Granulation of hydrophobic powders: design and control of granule structure. This unique project will further enhance Australia's established world-class excellence in granulation research, and will assist in setting up a new school of excellence in granulation at Monash University. The innovative use of normally problematic material properties to produce 'designer granules' is a clear example of a 'Frontier Technologies' that can be used to develop 'Advanced Materials' for the next generation o ....Granulation of hydrophobic powders: design and control of granule structure. This unique project will further enhance Australia's established world-class excellence in granulation research, and will assist in setting up a new school of excellence in granulation at Monash University. The innovative use of normally problematic material properties to produce 'designer granules' is a clear example of a 'Frontier Technologies' that can be used to develop 'Advanced Materials' for the next generation of agricultural, food and pharmaceutical industries, particularly for delivery of hydrophobic drugs. The innovative ideas presented in this proposal are expected to provide multiple opportunities for collaboration with national and international research institutions and pharmaceutical companies. Read moreRead less
Selective Adsorption throught Molecular Imprinting in Nanoporous Silica. A novel synthesis method, molecular imprinting (MI) combined with a templating technique, will be used to prepare mesoporous silica materials with specific molecular recognition sites. The surface morphology of the materials can be duplicated at a molecular level known as molecular imprinting. The imprinting of metal ions, organic and enantiomeric molecules and the subsequent interactions with the template will be studied ....Selective Adsorption throught Molecular Imprinting in Nanoporous Silica. A novel synthesis method, molecular imprinting (MI) combined with a templating technique, will be used to prepare mesoporous silica materials with specific molecular recognition sites. The surface morphology of the materials can be duplicated at a molecular level known as molecular imprinting. The imprinting of metal ions, organic and enantiomeric molecules and the subsequent interactions with the template will be studied. The molecular recognition properties of imprinted materials will be evaluated by selective adsorption equilibrium and kinetics of Hg2+/Pd2+, D-glucose and (-)-borneol/(+)-fenchol respectively. The novelty of the research is in combining the template synthesis of nanoporous silicates with the technique of MI.Read moreRead less
Discrete Element Method for Analysis and Design of Pharmaceutical Encapsulation. Tablets represent the preferred method of dose delivery in the pharmaceutical industry, with over 80% of the market. PressFit - gelcaps have recently been developed, which encase a tablet core within a gelatin coating. The product combines the consumer appeal of capsules with the processing convenience of tablets, and provides a high degree of tamper-resistance. An important issue is that the caplets are required ....Discrete Element Method for Analysis and Design of Pharmaceutical Encapsulation. Tablets represent the preferred method of dose delivery in the pharmaceutical industry, with over 80% of the market. PressFit - gelcaps have recently been developed, which encase a tablet core within a gelatin coating. The product combines the consumer appeal of capsules with the processing convenience of tablets, and provides a high degree of tamper-resistance. An important issue is that the caplets are required to have very precise dimensional precision, an issue not previously of high priority for tabletting . This project seeks to enhance the competitive advantage of this new technology, through a combination of advanced mathematical modeling supported by experiments.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
Controlled Crystallisation of Bioactives. The new technologies developed in this project for bioactive recovery and particle design will allow the development of new value added products for Australia's growing biotechnology industry, especially in pharmaceuticals, neutraceuticals and functional foods. Two PhD students will receive excellent research training to then move into research and development in these industries.
Particle Design for Recovery and Delivery of Bioactives. This project will develop new strategies for economically viable recovery of bioactives from complex solutions, slurries and sludges of biomaterials eg. waste streams from milk and soy bean processing, and fermentation broths. These bioactives, often proteins, have growing applications as high value drugs, nutriceuticals and food additives but are difficult to separate and to maintain in an active form. Crystallisation will be used as a ....Particle Design for Recovery and Delivery of Bioactives. This project will develop new strategies for economically viable recovery of bioactives from complex solutions, slurries and sludges of biomaterials eg. waste streams from milk and soy bean processing, and fermentation broths. These bioactives, often proteins, have growing applications as high value drugs, nutriceuticals and food additives but are difficult to separate and to maintain in an active form. Crystallisation will be used as a primary separation technique. Molecular studies of protein interactions will be used to predict good crystallisation conditions and linked to process crystallisation studies. Both standard and novel particle design strategies will be used to control crystal size and morphology, as well as package the boactive in a deliverable form without loss of activity.Read moreRead less
Particle design and recovery of bioactives by crystallisation and precipitation. This project will develop new strategies for economically viable recovery of bioactives from complex solutions of biomaterials eg. separation of biopharmaceuticals from genetically engineered cell culture, food ingredient processing, functional food and nutraceutical extraction from natural sources. Crystallisation and precipitation will be used as primary separation techniques. We propose a new paradigm in which ....Particle design and recovery of bioactives by crystallisation and precipitation. This project will develop new strategies for economically viable recovery of bioactives from complex solutions of biomaterials eg. separation of biopharmaceuticals from genetically engineered cell culture, food ingredient processing, functional food and nutraceutical extraction from natural sources. Crystallisation and precipitation will be used as primary separation techniques. We propose a new paradigm in which molecular studies of protein interactions will be used to predict good crystallisation conditions and linked to process crystalliation studies. Studies will use a model system of egg white protein mixtures and a real system of industrial importance - the purification of valuable protein products from soy beans (valued at $500 million per year world wide). Soy beans studies will include pilot scale tests at Dupont's industrial reseach laboratories.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