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Role Of Amnion Derived Stem Cells In Reducing Lung Fibrosis
Funder
National Health and Medical Research Council
Funding Amount
$349,485.00
Summary
Human amniotic epithelial multipotential cells from the term placenta are being studied in a mouse model of pulmonary fibrosis-emphysema to demonstrate their anti-inflammatory, anti-fibrotic, immune-suppresive and lung repair capability. The availability and numbers of these cells from discarded placentas at birth are unlimited and their potential to repair serious lung disease would have strong clinical interest as a new stem cell therapy.
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.
Advanced nanotechnologies for targeting biofilms. Advanced nanotechnologies for targeting biofilms. This project aims to develop nano-particulate systems based on a single platform technology that can be delivered as an aerosol. The current lack of a suitable formulation and delivery system hinders the eradication of fungal and bacterial biofilms from surfaces. These new systems will have enhanced residency time, penetration properties and effectiveness in biofilms. This project intends to under ....Advanced nanotechnologies for targeting biofilms. Advanced nanotechnologies for targeting biofilms. This project aims to develop nano-particulate systems based on a single platform technology that can be delivered as an aerosol. The current lack of a suitable formulation and delivery system hinders the eradication of fungal and bacterial biofilms from surfaces. These new systems will have enhanced residency time, penetration properties and effectiveness in biofilms. This project intends to understand the properties that govern the formation and interactions in these systems, and develop in-vitro tools that the wider scientific community can use. The project expects to generate a single platform that can be used for the eradication of biofilms in numerous applications, from healthcare to agriculture.Read moreRead less
Control Of Human Inspiratory Muscles In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$396,699.00
Summary
This project will study how human inspiratory muscles that 'pump' air into the lungs and upper airway 'dilator' muscles are controlled in normal healthy subjects and subjects with respiratory disorders such as obstructive sleep apnoea. We will study (i) the output to the inspiratory muscles, (ii) the interation of automatic and voluntary control of breathing, and (iii) reflex connections of human pump and dilator muscles. This work promises new understanding of basic and patho-physiology.
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
Economic, social and cross cultural issues in non-pharmaceutical protection of front line responders to pandemic influenza and emerging infections. The protection of front line responders in a pandemic is essential to underpin an effective response. This research is the only work internationally which will address a key gap in evidence. This research has major implications for the national stockpile and for management of front line responders in a pandemic. These data are urgently needed, not ju ....Economic, social and cross cultural issues in non-pharmaceutical protection of front line responders to pandemic influenza and emerging infections. The protection of front line responders in a pandemic is essential to underpin an effective response. This research is the only work internationally which will address a key gap in evidence. This research has major implications for the national stockpile and for management of front line responders in a pandemic. These data are urgently needed, not just in Australia, but globally to inform pandemic planning and disease control policy around emerging infections and bioterrorism.Read moreRead less
Treating tuberculosis: targeted delivery of multidrug nano-suspensions. Tuberculosis (TB) is a lung disease of worldwide prevalence. Treatment times are long and mortality is high in children and the elderly. Current treatments are ineffective and drug resistant TB is a real pandemic threat. The project will develop a cost-effective nano-particle system that can be incorporated into conventional nebulisers for use worldwide.
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
X-ray Micro-tomography Validation of HRCT-Based Airway Measurements. This project brings together a newly emergent modality of microscopy in the form of 3D X-ray micro-tomography (XRMT) along with leading-edge image analysis to develop breakthrough science in respiratory research aimed at improving the reliability of high resolution computed tomography (HRCT). The project will develop novel 3D lung image segmentation protocols, a stereotactic registration program allowing 3D matching of XRCT and ....X-ray Micro-tomography Validation of HRCT-Based Airway Measurements. This project brings together a newly emergent modality of microscopy in the form of 3D X-ray micro-tomography (XRMT) along with leading-edge image analysis to develop breakthrough science in respiratory research aimed at improving the reliability of high resolution computed tomography (HRCT). The project will develop novel 3D lung image segmentation protocols, a stereotactic registration program allowing 3D matching of XRCT and HRCT data sets, and a validation protocol for quantitative HRCT analysis of airway disease. These outcomes will allow wider application of HRCT to non-invasively follow the dynamics of pulmonary function.Read moreRead less
Modelling and Measurement of Flow-Structure Dynamics in the Human Upper Airway. Sleep disruption due to the common and disabling conditions of snoring and obstruction of the human upper airway can result in chronic fatigue, lost work and accidents caused by daytime drowsiness. To date the behaviour of the upper airway has not been adequately studied in terms able to reveal the mechanical causes of these conditions. This deficiency is addressed through the development and use of simulation tools ....Modelling and Measurement of Flow-Structure Dynamics in the Human Upper Airway. Sleep disruption due to the common and disabling conditions of snoring and obstruction of the human upper airway can result in chronic fatigue, lost work and accidents caused by daytime drowsiness. To date the behaviour of the upper airway has not been adequately studied in terms able to reveal the mechanical causes of these conditions. This deficiency is addressed through the development and use of simulation tools and measurement techniques that will elucidate the flow-structure dynamics leading to new diagnostic and improved treatment methods. Simulating the effect of treatment on any individual will permit it to be chosen to maximise its efficacy for a problem that costs the nation an estimated $2 Billion per year in lost productivity.Read moreRead less