The Fluid-Particle Mechanics of a Synthetic Jet-based Dry Powder Inhaler. This project aims to untangle the fundamental principles that govern the fluid mechanics and particulate interactions in a novel concept chip-based micro-zero-net-mass-flux (micro-ZNMF) jet-assisted dry powder inhaler (DPI). Respiratory diseases affect 6.2 million Australians. The treatment of these diseases is hampered by the poor efficiency of current delivery systems, with conventional DPI devices exhibiting sub-optimum ....The Fluid-Particle Mechanics of a Synthetic Jet-based Dry Powder Inhaler. This project aims to untangle the fundamental principles that govern the fluid mechanics and particulate interactions in a novel concept chip-based micro-zero-net-mass-flux (micro-ZNMF) jet-assisted dry powder inhaler (DPI). Respiratory diseases affect 6.2 million Australians. The treatment of these diseases is hampered by the poor efficiency of current delivery systems, with conventional DPI devices exhibiting sub-optimum performance, delivering typically less than 20% of the loaded dose to the target site, the lungs. The new fundamental knowledge resulting from this research will enable the engineering of a high-efficiency groundbreaking DPI, with the potential to be fully adaptive user-specific benefiting millions of Australians. Read moreRead less
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
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