Enabling aerosol delivery of phages to defeat antibiotic-resistant bacteria. This project aims to explore the use of bacteriophages towards producing a safe, natural, and highly effective alternative to traditional antibiotics. Respiratory infections caused by multidrug-resistant Gram-negative bacteria are a major health problem worldwide, and cost Australia over $150 million annually. Some 5,000 Australians die each year from antibiotic resistant infections. The project aims to produce efficac ....Enabling aerosol delivery of phages to defeat antibiotic-resistant bacteria. This project aims to explore the use of bacteriophages towards producing a safe, natural, and highly effective alternative to traditional antibiotics. Respiratory infections caused by multidrug-resistant Gram-negative bacteria are a major health problem worldwide, and cost Australia over $150 million annually. Some 5,000 Australians die each year from antibiotic resistant infections. The project aims to produce efficacious and stable formulations of bacteriophages for easy delivery by inhalation as aerosols with a long shelf-life, making them a commercially viable product. The expected research outcome can lead to an economic and efficient technology to produce phage powders for novel treatment strategies of infections by inhalation.Read moreRead less
Probing Anaesthetic Effects with New Functional Imaging Paradigms. This project seeks new insights into the effects of anaesthetics on brain function and repair. Anaesthesia is used in small-animal imaging to immobilise the animal, but in many cases the anaesthesia itself affects the neurophysiological parameters under study. It has also been shown that many anaesthetics enhance recovery after brain injury in small animals. This project plans to exploit a novel functional brain-imaging technique ....Probing Anaesthetic Effects with New Functional Imaging Paradigms. This project seeks new insights into the effects of anaesthetics on brain function and repair. Anaesthesia is used in small-animal imaging to immobilise the animal, but in many cases the anaesthesia itself affects the neurophysiological parameters under study. It has also been shown that many anaesthetics enhance recovery after brain injury in small animals. This project plans to exploit a novel functional brain-imaging technique for conscious animals to gain new insights into the effects of anaesthetics on brain function and recovery from injury. The knowledge gained is expected to improve knowledge of anaesthetic action, guide future anaesthetic use in small animal imaging to improve the accuracy of image-derived research data, and help to clarify how anaesthetics confer neuroprotective effects in brain injury.Read moreRead less
Production of nano-composite particles for inhalational delivery of combination drugs. The project seeks to create a new particle engineering process for pharmaceuticals. The successful outcome will i) enhance substantially the competitiveness of Australia’s research in functional nanomaterials and advanced biomaterials, and ii) benefit the Australian pharmaceutical industry in developing proprietary pharmaceutical formulations.
Novel nano-composite particles for controlled-release drugs via inhalation. This project will explore a novel nano-medicine technology using nanocrystals in liposomes to design new composite particles to enable optimal release of antibiotics delivered by inhalation. Respiratory infection caused by multidrug-resistant bacteria is a major health problem worldwide. Controlled-release products using liposomes simplify dose regimen and enhance bacterial killing. Currently, aerosolised liposomes are l ....Novel nano-composite particles for controlled-release drugs via inhalation. This project will explore a novel nano-medicine technology using nanocrystals in liposomes to design new composite particles to enable optimal release of antibiotics delivered by inhalation. Respiratory infection caused by multidrug-resistant bacteria is a major health problem worldwide. Controlled-release products using liposomes simplify dose regimen and enhance bacterial killing. Currently, aerosolised liposomes are limited to liquid forms with limited control over release and stability. The project will provide new technology on manufacturing composite powders of antibiotics that may ultimately lead to the development of effective new treatments against drug-resistant bacteria.Read moreRead less
Smartdrops - Shaping the future of particle technology. The aim of this project is to develop a particle engineering technology, based on microfluidics, that results in micro-droplets with controlled geometry and morphology. These Smartdrops will be used to target respiratory macrophages for the delivery of inflammatory suppressants, since their dimensions can be controlled to optimise lung deposition and macrophage recognition. The project aims to develop an aerosol inhaler and a series of phys ....Smartdrops - Shaping the future of particle technology. The aim of this project is to develop a particle engineering technology, based on microfluidics, that results in micro-droplets with controlled geometry and morphology. These Smartdrops will be used to target respiratory macrophages for the delivery of inflammatory suppressants, since their dimensions can be controlled to optimise lung deposition and macrophage recognition. The project aims to develop an aerosol inhaler and a series of physico-chemical and in vitro characterisation tools that will be used to study Smartdrop formation, aerosol properties and their interactions with cells. The outcome of this project is intended to be the development of a technology for treating chronic lung inflammation which could also be utilised for a number of other commercial applications.Read moreRead less
The combined use of proteomics and small molecules for target identification and pathway analysis. This project intends to investigate how a series of new small molecules identified from our research to improve the metabolic effects of insulin. This project will integrate medicinal chemistry with proteomics and metabolic biology to identify the cellular targets and their mechanism of action.
Development and use of novel technologies to improve drugs targeting G protein-coupled receptor complexes involved in disease. The purpose of this project is to develop and use new and innovative technologies to improve many of the drugs taken for a wide range of medical conditions. The expected outcomes are the discovery of better drugs and a greater understanding of the drugs currently on the market, particularly enabling improved management of side-effects.