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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
Improving clostridial toxoid production through molecular fermentation maps. This project aims to improve vaccine production by generating detailed molecular maps of fermentation which will be used to design superior fermentation processes with reduced cost. Toxoid vaccines, used routinely in the livestock industry to prevent animal-disease caused by pathogenic Clostridia, are produced using batch fermentation processes. These processes have undergone limited optimisation over the past five deca ....Improving clostridial toxoid production through molecular fermentation maps. This project aims to improve vaccine production by generating detailed molecular maps of fermentation which will be used to design superior fermentation processes with reduced cost. Toxoid vaccines, used routinely in the livestock industry to prevent animal-disease caused by pathogenic Clostridia, are produced using batch fermentation processes. These processes have undergone limited optimisation over the past five decades. Low titres and frequent batch failures greatly affect capital use and represent a significant cost. In addition, current optimisation approaches are limited by the use of expensive and noisy endpoint assays. This project aims to use high-throughput chemistry (multi-omics) that overcome these limitations.Read moreRead less
Algal direct-air CO2 capture through interfacial enzyme immobilisation . Capturing CO2 directly from the atmosphere is challenging due to inherently slow mass transfer kinetics. This project aims to overcome this using an enzyme that can rapidly solubilise CO2 from air into water, to produce algae. By engineering the enzyme immobilisation at the air-water interface, this project will activate and protect the enzymes, increasing their lifespan and reducing costs. By understanding mass transfer an ....Algal direct-air CO2 capture through interfacial enzyme immobilisation . Capturing CO2 directly from the atmosphere is challenging due to inherently slow mass transfer kinetics. This project aims to overcome this using an enzyme that can rapidly solubilise CO2 from air into water, to produce algae. By engineering the enzyme immobilisation at the air-water interface, this project will activate and protect the enzymes, increasing their lifespan and reducing costs. By understanding mass transfer and enzyme activity in the interfacial immobilisation media, floating enzyme rafts can be developed for deployment over expansive areas, facilitating large-scale conversion of atmospheric CO2 into algae-derived fuels, feeds and chemicals.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101549
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Creating a baker's yeast chassis cell via shikimate pathway engineering for production of sustainable, carbon-neutral plastic precursors for the future. From air bags to carpets, tyres and garden hoses, plastics shape our every day life. Coming from fossil fuels most are currently neither sustainable nor renewable. This project will engineer baker's yeast to produce plastic precursors from cane sugar in a fermentation process. This lays the basis for a sugar cane based chemical industry.
Intracellular manufacturing - high performance biomaterials from methane. The aim of this project is to produce high performance biodegradable polymers directly from methane. The key innovation is employing cutting-edge community genomic and transcriptomic approaches to characterise intracellular production lines in order to tailor polyhydroxybutyrate-co-valerate (PHBV) copolymer microstructures. This is a truly multidisciplinary project bringing together engineers, polymer scientists and molecu ....Intracellular manufacturing - high performance biomaterials from methane. The aim of this project is to produce high performance biodegradable polymers directly from methane. The key innovation is employing cutting-edge community genomic and transcriptomic approaches to characterise intracellular production lines in order to tailor polyhydroxybutyrate-co-valerate (PHBV) copolymer microstructures. This is a truly multidisciplinary project bringing together engineers, polymer scientists and molecular biologists. It is expected that a direct outcome of the project will be the first PHBV copolymer from methane. As such, the project aims to develop technology for the production of tough, flexible and affordable biopolymers and, at the same time, provide an opportunity to add value to methane.Read moreRead less
Sustainable dollar notes and other polypropylenes from bioderived feedstocks. Fossil fuels provide us with the essential chemicals for our life style. The chemical industry recognizes limited supply and a need to reduce carbon emissions. Microbes are able to supply green chemicals (e.g. bio-ethanol), but efficiencies are often low. This project will develop microbes for the fermentative production of plastics from cane sugar.
