Identifying The Optimal Age To Apply Physical Activity Interventions To Improve Heart Health
Funder
National Health and Medical Research Council
Funding Amount
$852,804.00
Summary
By performing sophisticated, novel and sensitive measurements on the heart at age 30 and linking these to richly characterised historical data, we will determine whether there is an optimal age to apply physical activity interventions to improve adult heart health. This is possible using data collected from 18 weeks pregnancy through to adulthood in ~3,000 Australians. This study will inform policy and interventions to reduce heart disease; the single biggest cause of mortality in Australia.
Harnessing Information Technology To Improve Self-management Behaviours And Health Outcome In People With Heart Failure: A Smarthome Ecosystem Living Lab Study
Funder
National Health and Medical Research Council
Funding Amount
$1,120,226.00
Summary
The burden of heart failure in Australia is substantial. Management of heart failure is complex and requires self-management of symptoms and behaviour change, which requires ongoing education and support to achieve. Current approaches for supporting self-management do not meet the needs of people with heart failure or the healthcare system. This Australian first project aims to co-design an intelligent smart home ecosystem (Smart Heart) to support the management for people with heart failure.
Targeting Neurovascular Communication As A Novel Way Of Reducing Vision Loss In Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$986,663.00
Summary
Diabetes is a leading cause of blindness. Here, we evaluate whether diabetes causes changes in the way neurons signal to blood vessels, and whether blocking some of the signals from neurons reduces blood vessel abormalities. Overall, this information is critical to our understanding of the early changes that occur during diabetes and whether novel treatments used early in diabetes can prevent long term changes and vision loss.
Dissecting Brain Network Ageing Using Whole Brain Imaging
Funder
National Health and Medical Research Council
Funding Amount
$692,964.00
Summary
In this proposal, we will make the first attempt to map the whole brain activity change during ageing using a series of state-of-the-art techniques. We will also identify genetic and pharmacological interventions that improve brain network function during ageing. Outcomes from this research will provide an unprecedented understanding of functional ageing within the brain and identify therapeutic interventions to prevent this process.
Organisation Of The Genome During The Development Of Antibody-secreting Cells
Funder
National Health and Medical Research Council
Funding Amount
$886,155.00
Summary
Each cell of our body contains over two metres of DNA that must be correctly packaged in order for our cells to function. We are using cutting-edge molecular biology techniques to study how this DNA circuitry is established in the white blood cells of our immune system that produce antibodies. Our novel approaches will reveal unique strategies to modulate immune responses to our benefit.
A Novel Interaction Between The Immune And Vascular Systems In Early-onset Preeclampsia; An Opportunity For New Treatments?
Funder
National Health and Medical Research Council
Funding Amount
$921,623.00
Summary
Preeclampsia is a pregnancy complication that leads to poor birth outcomes and elevated lifelong cardiovascular disease risk in 4 million women each year. It has no cure and treatments are limited because the causal mechanisms are not understood. We have identified a specialised immune cell in the mother's blood that assists blood vessels to function properly in pregnancy. We will assess whether interventions to enhance these cells can improve poor blood vessel function and pregnancy outcomes.
About one in eight known genetic disorders involve DNA alteration that activates a cellular quality control mechanism that disables the affected gene. This mechanism is more efficient in some individuals than others. It can influence disease outcomes and severity. We will engineer and apply tools and models to measure and manipulate this crucial cellular mechanism. This will allow us to predict disease severity as well as to intervene where a manipulation of this mechanism will be beneficial.