Increasing the utility of tetanus toxins by protein engineering. There are a variety of common diseases that are the result of muscular defects. Some of these may be able to be treated with an agent that increases muscle tone, thereby giving benefit to the patient in the alleviation of symptoms. This project aims to use some of the most potent substances known, bacterial toxins, and engineer them to be valuable agents for treatment of certain muscular disorders.
Investigating the actions of anti-inflammatory pathways in chronic lung disease. There is an urgent need to develop better drugs for Chronic Obstructive Pulmonary Disease (COPD) as patients become resistant to currently used anti-inflammatory drugs with disease progression. This research will uncover fundamental biology into an important class of anti-inflammatory receptor termed ALX/FPR2. This receptor normally coordinates the clearance of infection and injured tissue and subsequently switches ....Investigating the actions of anti-inflammatory pathways in chronic lung disease. There is an urgent need to develop better drugs for Chronic Obstructive Pulmonary Disease (COPD) as patients become resistant to currently used anti-inflammatory drugs with disease progression. This research will uncover fundamental biology into an important class of anti-inflammatory receptor termed ALX/FPR2. This receptor normally coordinates the clearance of infection and injured tissue and subsequently switches off inflammation. Essential knowledge into why this receptor pathway fails to switch off inflammation will be determined. Furthermore, the development of targeting strategies to this receptor represents an innovative approach to blocking damaging and chronic airway inflammation.Read moreRead less
Elucidating the post-transcriptional regulation of mast cell proteases. Mast cells (MCs) are immune cells that protect against pathogens but may induce deleterious inflammation. MC function is mediated by specific proteases that are pre-formed and stored in granules. These proteases have unique yet poorly understood mechanisms of regulation. The aim of the project is to use a novel suite of molecular tools and genetically modified mice to identify the critical regions of transcripts that post-tr ....Elucidating the post-transcriptional regulation of mast cell proteases. Mast cells (MCs) are immune cells that protect against pathogens but may induce deleterious inflammation. MC function is mediated by specific proteases that are pre-formed and stored in granules. These proteases have unique yet poorly understood mechanisms of regulation. The aim of the project is to use a novel suite of molecular tools and genetically modified mice to identify the critical regions of transcripts that post-transcriptionally regulate the production and storage of these proteins. The project aims to identify the RNA binding proteins, microRNAs and other novel factors that also regulate them. This is expected to elucidate the post-transcriptional mechanisms of regulation of MC proteases.Read moreRead less
In-vivo detection of airway injury and disease using phase contrast X-ray velocimetry. Currently diagnosis of lung disease, a major cause of death in humans, is based on clinical symptoms that do not usually manifest until the disease is well advanced. This project will develop a novel imaging technique, X-ray velocimetry, to detect changes in tissue before symptoms arise, potentially leading to strategies for managing lung diseases.
Low dose methods for detecting early lung disease using x-ray phase contrast imaging. This project will develop a highly sensitive, low-dose x-ray imaging technique for the early detection of diseases of the respiratory system. This technology will have the potential to be used as a diagnostic screening tool to reduce the incidence of respiratory related deaths from diseases such as lung cancer and emphysema.
Understanding the biology of reactive oxygen species. This project will utilise forefront technologies to identify and characterise fundamental biological processes involving toxic free radicals that cause infectious disease and cancer. The approach synergises with researchers across disciplines and universities to ultimately identify future drugs to improve and maintain health.
Assessing a model of the physiological changes at arousal from sleep. Arousals from sleep are common in the elderly and have adverse consequences. This project will investigate a model of the changes in bodily processes (muscle, brain and cardiovascular activation) that occur when humans awaken from sleep.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668493
Funder
Australian Research Council
Funding Amount
$230,000.00
Summary
Characterising particulate laden flow in the lung airways: from drug delivery to primary anthropogenic sources. Facilities will provide infrastructure at Monash University and University of Sydney to continue the collaboration enhancing excellence in an exciting application of fluidics research, supporting the highest level of graduate training, providing innovative tools for industry and promoting industrial collaborations. The infrastructure is unique and will create international funding and ....Characterising particulate laden flow in the lung airways: from drug delivery to primary anthropogenic sources. Facilities will provide infrastructure at Monash University and University of Sydney to continue the collaboration enhancing excellence in an exciting application of fluidics research, supporting the highest level of graduate training, providing innovative tools for industry and promoting industrial collaborations. The infrastructure is unique and will create international funding and collaborative opportunities to support research and postgraduate training. The equipment will add value to existing infrastructure to enhance understanding of particulate flow with the paradoxical outcomes of improving drug deposition in respiratory delivery and of minimising anthropogenic particular deposition for better therapeutic and health outcomes.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560661
Funder
Australian Research Council
Funding Amount
$245,300.00
Summary
Particulate Characterisation for Pharmaceutical and Engineering Applications. The aim of this proposal is to establish joint facilities between the University of Sydney, Monash University and UNSW for the characterization of surface properties and particle sizes of pharmaceutical aerosols and industrial powders. Such knowledge is important for controlling aerosol production and delivery of drug particles to the lungs. This will have a significant benefit to the pharmaceutical industry and patien ....Particulate Characterisation for Pharmaceutical and Engineering Applications. The aim of this proposal is to establish joint facilities between the University of Sydney, Monash University and UNSW for the characterization of surface properties and particle sizes of pharmaceutical aerosols and industrial powders. Such knowledge is important for controlling aerosol production and delivery of drug particles to the lungs. This will have a significant benefit to the pharmaceutical industry and patients requiring aerosol treatment. Further, the proposed facilities will enhance research in complex particulate processes and modelling, functional nanomaterials, and soft sensor development, thus keeping Australia at the forefront of powder research into various high value adding particulate areas.Read moreRead less
Optimising bubble continuous positive airway pressure (CPAP) for preterm infants. Synchrotron imaging will be used to see how the lungs of newborns are aerated and move when they are supported by continuous positive airway pressure (CPAP) breathing support. This project will provide fundamental biological information that will contribute to refinement of devices to support breathing in babies.