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Novel technologies for biodiesel production from meat processing waste streams. Deriving products from all levels of the agricultural production chain to achieve zero-waste, greatly increases profitability and optimises sustainability. In the meat industry, new opportunities are opening to use by-products such as tallow for the production of novel, cleaner energy-producing biodiesel fuel by way of cutting-edge technologies. Production by these technologies greatly enhances cost benefits, fuel p ....Novel technologies for biodiesel production from meat processing waste streams. Deriving products from all levels of the agricultural production chain to achieve zero-waste, greatly increases profitability and optimises sustainability. In the meat industry, new opportunities are opening to use by-products such as tallow for the production of novel, cleaner energy-producing biodiesel fuel by way of cutting-edge technologies. Production by these technologies greatly enhances cost benefits, fuel properties and energy security. In this proposal we will partner with a large South Australian regional abattoir and rendering facility to develop these technologies initially at the laboratory scale, and then up-scaling to pilot and full production levels. Read moreRead less
Scaling microfluidics for cell manufacture. Scaling microfluidics for cell manufacture. This project aims to scale microfluidic devices for cell manufacture. Large-scale cell manufacturing processes (cell selection, gene transfer and culture expansion) are expensive, multistep and labour-intensive processes. Lab-on-a-chip devices can automate and integrate these complex processes at microscale. This project will evaluate a prototype bioreactor. This research is expected to make cell therapies ch ....Scaling microfluidics for cell manufacture. Scaling microfluidics for cell manufacture. This project aims to scale microfluidic devices for cell manufacture. Large-scale cell manufacturing processes (cell selection, gene transfer and culture expansion) are expensive, multistep and labour-intensive processes. Lab-on-a-chip devices can automate and integrate these complex processes at microscale. This project will evaluate a prototype bioreactor. This research is expected to make cell therapies cheap enough to become standard treatment, which would benefit patients with diseases that are incurable by conventional therapies (surgery and drug treatments). It should also benefit the Australian advanced manufacturing sector, particularly biopharmaceutical and cell therapy industries.Read moreRead less
Probing microbial emulsions to break barriers to green oil production. This project aims to understand ultrasonic processing of concentrated slurries of oil-bearing yeast and algae. Humans must reduce their dependency on petroleum. While microorganisms can produce oils as replacement fuels and base chemicals, the processes for extracting these oils are inefficient. Ultrasound could improve oil recovery by replacing toxic solvents. Understanding the effects of ultrasound on microbial emulsions is ....Probing microbial emulsions to break barriers to green oil production. This project aims to understand ultrasonic processing of concentrated slurries of oil-bearing yeast and algae. Humans must reduce their dependency on petroleum. While microorganisms can produce oils as replacement fuels and base chemicals, the processes for extracting these oils are inefficient. Ultrasound could improve oil recovery by replacing toxic solvents. Understanding the effects of ultrasound on microbial emulsions is expected to develop solvent-free oil recovery processes that improve the economic and environmental benefits of microbial oil production. Such processes would greatly increase the efficiency and reduce the cost of producing microbial oils that can be used as green alternatives to petroleum fuels and chemicals.Read moreRead less
Efficient CO and CO2 conversion to biopolymers using phototrophic bacteria. This project aims to deliver efficient processes for the large-scale production of biopolymers from low cost inputs, using phototrophic bacteria. Feedstocks include syngas from solid wastes and carbon-dioxide-hydrogen mixes from fossil and renewable sources. The choice of phototrophic bacteria avoids the energy losses associated with existing technologies, since photons are used instead of chemical energy for metabolic n ....Efficient CO and CO2 conversion to biopolymers using phototrophic bacteria. This project aims to deliver efficient processes for the large-scale production of biopolymers from low cost inputs, using phototrophic bacteria. Feedstocks include syngas from solid wastes and carbon-dioxide-hydrogen mixes from fossil and renewable sources. The choice of phototrophic bacteria avoids the energy losses associated with existing technologies, since photons are used instead of chemical energy for metabolic needs. This project enables the production and optimisation of biopolymers through collaborations between engineers, polymer scientists and molecular biologists. The project will deliver technologies to produce tough, flexible and affordable biopolymers, converting wastes and greenhouse gases to a valuable product.Read moreRead less
Design a Targeted Delivery System for Probiotics. The project aims to improve the effectiveness of probiotics by developing a targeted delivery system to the colon. This interdisciplinary research will generate new knowledge in the field of microbiota and develop new delivery systems for live microorganisms and other active compounds. Expected outcomes include increased understanding of the factors affecting the viability of probiotics during storage and passage through the gastro-intestinal tra ....Design a Targeted Delivery System for Probiotics. The project aims to improve the effectiveness of probiotics by developing a targeted delivery system to the colon. This interdisciplinary research will generate new knowledge in the field of microbiota and develop new delivery systems for live microorganisms and other active compounds. Expected outcomes include increased understanding of the factors affecting the viability of probiotics during storage and passage through the gastro-intestinal tract, the establishment of probiotics into gut flora, and how this incorporation affects the dynamics of gut microbiota. The new technology can be utilised across a wide range of therapeutics that target the colon to promote the well-being of our society through commercialisation by industry partner.Read moreRead less
