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Ultrasonic Processing of Dairy Ingredients to Control Protein Aggregation and Promote Heat Stability. This project is an emerging collaboration between the University of Melbourne, Food Science Australia and the Dairy Ingredients Group of Australia. We aim to use acoustically generated chemical and physical effects to modify dairy proteins. Transformation of the sulphur-containing proteins by this means should overcome many of the difficulties currently encountered in thermal processing of whole ....Ultrasonic Processing of Dairy Ingredients to Control Protein Aggregation and Promote Heat Stability. This project is an emerging collaboration between the University of Melbourne, Food Science Australia and the Dairy Ingredients Group of Australia. We aim to use acoustically generated chemical and physical effects to modify dairy proteins. Transformation of the sulphur-containing proteins by this means should overcome many of the difficulties currently encountered in thermal processing of whole milk and whey proteins. This work will place the Australian dairy industry in a pre-eminent position for the development of valuable, heat-stable and uniquely functional ingredients based on novel micro/nano structures. Existing world class expertise will be further developed in ultrasonic processing and sonochemistry as frontier technologies.Read moreRead less
Design and Development of DNA Oligonucleotide Microarrays (Biochips) for Fish Species Identification From Processed Food Products. Australia's seafood industry (valued at A$2 billion/annum) imports and exports a wide variety of fish and shellfish products. This industry is open to exploitation, specifically in respect of product labelling. A rapid and reliable method for identifying commercial and endangered fish species in seafood products is urgently needed for effective management and regulat ....Design and Development of DNA Oligonucleotide Microarrays (Biochips) for Fish Species Identification From Processed Food Products. Australia's seafood industry (valued at A$2 billion/annum) imports and exports a wide variety of fish and shellfish products. This industry is open to exploitation, specifically in respect of product labelling. A rapid and reliable method for identifying commercial and endangered fish species in seafood products is urgently needed for effective management and regulation of the industry. New genetic biochip technology enables any species or strains of an organism to be rapidly, and accurately, identified by non-experts. In collaboration with GeneScan Australia, this project applies this new technology to develop a diagnostic tool for checking the labelling of Australian seafood products.Read moreRead less
Next-generation technology for determining fitness-for-use of starches in cereal grains. The project will deliver a new methodology to characterize starch-containing materials such as grains. This will provide the first tools to readily measure the full size distribution of starch in industry laboratories, giving far more information than is currently accessible. The data will be extremely sensitive to structural characteristics associated with desirable end-use properties. The new process will ....Next-generation technology for determining fitness-for-use of starches in cereal grains. The project will deliver a new methodology to characterize starch-containing materials such as grains. This will provide the first tools to readily measure the full size distribution of starch in industry laboratories, giving far more information than is currently accessible. The data will be extremely sensitive to structural characteristics associated with desirable end-use properties. The new process will enable conventional instrumentation methodology to be re-engineered to better select starch-containing materials. This will enable superior targeting and processing of materials for improved products in human nutrition, animal feed and manufactured goods such as biodegradable plastics.Read moreRead less
Characterisation and selection of phytocompound and physical seed quality characters of chickpea (Cicer arietinum). To develop and expand both value and volume of the Australian market share for chickpea. Retention and expansion of existing markets will occur through improved seed physical traits such as size, colour and processing efficiency, whilst creation of new markets will be achieved through enhancing novel traits such as the level of phytocompounds. In collaboration with Victoria's Dep ....Characterisation and selection of phytocompound and physical seed quality characters of chickpea (Cicer arietinum). To develop and expand both value and volume of the Australian market share for chickpea. Retention and expansion of existing markets will occur through improved seed physical traits such as size, colour and processing efficiency, whilst creation of new markets will be achieved through enhancing novel traits such as the level of phytocompounds. In collaboration with Victoria's Department of Primary Industry staff, genes governing chickpea quality traits will be characterised through applying novel combinations of selection and analytical methods. A multidsciplinary team of plant breeders, grains chemists and molecular biologists will advance chickpea breeding in Australia by applying cutting-edge technologies.Read moreRead less
The Molecular Mechanism of Protein Instability in Dairy Powder Systems. Dairy is the fourth largest rural industry sectors in Australia, directly involving more than 13,000 farms and a large number of dairy factories. Most of Australia's 10 billion litre milk flow is converted to powder form for exports, with an annual value exceeding $1billion. The anticipated improvements in the performance and shelf-life of the dried dairy powder systems to be investigated in this project have the potential ....The Molecular Mechanism of Protein Instability in Dairy Powder Systems. Dairy is the fourth largest rural industry sectors in Australia, directly involving more than 13,000 farms and a large number of dairy factories. Most of Australia's 10 billion litre milk flow is converted to powder form for exports, with an annual value exceeding $1billion. The anticipated improvements in the performance and shelf-life of the dried dairy powder systems to be investigated in this project have the potential to generate significant economic impacts in both the dairy production and processing sectors. This work will also benefit the wider scientific community in dairy- and food-related areas, particularly in relation to the novel multidisciplinary approach involving a combination of material science and protein chemistry.Read moreRead less
