Engineering an environmentally-friendly metered dose inhaler. This project aims to deliver a novel simulation framework to accurately predict the behaviour of metered dose inhaler sprays using advanced numerical methods for flash-evaporating turbulent flows developed by the investigators. The project expects to generate new knowledge of the complex physics which occur in these devices through a first of its kind combination of unsteady non-equilibrium thermodynamics, turbulence and spray models. ....Engineering an environmentally-friendly metered dose inhaler. This project aims to deliver a novel simulation framework to accurately predict the behaviour of metered dose inhaler sprays using advanced numerical methods for flash-evaporating turbulent flows developed by the investigators. The project expects to generate new knowledge of the complex physics which occur in these devices through a first of its kind combination of unsteady non-equilibrium thermodynamics, turbulence and spray models. Expected outcomes of this project include a novel ability to predict and optimise the performance of inhalers to suit environmentally-friendly replacement propellants. This will significantly benefit the pharmaceutical sector as it will accelerate the design of next-generation inhalers and propellants.Read moreRead less
Developing novel aerosol inhalers for pulmonary drug delivery from the fundamental understanding of powder dispersion mechanisms. The project seeks to understand how powder aerosol inhalers can be significantly improved. The outcome will provide therapeutic benefits to the Australian community for better treatment of respiratory diseases and facilitate environmentally friendly technology since these inhalers do not require any harmful organic solvents to operate.
Improving respiratory drug delivery through targeted nozzle design. The project aims to develop designs for inhaler components which significantly reduce the existing variability in the sprays they produce, as well as an enhanced capacity to predict inhaler performance through development of new empirical models. This project will combine recently developed synchrotron x-ray measurement techniques with traditional visible light diagnostics to develop a greater understanding of the link between t ....Improving respiratory drug delivery through targeted nozzle design. The project aims to develop designs for inhaler components which significantly reduce the existing variability in the sprays they produce, as well as an enhanced capacity to predict inhaler performance through development of new empirical models. This project will combine recently developed synchrotron x-ray measurement techniques with traditional visible light diagnostics to develop a greater understanding of the link between the geometry of pressurised, metered-dose inhaler components and the drug particles these devices produce. The long term benefit from this research will be improved delivery efficiency and shorter product development times, leading to reduced dose-rate costs. This understanding will enable the development of the next generation of treatment devices with enhanced efficiency in delivery of the drugs used to treat these diseases and reduced costs per dose.Read moreRead less
Smart hybrid system for the formulation and design of dry powder inhalers. This project aims to develop a greater understanding of the link between inhaler device components and the dry powder formulation within. From this understanding, the project aims to develop a hybrid model for the design and manufacture of dry powder inhalers with improved aerosol deposition performances as well as an enhanced capacity to predict formulation performance. The long term benefits will be improved delivery ef ....Smart hybrid system for the formulation and design of dry powder inhalers. This project aims to develop a greater understanding of the link between inhaler device components and the dry powder formulation within. From this understanding, the project aims to develop a hybrid model for the design and manufacture of dry powder inhalers with improved aerosol deposition performances as well as an enhanced capacity to predict formulation performance. The long term benefits will be improved delivery efficiency and shorter development times, leading to reduced manufacturing costs.Read moreRead less
Bridging the gap between global mechanics and regional imaging in the lungs. The detailed mechanics of breathing are not well understood, due to a lack of regional lung measurement techniques. This project aims to develop a powerful analysis tool to image in vivo mechanical properties of the lungs. The expected outcome of this project is a novel platform for investigation and understanding of lung function, enabling information previously only available for the whole lung to be calculated for lo ....Bridging the gap between global mechanics and regional imaging in the lungs. The detailed mechanics of breathing are not well understood, due to a lack of regional lung measurement techniques. This project aims to develop a powerful analysis tool to image in vivo mechanical properties of the lungs. The expected outcome of this project is a novel platform for investigation and understanding of lung function, enabling information previously only available for the whole lung to be calculated for local lung regions within the body. The image analysis methods developed are intended to enable respiratory researchers to investigate lung function in unprecedented detail, leading to new insights into the workings of this complicated and vital organ. Read moreRead less
