Reducing skeletal malformations in cultured marine fish using gene expression, improved nutrition and advanced system operation. Reducing malformations in farmed fish will benefit the Australian economy and society by providing greater quantities of cheaper, higher quality fish. Increased farmed fish production, currently worth ~$300 million p.a., will increase exports and decrease imports (currently ~50% of all Australian consumed fish). To benefit are the important regional farming operations ....Reducing skeletal malformations in cultured marine fish using gene expression, improved nutrition and advanced system operation. Reducing malformations in farmed fish will benefit the Australian economy and society by providing greater quantities of cheaper, higher quality fish. Increased farmed fish production, currently worth ~$300 million p.a., will increase exports and decrease imports (currently ~50% of all Australian consumed fish). To benefit are the important regional farming operations in QLD, NSW, SA, NT, TAS and WA. In particular, the largest industry in Tasmania will profit by having a viable new species to farm (striped trumpeter) reducing risk due to climate change and global oversupply of salmon. Another important benefactor will be the rapidly expanding yellowtail kingfish industry. Read moreRead less
Special Research Initiatives - Grant ID: SR0354798
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Interdisciplinary Network for Aquatic Animal Health. The value of Australian fisheries and aquaculture is increasing significantly and, whilst this has resulted in an increase in R&D spending in the area, stifled collaboration amongst isolated scientists sometimes results in slow research progress. This network will enhance research on aquatic animal health. Our main aim is to provide a stimulating environment, encourage collaboration and ensure fast flow of interdisciplinary information between ....Interdisciplinary Network for Aquatic Animal Health. The value of Australian fisheries and aquaculture is increasing significantly and, whilst this has resulted in an increase in R&D spending in the area, stifled collaboration amongst isolated scientists sometimes results in slow research progress. This network will enhance research on aquatic animal health. Our main aim is to provide a stimulating environment, encourage collaboration and ensure fast flow of interdisciplinary information between researchers. We will adapt methods and technologies from medical research and other disciplines to increase our understanding of aquatic animal health and at the same time ensure that our results are applied in other disciplines.Read moreRead less
Tracking squids from embryos to adults - novel approaches and new directions. Cutting edge acoustic tracking technology, combined with traditional tagging techniques and novel applications of trace element analysis, will allow for the life cycle of squid to be tracked through space and time - from embryonic stages through to spawning adults. Southern calamary earbones will be examined for evidence of elemental 'fingerprints' that reveal where they came from as hatchlings. This combined with trac ....Tracking squids from embryos to adults - novel approaches and new directions. Cutting edge acoustic tracking technology, combined with traditional tagging techniques and novel applications of trace element analysis, will allow for the life cycle of squid to be tracked through space and time - from embryonic stages through to spawning adults. Southern calamary earbones will be examined for evidence of elemental 'fingerprints' that reveal where they came from as hatchlings. This combined with tracking squid in Australia's biggest marine acoustic listening grid, will allow unprecedented resolution of squid life cycles. Commercial, recreational and managerial sectors are collaborating with this research to ensure sustainable management of this commercially important and ecologically crucial species.
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