Using Nanotechnology To Improve The Therapeutic Efficacy Of Iron Chelators
Funder
National Health and Medical Research Council
Funding Amount
$692,769.00
Summary
Iron loading disorders (such as thalassaemia) represent an important class of human disease. As part of the treatment for these diseases, the iron needs to be removed and this is often done using iron-binding drugs known as iron chelators. Current chelators are not ideal due to side effects or onerous delivery methods. The goal of this project is to use nanotechnology to develop more effective ways of delivering chelators to improve their effectiveness and reduce toxicity.
One of the current challenges in public health is to translate the progress from the Human Genome Project into reduced morbidity and mortality from disease. Once genetic defects are characterised, knowledge about the variability in severity of disease in mutation carriers, is important from a public health perspective. Hereditary Haemochromatosis (HH) is a common genetic disorder of iron overload that results in a wide spectrum of disease, varying from non-specific symptoms to severe damage to l ....One of the current challenges in public health is to translate the progress from the Human Genome Project into reduced morbidity and mortality from disease. Once genetic defects are characterised, knowledge about the variability in severity of disease in mutation carriers, is important from a public health perspective. Hereditary Haemochromatosis (HH) is a common genetic disorder of iron overload that results in a wide spectrum of disease, varying from non-specific symptoms to severe damage to liver, heart, pancreas and joints from iron deposition. It is easily treatable by regular blood donation, and population-based screening for HH has therefore been advocated. In this study we aim to address gaps in the existing data on HH regarding dietary and lifestyle factors that contribute to the variable clinical picture of HH. The study will be based on the Melbourne Collaborative Cohort Study, a cohort of 31,500 men and women who have been followed for approximately 10 years. Information on dietary and lifestyle factors was collected at initial enrollment, along with a blood specimen. We will test all non-Southern European participants (31,176) for the common HH mutations in the HFE gene and then select a subgroup of 1150 people, including all people with the main genetic defect as well as a comparison group, for further clinical followup. Participants will have genetic counselling and informed consent will be obtained. Participants will complete a short questionnaire and give a blood sample for measurement of iron overload, liver function, and other relevant blood tests, then undergo a brief clinical examination. Results of all tests will be given at a followup visit by genetic counsellor or physician. This study will provide important data on natural history of HH risk factors that influence variability in clinical presentation and the association of HFE mutations with chronic diseases and all cause mortality.Read moreRead less
Iron-Infection Interactions: Studies Of The Link Between Iron Metabolism And Infectious Diseases Of Global Significance
Funder
National Health and Medical Research Council
Funding Amount
$383,244.00
Summary
Anaemia, malaria and HIV affect millions of people worldwide, but interactions between these conditions are poorly understood. A haematologist with training in public health, my interest is in finding ways to control the enormous global burden of anaemia. My research will focus on how iron status influences infection with malaria and HIV. It will provide evidence for anaemia control guidelines and help improve global policies for controlling iron deficiency where these infections coexist.
Targeting Iron Piracy From Host Proteins By Neisseria And Haemophilus Spp. For The Development Of Novel Antimicrobials
Funder
National Health and Medical Research Council
Funding Amount
$645,205.00
Summary
The bacteria that cause the sexually transmitted infection gonorrhoea and meningococcal disease are a serious health concern. In order to cause disease, these bacteria must obtain the nutrient iron from our bodies. This proposed research will use cutting edge technologies to understand on a molecular level how these bacteria obtain iron during infection. It will then apply this knowledge to develop molecules that prevent these bacteria from obtaining iron, as a means of treating these diseases.
Defining The Impact Of Universal Iron Interventions In Young Children: A Randomized Controlled Trial In Rural Bangladesh
Funder
National Health and Medical Research Council
Funding Amount
$2,794,373.00
Summary
Although nearly half of the world's young children are anaemic, evidence regarding the best approaches to correct this problem are limited. New data even suggests that the conventional approaches (iron supplements, multiple micronutrient powders) may even be harmful. We will perform the definitive trial which will confirm the existence and magnitude of any benefit (and harm) from these interventions in young Bangladeshi children. This trial will inform global policy on anaemia control.
Benefits And Safety Of IRon Supplementation With MAlaria Chemoprevention To Children In Malawi (IRMA) - A Randomised Controlled Trial
Funder
National Health and Medical Research Council
Funding Amount
$3,064,309.00
Summary
Anaemia and malaria frequently coexist in low income settings e.g. sub-Saharan Africa and Asia. Iron interventions aim to reduce anaemia but exacerbate malaria. We aim to test whether iron is made safe by coadministering malaria prevention, and whether these interventions improve child health outcomes especially cognitive development, while ensuring malaria resistance does not emerge.