Markers of milk quality in commercially produced UHT milks and milk powders. Efficient production of safe, wholesome food relies on the application of the best available knowledge of the food material and the processing technologies involved. This project applies proteomics, the most advanced protein analysis technique, to determine the changes that occur in milk during high heat treatment and subsequent storage of the heat-processed milk product. Armed with such knowledge, the dairy processin ....Markers of milk quality in commercially produced UHT milks and milk powders. Efficient production of safe, wholesome food relies on the application of the best available knowledge of the food material and the processing technologies involved. This project applies proteomics, the most advanced protein analysis technique, to determine the changes that occur in milk during high heat treatment and subsequent storage of the heat-processed milk product. Armed with such knowledge, the dairy processing industry will be able to make informed decisions about processing and storage conditions to ensure the final products provided to the consumer are of the highest possible quality. Read moreRead less
Tomato and vegetable oil synergies for healthier foods. Vegetable and fruit products are recognised for their content of health-promoting phytonutrients. This project will investigate the bioavailability and subsequent in-vivo antioxidant activity of tomatoes and vegetable oils alone or in combination. A second aim will be to isolate particular phytonutrients from tomates and selected vegetable oils, and then to combine them for determination of synergistic interactions affecting antioxidant ac ....Tomato and vegetable oil synergies for healthier foods. Vegetable and fruit products are recognised for their content of health-promoting phytonutrients. This project will investigate the bioavailability and subsequent in-vivo antioxidant activity of tomatoes and vegetable oils alone or in combination. A second aim will be to isolate particular phytonutrients from tomates and selected vegetable oils, and then to combine them for determination of synergistic interactions affecting antioxidant activity. Opportunities for the preparation of new phytonutrient-oil combination foods with increased antioxidant activity and the potential to enhance the health status of consumers will be developed. The research will provide food processors with expertise to develop novel plant-derived ingredients and food products for sale in the internationally growing functional foods market.Read moreRead less
Establishing the relations between starch nano- and mesostructure and macroscopic physical properties. Starch is the major energy component within human diets, and the most abundant polymer that can be readily extracted from annual crop plants, leading to many actual and potential industrial applications. There are major opportunities to optimise the nutritional value of starches in the human diet, and to enhance the properties of extracted starches as renewable alternatives to petrochemical pol ....Establishing the relations between starch nano- and mesostructure and macroscopic physical properties. Starch is the major energy component within human diets, and the most abundant polymer that can be readily extracted from annual crop plants, leading to many actual and potential industrial applications. There are major opportunities to optimise the nutritional value of starches in the human diet, and to enhance the properties of extracted starches as renewable alternatives to petrochemical polymers. This project will open up our understanding of the structure of starch polymers and show how this relates to important properties such as enzyme digestibility rates, leading to new opportunities for public health and commercial benefits.Read moreRead less
Integrating electrophysiology and molecular biology to understand the role of cell membranes in bacterial responses to chill and osmotic stress. Modern food manufacture is driven by competing demands: consumers prefer foods that are 'natural', i.e. having received minimal processing and containing less preservatives, and last, but are safe. Thus, a challenge is to find minimal sets of treatments and preservatives that limit microbial growth.
Current methods to for determining limits to microbi ....Integrating electrophysiology and molecular biology to understand the role of cell membranes in bacterial responses to chill and osmotic stress. Modern food manufacture is driven by competing demands: consumers prefer foods that are 'natural', i.e. having received minimal processing and containing less preservatives, and last, but are safe. Thus, a challenge is to find minimal sets of treatments and preservatives that limit microbial growth.
Current methods to for determining limits to microbial growth are time and consuming and empirical. We will assess the potential of a new method (MIFE) to rapidly measure limits of bacterial growth under combinations of treatments. At the same time we will study how cells, and in particular how the cell membrane, responds to these stresses to provide insights for the development of new, minimal - yet safe - food preservation technologies.
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Gating, specificity and regulation of the YggB channel protein from Corynebacterium glutamicum. The proposed research will greatly contribute to our understanding of the functioning of a bacterial membrane channel/transporter, which has played a significant role in biotechnology of commercially important amino acids. A direct national benefit will result from establishing collaboration with a leading German laboratory providing expertise in protein biochemistry and molecular microbiology not ava ....Gating, specificity and regulation of the YggB channel protein from Corynebacterium glutamicum. The proposed research will greatly contribute to our understanding of the functioning of a bacterial membrane channel/transporter, which has played a significant role in biotechnology of commercially important amino acids. A direct national benefit will result from establishing collaboration with a leading German laboratory providing expertise in protein biochemistry and molecular microbiology not available in Australia. The acquired knowledge will present an original contribution which will have a strong impact on a very competitive field of molecular microbiology and biotechnology.Read moreRead less