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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.
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.
Discrete particle simulation of powder dispersion in pharmaceutical aerosol inhalers. A successful completion of the project will i) greatly enhance the Australian R&D profile and capabilities of both computational modelling and pharmaceutical aerosol research in the world; ii) provide an improved delivery of therapeutic dose to patients via inhalers with better performance to enhance the therapeutic benefits; iii) enable wide availability of inexpensive and effective pharmaceutical inhalation p ....Discrete particle simulation of powder dispersion in pharmaceutical aerosol inhalers. A successful completion of the project will i) greatly enhance the Australian R&D profile and capabilities of both computational modelling and pharmaceutical aerosol research in the world; ii) provide an improved delivery of therapeutic dose to patients via inhalers with better performance to enhance the therapeutic benefits; iii) enable wide availability of inexpensive and effective pharmaceutical inhalation products to the Australian community for the treatment of asthma and other diseases, iv) facilitate environmentally friendly technology since powder aerosol delivery does not require any harmful organic solvents to operate.Read moreRead less
Synthesis of nanoparticles by impinging liquid-jet precipitation for inhalation drug delivery. The project aim is to develop a state of the art technology for the efficient, reliable and economical production of nanoparticles of drugs suitable for inhalation delivery to the lung. Nanoparticles can penetrate deeper into the lung where they deposit and dissolve faster for enhanced therapeutic effects. The project will focus on both the production process and the particle properties for aerosol a ....Synthesis of nanoparticles by impinging liquid-jet precipitation for inhalation drug delivery. The project aim is to develop a state of the art technology for the efficient, reliable and economical production of nanoparticles of drugs suitable for inhalation delivery to the lung. Nanoparticles can penetrate deeper into the lung where they deposit and dissolve faster for enhanced therapeutic effects. The project will focus on both the production process and the particle properties for aerosol administration. Successful development of the technology will not only gain new knowledge in the key area of nanotechnology, but also lead to better inhalation therapy to benefit patients.Read moreRead less
Development of a novel process for the formation of particles with controlled surface architecture for respiratory drug delivery. A successful conclusion of this project will enhance substantially the competitiveness of Australia's research in functional nanomaterials and advanced biomaterials. The Australian pharmaceutical industry will gain through the ability to develop proprietary pharmaceutical formulations targeted towards taking advantage of the novel process. Patients of asthma, lung inf ....Development of a novel process for the formation of particles with controlled surface architecture for respiratory drug delivery. A successful conclusion of this project will enhance substantially the competitiveness of Australia's research in functional nanomaterials and advanced biomaterials. The Australian pharmaceutical industry will gain through the ability to develop proprietary pharmaceutical formulations targeted towards taking advantage of the novel process. Patients of asthma, lung infection and other serious health problems will benefit from an improved delivery of therapeutic dose at a much reduced cost. The technology is environmentally friendly as powder aerosol delivery does not require any harmful organic solvent to operate.Read moreRead less
High Gravity Precipitation of Nanoparticles for Pulmonary Drug Delivery. This collaborative project aims to explore the huge market potential of drug delivery by inhalation aerosols using nanoparticles. It will apply cutting edge nanotechnology to develop new techniques using high gravity to synthesise particles of biomaterials suitable for inhalation. Nanoparticles can penetrate deeper into the lung where they deposit and dissolve faster for enhanced therapeutic effects. Successful developme ....High Gravity Precipitation of Nanoparticles for Pulmonary Drug Delivery. This collaborative project aims to explore the huge market potential of drug delivery by inhalation aerosols using nanoparticles. It will apply cutting edge nanotechnology to develop new techniques using high gravity to synthesise particles of biomaterials suitable for inhalation. Nanoparticles can penetrate deeper into the lung where they deposit and dissolve faster for enhanced therapeutic effects. Successful development of the technology will position both Australia and the industry partner to take a lead in the application of this novel technology in pharmaceutical aerosols, and provides better inhalation therapy to benefit patients.Read moreRead less
Micromechanical analysis of size segregation and its prediction in granular free-surface flows. Industries often suffer from size segregation in the handling and processing of granular materials, leading to significant economic consequences. This project aims to develop a fundamental understanding of size segregation and prediction models, enabling industries to eliminate, minimise, or manage the effects to an acceptable level.
Optical tweezers as a micro-rheological probe of soft surfaces. Biomembranes are more than soft containers - their dynamic flexibility plays an important role in cell function, but measurements of mechanical properties of soft surfaces are non-existent. This project develops and applies a new optical tweezers method to measure the flexibility of membranes and its effects upon the friction of nearby particles.
Supercritical-microfluidics technology for targeted delivery to the colon. This research will develop nanosystems to target delivery of drugs to the colon. Our nanosystems will permit the combination of clinically used chemotherapy drugs within a single dosage form. This will improve the efficiency of delivery to the colon while reducing unwanted side-effects. A novel supercritical microfluidics system will be developed to produce therapeutic nano-carriers in a continuous mode with lower labour ....Supercritical-microfluidics technology for targeted delivery to the colon. This research will develop nanosystems to target delivery of drugs to the colon. Our nanosystems will permit the combination of clinically used chemotherapy drugs within a single dosage form. This will improve the efficiency of delivery to the colon while reducing unwanted side-effects. A novel supercritical microfluidics system will be developed to produce therapeutic nano-carriers in a continuous mode with lower labour requirement, higher production rate and better quality control than conventional production methods. The new process will combine benefits from both supercritical fluid technology (green process) and microfluidics (high mass & heat transfer).Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100082
Funder
Australian Research Council
Funding Amount
$408,000.00
Summary
Nanostructures derived from metal-organic frameworks for sodium-ion batteries. This project aims to overcome poor reaction kinetics and the lack of effective anode materials owing to the large size of sodium-ions in high performance sodium-ion batteries. The project will explore a series of functional nanomaterials with unique nanostructures and complex compositions, enabled by metal-organic framework assisted synthetic methods. High performance sodium ion batteries are demonstrating great poten ....Nanostructures derived from metal-organic frameworks for sodium-ion batteries. This project aims to overcome poor reaction kinetics and the lack of effective anode materials owing to the large size of sodium-ions in high performance sodium-ion batteries. The project will explore a series of functional nanomaterials with unique nanostructures and complex compositions, enabled by metal-organic framework assisted synthetic methods. High performance sodium ion batteries are demonstrating great potential to meet the future demand for large-scale and low-cost stationary energy storage. However, their practical implementation is still hindered by their poor reaction kinetics and the lack of effective anode materials owing to the large size of sodium-ions. The project outcomes will promote the commercialisation of sodium ion batteries and power Australia’s sustainable economy in the long run.Read moreRead less