Industrial Transformation Research Hubs - Grant ID: IH230100010
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Research Hub for Smart Process Design and Control . ARC Research Hub for Smart Process Design and Control aims to develop and apply advanced computational technologies to model and optimise complex multiphase processes by integrating the novel multiscale and AI modelling approaches. The outcomes include theories, computer models and simulation techniques, advanced knowledge about process modelling and optimisation, innovative technologies and processes for low carbon operations, and tens of ....ARC Research Hub for Smart Process Design and Control . ARC Research Hub for Smart Process Design and Control aims to develop and apply advanced computational technologies to model and optimise complex multiphase processes by integrating the novel multiscale and AI modelling approaches. The outcomes include theories, computer models and simulation techniques, advanced knowledge about process modelling and optimisation, innovative technologies and processes for low carbon operations, and tens of postdoc and PhD students through academic, industrial and international collaboration. Their application will significantly improve energy/process efficiency and reduce CO2 emission. The Hub will generate a significant impact on the mineral and metallurgical industries which are important to Australia.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC220100028
Funder
Australian Research Council
Funding Amount
$4,969,602.00
Summary
ARC Training Centre for Innovative Composites for the Future of Sustainable Mining Equipment. The Centre aims to train industry-focused researchers in advanced manufacturing of new-generation mining equipment and sustainable mining technology, through close collaborations among key universities and mining and manufacturing companies. The Centre will cultivate a team of world-class academic researchers and industry leaders to deliver an innovative program on research of innovative composites coup ....ARC Training Centre for Innovative Composites for the Future of Sustainable Mining Equipment. The Centre aims to train industry-focused researchers in advanced manufacturing of new-generation mining equipment and sustainable mining technology, through close collaborations among key universities and mining and manufacturing companies. The Centre will cultivate a team of world-class academic researchers and industry leaders to deliver an innovative program on research of innovative composites coupled with work-integrated learning, to not only produce a workforce that meets future skills demand but also develop sustainable and cost-effective mining equipment and high-efficiency mining technologies, benefiting the nation's manufacturing and mining sectors and significantly enhancing the competitiveness of the Australian mining industry.Read moreRead less
Model studies of Australian lump ore applied to blast furnace ironmaking. Ore lump use in ironmaking blast furnaces (BFs) requires no preprocessing and has a lower carbon footprint. However, it suffers various technical problems. This project aims to understand and optimize the conditions for such operations. This will be achieved by means of a combined theoretical and experimental program, involving the use of state-of-the-art multiscale computer modelling and simulation techniques. The researc ....Model studies of Australian lump ore applied to blast furnace ironmaking. Ore lump use in ironmaking blast furnaces (BFs) requires no preprocessing and has a lower carbon footprint. However, it suffers various technical problems. This project aims to understand and optimize the conditions for such operations. This will be achieved by means of a combined theoretical and experimental program, involving the use of state-of-the-art multiscale computer modelling and simulation techniques. The research outcomes will be tested in the design and control of lump charging operations in practice through collaboration with the industrial partner. This will ultimately increase Australian ore lump usage in BFs, leading to significant financial and environmental benefits to Australia and the entire steel industry worldwide.Read moreRead less
Thermodynamic basis for ironmaking and slag recycling in circular economy. This project aims to develop new, powerful state-of-the-art computer-based tools to predict the outcomes of complex chemical reactions, high-temperature ironmaking and slag recycling processes. Globally, over 1 billion tonnes of iron are produced each year consuming 30 billion billion (Quintillion) Joules energy! and creating over 300 million tonnes of molten oxides (slags). Our industry partners need new advanced thermod ....Thermodynamic basis for ironmaking and slag recycling in circular economy. This project aims to develop new, powerful state-of-the-art computer-based tools to predict the outcomes of complex chemical reactions, high-temperature ironmaking and slag recycling processes. Globally, over 1 billion tonnes of iron are produced each year consuming 30 billion billion (Quintillion) Joules energy! and creating over 300 million tonnes of molten oxides (slags). Our industry partners need new advanced thermodynamic databases and computer models with which to optimise their major industrial processes and develop new technologies. By delivering these tools, this project expects to benefit both industry and the community through improved process efficiencies, and reductions in energy usage, pollutants, and environmental impacts.
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