new structures of nanotubes by combining peptide sequences and synthetic polymers. These nanostructured materials will form the basis of a wide range of technological applications, such as inorganic nanotubes, ion channels, drug carriers, and more broadly in nanotechnology and nanomedicine.
Polyion complex micelles as smart nano-sized drug carriers for proteins. Novel treatments against diseases are often based on proteins, which are unstable against hydrolysis and sometimes difficult to deliver across the cell membrane. The aim of the project is to create a smart drug carrier that can encapsulate proteins efficiently. A range of block copolymers will be synthesised that are able to condense a positively charged protein resulting in the formation of polyion complex micelles. The po ....Polyion complex micelles as smart nano-sized drug carriers for proteins. Novel treatments against diseases are often based on proteins, which are unstable against hydrolysis and sometimes difficult to deliver across the cell membrane. The aim of the project is to create a smart drug carrier that can encapsulate proteins efficiently. A range of block copolymers will be synthesised that are able to condense a positively charged protein resulting in the formation of polyion complex micelles. The polymer structure will be fine-tuned to create a drug carrier that releases the protein efficiently once inside mammalian cells. The outcome will be the enhanced understanding of the relationship between polymer structure and the activity of the protein and ultimately the design of an advanced and smart drug carrier.Read moreRead less
Next-generation lithography: photo-directing assembly of block copolymers. This project aims to introduce a novel approach to organising block polymers through the photochemical modification of the surface of a photo-sensitive polymer. Chemo-epitaxy is the science of organising materials on a surface decorated with chemical patterns. The process has the potential to revolutionise the manufacture of integrated circuits, enabling faster processors. This project expects to introduce innovative conc ....Next-generation lithography: photo-directing assembly of block copolymers. This project aims to introduce a novel approach to organising block polymers through the photochemical modification of the surface of a photo-sensitive polymer. Chemo-epitaxy is the science of organising materials on a surface decorated with chemical patterns. The process has the potential to revolutionise the manufacture of integrated circuits, enabling faster processors. This project expects to introduce innovative concepts in polymer chemistry and nanoscale assembly with the potential to advance a multi-billion-dollar industry.Read moreRead less
A platform for the efficient optimisation of drug delivery using cross-linked micelles and thioclick-chemistry toward better anti-cancer treatment. The delivery of albendazole - an anti-cancer drug - will be improved by encapsulating the drug into nanoparticles. State of the art polymer chemistry will be employed to generate a versatile drug delivery system. The resulting nanoparticles will be able to better control drug delivery and to enhance cellular uptake of the drug.
Discovery Early Career Researcher Award - Grant ID: DE200101096
Funder
Australian Research Council
Funding Amount
$427,098.00
Summary
Programming Polymer Function via Ring-opening Polymerisation of Peptides. The project aims to set the foundation of a class of intelligent polymers, whose structure and function – including catalytic activity and biodegradability – can be readily programmed. In contrast to well-established radical polymerization techniques leading to all-carbon based backbones, the outlined research will develop technologies to incorporate short peptides into the backbones of synthetic polymers. The syntheticall ....Programming Polymer Function via Ring-opening Polymerisation of Peptides. The project aims to set the foundation of a class of intelligent polymers, whose structure and function – including catalytic activity and biodegradability – can be readily programmed. In contrast to well-established radical polymerization techniques leading to all-carbon based backbones, the outlined research will develop technologies to incorporate short peptides into the backbones of synthetic polymers. The synthetically adjustable amino acid sequence of the main chain embedded peptides will translate into the structure and function of the modular polymer. The DECRA will deliver unprecedented access towards tailor-made mechanical properties, catalytic activity and biodegradability of polymeric materials.Read moreRead less