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.
Numerical Modelling and Experimental Studies to Design and Engineer Nanoparticulate Systems for Bioapplications. Project outcomes will enhance Australia's reputation for scientific innovation in the field of bio-nanotechnology. The project will expand the knowledge base in this area and increase Australia's international profile in research on nanomaterials for bio-related applications. The project partners UNSW and Australian company (Minomic), integrating their skills, expertise and facilities ....Numerical Modelling and Experimental Studies to Design and Engineer Nanoparticulate Systems for Bioapplications. Project outcomes will enhance Australia's reputation for scientific innovation in the field of bio-nanotechnology. The project will expand the knowledge base in this area and increase Australia's international profile in research on nanomaterials for bio-related applications. The project partners UNSW and Australian company (Minomic), integrating their skills, expertise and facilities to address current limitations in understanding the stability of magnetic nanoparticles in biological fluids. The Australian partners will play a leading role in commercializing new applications for functionalized magnetic nanoparticles. The project will provide an excellent multidisciplinary research environment and training for early career researchers.Read moreRead less
Modelling of Adsorption Dynamics in Microporous Adsorbents Using Fractional Order Diffusion Equations. This project investigates the use of fractional order diffusion equations in modelling adsorption dynamics in microporous carbons. The long tail behaviour of adsorption processes cannot be readily explained by the classical second order Fickian model, and makes adsorption a candidate for the use of fractional order diffusion equations that have the potential to model such features. In the pre ....Modelling of Adsorption Dynamics in Microporous Adsorbents Using Fractional Order Diffusion Equations. This project investigates the use of fractional order diffusion equations in modelling adsorption dynamics in microporous carbons. The long tail behaviour of adsorption processes cannot be readily explained by the classical second order Fickian model, and makes adsorption a candidate for the use of fractional order diffusion equations that have the potential to model such features. In the present project we shall develop suitable numerical techniques for solving the fractional order diffusion model, and apply these to the interpretation of experimental kinetic data. The outcome will be an improved model of adsorption dynamics considering the fractal nature of the solid.Read moreRead less
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
Modelling of Adsorption Dynamics in Microporous Solids based on Molecular Dynamics Computations. This project seeks to incorporate non-equilibrium molecular dynamics calculations into particle scale models for adsorption kinetics. Molecular dynamics calculations will be performed for hydrocarbon molecules in small pores to obtain transport coefficients in pores of various sizes, at various bulk gas pressures and temperatures. These transport coefficients will be used in particle scale models t ....Modelling of Adsorption Dynamics in Microporous Solids based on Molecular Dynamics Computations. This project seeks to incorporate non-equilibrium molecular dynamics calculations into particle scale models for adsorption kinetics. Molecular dynamics calculations will be performed for hydrocarbon molecules in small pores to obtain transport coefficients in pores of various sizes, at various bulk gas pressures and temperatures. These transport coefficients will be used in particle scale models to obtain a dynamic model, which will be utilised to interpret experimental data from the literature as well as that being obtained in our laboratory. Such first principles-based modelling has not been performed before at the particle scale, and will mitigate the empiricism in existing approaches.Read moreRead less
Improved Nanoscale and Molecular Models for Nanostructured Carbons, and their Applications in Simulation of Confined Fluids. This project has a multitude of benefits for Australia, a key one of which is the promotion of cross-disciplinary interaction and collaboration to conduct leading edge research in a technologically important area. In addition the project will utilize two PhD students who will be trained in research, and gain a broad range of skills in this multifaceted project involving t ....Improved Nanoscale and Molecular Models for Nanostructured Carbons, and their Applications in Simulation of Confined Fluids. This project has a multitude of benefits for Australia, a key one of which is the promotion of cross-disciplinary interaction and collaboration to conduct leading edge research in a technologically important area. In addition the project will utilize two PhD students who will be trained in research, and gain a broad range of skills in this multifaceted project involving theory, simulation and experiment. The research, grounded in molecular fundamentals, will also lead to the development of advanced tools for adsorption process modelling, useful in process design and scale-up, and contribute to Goal 1 of National Priority Area 3: Frontier Technologies for Building and Transforming Australian Industries.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