New fermentation and purification production technologies for menaquinone-7 for promoting bone and cardiovascular health. We will develop a significantly more cost-efficient and environmentally friendly process for the production of vitamin K (menaquinone-7, or MK7) to manufacture food supplements for humans and animals. MK7 will increase bone regeneration and minimise the risk of cardiovascular disease. It has the potential to reduce the costs of these conditions for the community, and to incre ....New fermentation and purification production technologies for menaquinone-7 for promoting bone and cardiovascular health. We will develop a significantly more cost-efficient and environmentally friendly process for the production of vitamin K (menaquinone-7, or MK7) to manufacture food supplements for humans and animals. MK7 will increase bone regeneration and minimise the risk of cardiovascular disease. It has the potential to reduce the costs of these conditions for the community, and to increase the quality of life for Australia's ageing population. Orthopaedic diseases are also a major veterinary issue, and our advance should make MK7 a more widely used available supplementary food for animals such as horses and dogs. Read moreRead less
Particle segregation and dynamics in inertial microfluidics systems. This project aims to produce microfluidic devices suitable for high-throughput cell sorting and cellular therapy in the biopharmaceutical industry. This project will combine state-of-the-art experimental approaches with advanced modelling techniques to design and develop the new generation of filtration systems for the pharmaceutical industry. The knowledge and models developed in this project will assist design and development ....Particle segregation and dynamics in inertial microfluidics systems. This project aims to produce microfluidic devices suitable for high-throughput cell sorting and cellular therapy in the biopharmaceutical industry. This project will combine state-of-the-art experimental approaches with advanced modelling techniques to design and develop the new generation of filtration systems for the pharmaceutical industry. The knowledge and models developed in this project will assist design and development of a unique platform for scalable, high-throughput, low-cost and continuous cell separation.Read moreRead less
In situ microbial conversion of coal to methane: Biotechnology development for clean use of Australian coal. We will develop a biotechnology that uses native microorganisms to accelerate the underground conversion of coal to methane. Approximately 90% of Australia’s coal resources cannot be accessed economically using traditional mining technologies. A technology that converts coal to methane could generate an energy supply worth an estimated $60 billion, foster the development of an energy indu ....In situ microbial conversion of coal to methane: Biotechnology development for clean use of Australian coal. We will develop a biotechnology that uses native microorganisms to accelerate the underground conversion of coal to methane. Approximately 90% of Australia’s coal resources cannot be accessed economically using traditional mining technologies. A technology that converts coal to methane could generate an energy supply worth an estimated $60 billion, foster the development of an energy industry now in its infancy, and generate numerous new employment opportunities. Environmentally, methane is a cleaner burning fuel than coal, uses much less water for processing and generates the same quantity of electricity with lower CO2 emissions. This project highlights the fact that Australia’s microbial diversity is a resource we cannot afford to ignore.Read moreRead less
A New Platform for Developing a Compound Against Herpes Simplex Virus. This project aims to further explore the research team’s recent fundamental discovery of a protein found naturally in an Australian abalone that inhibits viral entry by blocking three key viral glycoproteins. We would aim to utilise this knowledge towards development of a new class of therapeutics against Herpes simplex viruses (HSV) and their consequent infections. The new therapeutics could overcome the low bioavailability ....A New Platform for Developing a Compound Against Herpes Simplex Virus. This project aims to further explore the research team’s recent fundamental discovery of a protein found naturally in an Australian abalone that inhibits viral entry by blocking three key viral glycoproteins. We would aim to utilise this knowledge towards development of a new class of therapeutics against Herpes simplex viruses (HSV) and their consequent infections. The new therapeutics could overcome the low bioavailability of current drugs and thus significantly shorten the recurrence period. Such new drugs may have broad applicability.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC130100009
Funder
Australian Research Council
Funding Amount
$2,100,000.00
Summary
ARC Training Centre for Molecular Technology in the Food Industry. A molecular technology platform for enabling the next revolution in the food industry. Society needs new approaches for solving the difficulties of providing enough food for the future. This Training Centre will train young scientists in the application of applying molecular analysis skills to solve specific problems that the food industry faces in the whole process of taking food production from “field to fork”.