Enabling precise droplet control in hydrofluorocarbon free sprays. This project aims to investigate the use of blended propellants to replace hydrofluorocarbons in technical aerosols. This project expects to generate new knowledge in the area of multiphase fluid mechanics and aerosol science through a combination of modeling, optical and synchrotron X-ray measurement techniques. Expected outcomes of this project include a capacity to develop environmentally friendly technical aerosol formulation ....Enabling precise droplet control in hydrofluorocarbon free sprays. This project aims to investigate the use of blended propellants to replace hydrofluorocarbons in technical aerosols. This project expects to generate new knowledge in the area of multiphase fluid mechanics and aerosol science through a combination of modeling, optical and synchrotron X-ray measurement techniques. Expected outcomes of this project include a capacity to develop environmentally friendly technical aerosol formulations which can match and potentially outperform currently available hydrofluorocarbon based products. This should provide significant benefits to the pharmaceutical industry through the generation of new knowledge regarding the fundamental physics of multicomponent sprays.Read moreRead less
Hybrid imaging/modelling: A new paradigm for understanding the lung. Our lungs are essential to sustain our lives, yet the details of lung biomechanics are barely understood because the available tools, imaging, modelling and simulation have significant limitations. Imaging is largely limited to providing structural information; simulation is severely restricted by a lack of validation; and inverse modelling is critically hampered by a lack of spatially resolved inputs. The project’s multidiscip ....Hybrid imaging/modelling: A new paradigm for understanding the lung. Our lungs are essential to sustain our lives, yet the details of lung biomechanics are barely understood because the available tools, imaging, modelling and simulation have significant limitations. Imaging is largely limited to providing structural information; simulation is severely restricted by a lack of validation; and inverse modelling is critically hampered by a lack of spatially resolved inputs. The project’s multidisciplinary team is uniquely positioned to explore these problems through the hybridisation of world-leading functional lung imaging technology with state-of-the-art modelling. This project aims to provide, perhaps for the first time, the capacity to see details with the resolution of imaging, richness of modelling and reliability of the finest measurements.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101133
Funder
Australian Research Council
Funding Amount
$358,551.00
Summary
Linking structure and function: a new approach for understanding the lung. This project aims to develop a powerful analysis tool to measure gas transport and mixing within lungs. This project will study the mechanical workings of the lungs, using an innovative approach for analysis of lung images. The expected outcome of this project is a novel platform for investigation and understanding of lung function. It is anticipated that application of the project outcomes to medical challenges in the lo ....Linking structure and function: a new approach for understanding the lung. This project aims to develop a powerful analysis tool to measure gas transport and mixing within lungs. This project will study the mechanical workings of the lungs, using an innovative approach for analysis of lung images. The expected outcome of this project is a novel platform for investigation and understanding of lung function. It is anticipated that application of the project outcomes to medical challenges in the long-term will lead to improved diagnostics and treatments for lung diseases.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100018
Funder
Australian Research Council
Funding Amount
$362,441.00
Summary
Engineering suspended particle sprays through controlled cavitation. This project aims to use cavitation to engineer particle size in sprays of micronised particles suspended in a propellant, and develop a physical mechanism for this process. Understanding how cavitation affects the size of agglomerates in the liquid phase and droplet size in a spray is critical to developing spray devices that require precise control over the final particle size. This will be achieved through high-resolution op ....Engineering suspended particle sprays through controlled cavitation. This project aims to use cavitation to engineer particle size in sprays of micronised particles suspended in a propellant, and develop a physical mechanism for this process. Understanding how cavitation affects the size of agglomerates in the liquid phase and droplet size in a spray is critical to developing spray devices that require precise control over the final particle size. This will be achieved through high-resolution optical imaging techniques and synchrotron X-ray diagnostics. This project is expected to provide physical insight with applications for inhaled and topical pharmaceutical sprays, and industry spray drying of food products.Read moreRead less
Multi-drug dry powder inhalation systems for the effective treatment of chronic obstructive pulmonary disease. Utilising a combination of particle engineering, computer modeling, rapid prototyping and high-speed 3D imaging this project will develop a novel approach to treat chronic obstructive pulmonary disease. A multi-drug particle system whose surface is independent of the drugs incorporated will be optimised in a novel high efficiency inhalation device.