Development of a Novel Process for the Formation of Polymer Vesicles. The project would provide an increased understanding of polymer structures, polymer-drug interactions and dense gas processing of polymers. The novel process developed would be beneficial on a manufacturing level since it dramatically reduces processing time and minimises energy requirements. The research to be conducted is leading-edge technology that will attract business from international polymer, drug and biotechnology co ....Development of a Novel Process for the Formation of Polymer Vesicles. The project would provide an increased understanding of polymer structures, polymer-drug interactions and dense gas processing of polymers. The novel process developed would be beneficial on a manufacturing level since it dramatically reduces processing time and minimises energy requirements. The research to be conducted is leading-edge technology that will attract business from international polymer, drug and biotechnology companies. The development of world-class research provides Australia with recognition as a world leader in the field and strengthens and broadens the knowledge base of Australian scientists and engineers.Read moreRead less
Innovative green technology for bio-particle engineering. Approximately 40% of new pharmaceuticals are poorly soluble in bodily fluids. In many cases this leads to poor bioavailability, and consequent undesirable side effects as a result of high compensating dosages and generally poor patient compliance. These issues will be addressed by developing a green technology for the re-engineering of pharmaceuticals with the objective of increasing bioavilability. The research programme falls within th ....Innovative green technology for bio-particle engineering. Approximately 40% of new pharmaceuticals are poorly soluble in bodily fluids. In many cases this leads to poor bioavailability, and consequent undesirable side effects as a result of high compensating dosages and generally poor patient compliance. These issues will be addressed by developing a green technology for the re-engineering of pharmaceuticals with the objective of increasing bioavilability. The research programme falls within the Designated Research Priority of Frontier Technologies for Building and Transforming Australian Industries. Read moreRead less
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0238094
Funder
Australian Research Council
Funding Amount
$197,000.00
Summary
Fine and Ultrafine Particle - Characterisation and Research Facility. The proposed grant aims to establish an integrated facility for characterising and researching fine and ultrafine particles. It will serve various research groups of three collaborating universities. Current facilities are limited to characterisation of liquid-borne particles down to 10 nm size. To extend the groups research interests into aerosols and nanoparticles the facilities requested in this grant are essential. Equipme ....Fine and Ultrafine Particle - Characterisation and Research Facility. The proposed grant aims to establish an integrated facility for characterising and researching fine and ultrafine particles. It will serve various research groups of three collaborating universities. Current facilities are limited to characterisation of liquid-borne particles down to 10 nm size. To extend the groups research interests into aerosols and nanoparticles the facilities requested in this grant are essential. Equipment critical for research into catalytic processes is also requested. Integration of the groups will create a force that institutions and industries,nation-wide, can turn to when the need for competent analytical and research solutions for particles and catalysis arises.Read moreRead less
Engineering of cartilage-based biomaterials under dynamic culture conditions. This work contributes to the development of advanced technologies in the area of biomaterials. The cartilage biomaterials generated in this work will lead to new medical applications in tissue reconstruction and replacement, which is of direct benefit to society by improving the methods used to treat joint disease and injury. As there is a significant commercial market for tissue-engineered cartilage products, this res ....Engineering of cartilage-based biomaterials under dynamic culture conditions. This work contributes to the development of advanced technologies in the area of biomaterials. The cartilage biomaterials generated in this work will lead to new medical applications in tissue reconstruction and replacement, which is of direct benefit to society by improving the methods used to treat joint disease and injury. As there is a significant commercial market for tissue-engineered cartilage products, this research also has implications for enhancing the scope and profitability of the Australian biotechnology industry. The project will be a vehicle for research training in a broad range of interdisciplinary areas. Students involved in the work will be equipped with a versatile and valuable combination of skills.Read moreRead less
Application of bioreactors for culture of differentiated cells and solid-phase tissues. The aim of this project is to develop methods for producing three-dimensional human cartilage outside of the body. Tissue-engineered cartilage has a range of applications, including in toxicity testing, for production of therapeutics, and as surgical transplant devices. Bioreactors will be used to culture cartilage under controlled conditions for development of living tissues with properties as close as possi ....Application of bioreactors for culture of differentiated cells and solid-phase tissues. The aim of this project is to develop methods for producing three-dimensional human cartilage outside of the body. Tissue-engineered cartilage has a range of applications, including in toxicity testing, for production of therapeutics, and as surgical transplant devices. Bioreactors will be used to culture cartilage under controlled conditions for development of living tissues with properties as close as possible to those of native articular cartilage. Novel culture strategies will be used to enhance the availability of growth factors and provide adequate oxygen and nutrient exchange. These techniques have the potential to yield significant improvements in the quality of engineered cartilage.Read moreRead less
The elutriation of ultrafine particles according to their density. This study is concerned with exploiting a new and powerful mechanism for separating particles according to their density, with strong potential for recovering and concentrating tens of billions of dollars worth of valuable minerals annually. By coupling the new separation mechanism with a centrifugal force it should be possible to apply gravity separation technology, arguably for the first time, to the recovery of ultrafine parti ....The elutriation of ultrafine particles according to their density. This study is concerned with exploiting a new and powerful mechanism for separating particles according to their density, with strong potential for recovering and concentrating tens of billions of dollars worth of valuable minerals annually. By coupling the new separation mechanism with a centrifugal force it should be possible to apply gravity separation technology, arguably for the first time, to the recovery of ultrafine particles from 200 microns to well below 10 microns, at high separation efficiency, and high feed rates. This study is also ideal for training new researchers, especially at the PhD level, in an area of importance to Australia's economic future. Read moreRead less