Discovery and characterisation of novel lanthipeptide biopreservatives. The aim of this project is to advance fundamental knowledge of microbial metabolism and provide natural anti-microbial molecules to the Australian food industry. A quarter of the world’s food supply is lost because of microbiological spoilage. Some chemical preservatives have been developed to combat food spoilage organisms, however their chronic impact on human health is the subject of debate. Consumer demand for safe and n ....Discovery and characterisation of novel lanthipeptide biopreservatives. The aim of this project is to advance fundamental knowledge of microbial metabolism and provide natural anti-microbial molecules to the Australian food industry. A quarter of the world’s food supply is lost because of microbiological spoilage. Some chemical preservatives have been developed to combat food spoilage organisms, however their chronic impact on human health is the subject of debate. Consumer demand for safe and natural alternatives is growing. Paradoxically, microbially-produced bioactive peptides may be the key to combating food spoilage organisms and food-borne pathogens. To this end, the project intends to develop an innovative strategy for the discovery, biosynthesis and characterisation of novel anti-microbial lanthipeptides.Read moreRead less
Synthetic phenazines for enhanced biogas production from renewable and non-renewable resources. Methane (biogas) has a large role to play in meeting the energy needs of the human race globally whilst reducing greenhouse gas emissions. Microbial communities are responsible for biogas production from non-renewable (coal) and renewable (food waste) resources. This project seeks to: increase biogas yields by redirecting electron flow towards biogas producing microbes using electrochemically active p ....Synthetic phenazines for enhanced biogas production from renewable and non-renewable resources. Methane (biogas) has a large role to play in meeting the energy needs of the human race globally whilst reducing greenhouse gas emissions. Microbial communities are responsible for biogas production from non-renewable (coal) and renewable (food waste) resources. This project seeks to: increase biogas yields by redirecting electron flow towards biogas producing microbes using electrochemically active phenazines; understand the molecular mechanism by which phenazines increase biogas yields; and, assess the environmental consequence of phenazine application to coal seam gas production and anaerobic digestion of food waste. Phenazines are likely to emerge as a safe and cost-effective technology for improved biogas generation.Read moreRead less
The use of in planta digestion for pretreatment of biofuel feedstock. This project will develop crop plants that overcome the current technical and economic impediments to the use of crop residues as biomass for large scale biofuel production. This innovation will position rural Australia at the forefront of global efforts to develop ligno-cellulose-based fuel ethanol industries and help meet mandatory renewable energy targets and the growing demand for alternative transport fuels. This project ....The use of in planta digestion for pretreatment of biofuel feedstock. This project will develop crop plants that overcome the current technical and economic impediments to the use of crop residues as biomass for large scale biofuel production. This innovation will position rural Australia at the forefront of global efforts to develop ligno-cellulose-based fuel ethanol industries and help meet mandatory renewable energy targets and the growing demand for alternative transport fuels. This project will also provide training and professional development for three early career researchers, exposing them to a suite of cutting edge technologies applied to a real world challenge - supplying renewable fuels in a sustainable and economically viable fashion.
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Mid-Career Industry Fellowships - Grant ID: IM230100154
Funder
Australian Research Council
Funding Amount
$1,049,904.00
Summary
Fungi Power: Designer Fungal Cell Factories for Advanced Biomanufacturing. This project aims to build an advanced biomanufacturing platform based on filamentous fungi in collaboration with industry. Using synthetic biology, the project expects to engineer superior fungal host strains customisable to the needs of the industry and to address their technological gaps. The expected outcomes include the development of cost-efficient and sustainable fungal-based bioprocesses for the companies to produ ....Fungi Power: Designer Fungal Cell Factories for Advanced Biomanufacturing. This project aims to build an advanced biomanufacturing platform based on filamentous fungi in collaboration with industry. Using synthetic biology, the project expects to engineer superior fungal host strains customisable to the needs of the industry and to address their technological gaps. The expected outcomes include the development of cost-efficient and sustainable fungal-based bioprocesses for the companies to produce products, such as fine chemicals, pharmaceutical actives and food ingredients. The project would provide significant benefits by enabling existing and emerging companies' commercial successes and competitiveness in global markets, creating new jobs and resulting in the growth of the bio-economy in Australia.Read moreRead less