Long-term Surgical And Socioeconomic Outcomes Following Aortopulmonary Septal Defect Repair In Children
Funder
National Health and Medical Research Council
Funding Amount
$89,197.00
Summary
About 2% of heart defects are due to communication between the 2 main arteries exiting the heart (truncus arteriosus and aortopulmonary window). If untreated, up to 30% of children die in the first year of life. With surgery many patients are now surviving into adulthood. The long-term outcomes are unknown. This study will review all patients with this defect across Australian and New Zealand. Results from this study will allow us to best manage these patients in the short and long-term.
Dissecting The Role Of Hedgehog Signalling In Chondrogenesis And Skeletal Disease
Funder
National Health and Medical Research Council
Funding Amount
$408,739.00
Summary
There are close to 400 inherited disorders that affect how the skeleton develops, as well as a range of injury and age-related skeletal defects. There is much interest in treating such abnormalities with artificial bone grown outside the body. In order to achieve this aim we must understand all of the processes involved in producing and maintaining bone within the body. We are using both mouse and cell culture models of skeletal development to increase our understanding of these processes.
Investigation Of Delta3 Function And Notch Signalling During Cell Fate Specification In Mouse And Human
Funder
National Health and Medical Research Council
Funding Amount
$221,717.00
Summary
This project seeks to understand how cells within the developing embryo are produced and how they are given a specific identity. These processes often require the cell to make a decision about what type of cell it will become. We are using the Delta3 gene, which is present in humans and in the mouse, as a tool for our investigations. Delta3 is expressed at the surface of the cell and Notch (its receptor) is present on the surface of neighbouring cells. Delta3 on one cell will bind to Notch on th ....This project seeks to understand how cells within the developing embryo are produced and how they are given a specific identity. These processes often require the cell to make a decision about what type of cell it will become. We are using the Delta3 gene, which is present in humans and in the mouse, as a tool for our investigations. Delta3 is expressed at the surface of the cell and Notch (its receptor) is present on the surface of neighbouring cells. Delta3 on one cell will bind to Notch on the neighbouring cell and activates Notch. When Notch is activated in a cell it pushes the cell to make its decision. This project aims to determine what exactly is the function of Delta3 in mammals and how at the level of the individual cell this protein exerts its effects. We have generated a mouse in which the Delta3 gene is no longer active and have observed that embryos do not develop normally. We will explore these defects (which affect the skeleton and the brain) in detail in order to define their origins. We will also use these abnormal mice to identify genes, which require the function of Delta3 for their normal activity. It is not only important to define the function of Delta3 in mammals but also to determine this protein functions. We wish to know how exactly Delta3 interacts with Notch. That is, which part of the Delta3 protein binds to which part of the Notch protein. We can address this by modifying the Delta3 protein in small (but revealing ways) and see if it can still bind the Notch receptor in a cell culture assay. Our studies have relevance to humans because recently it has been shown that Delta and Notch are associated with a human syndrome (spondylocostal dysostosis) in which individuals suffer from abnormal skeletons.Read moreRead less
Identifying Strategies To Improve Perinatal Outcomes After Assisted Conception
Funder
National Health and Medical Research Council
Funding Amount
$724,799.00
Summary
Around 20% of young women express concern with being able to conceive, 16% experience clinical infertility, and ~8% use invasive therapies for which there can be limited safety data. We, and others, have reported adverse events for mother and child after infertility treatment, including neonatal death and birth defects. This project will provide urgently needed, robust evidence to guide patient and clinical decision making so as to optimise health of mother and baby.
Molecular Basis Of Transgenerational Epigenetic Inheritance In Mammals
Funder
National Health and Medical Research Council
Funding Amount
$477,965.00
Summary
While it has long been recognised that it is not just DNA, but chromosomes, that are passed from the gametes to the embryo, the non-DNA component was thought to carry no information with respect to the offspring's ultimate phenotype. However, there is now evidence that the non-DNA component, the epigenetic component, can play a role in the inheritance of phenotype in mammals. This study will attempt to determine the molecular nature of this phenomenon.
Improving Respiratory Transition And Outcomes Of Newborn Infants
Funder
National Health and Medical Research Council
Funding Amount
$262,251.00
Summary
Effective mask ventilation is the most important intervention at birth that can reduce mortality and disability in term and preterm infants. I will develop strategies to help clinicians improve their resuscitation skills. I will also study new ways to better support babies’ transition after birth, to improve their short and long term outcomes. The results of this research will change the way newly born babies are cared for around the world.
Evaluating Recently Introduced Prevention Strategies And Investigating Further Aetiologies Of Cerebral Palsy
Funder
National Health and Medical Research Council
Funding Amount
$314,644.00
Summary
Cerebral palsy is an early brain injury that affects movement. Every year in Australia, this life long condition will be identified in another 600 infants. This Early Career Fellowship will train an Australian researcher to evaluate promising prevention strategies that could reduce the overall incidence of cerebral palsy for the first time. The researcher will also investigate other causes of cerebral palsy including birth defects that occur very early in pregnancy.
Defining The Role Of IGF-1 As A Novel Angiocrine Factor In The Development And Treament Of Common Craniofacial Disorders
Funder
National Health and Medical Research Council
Funding Amount
$573,848.00
Summary
1 in 1000 children are born with a small jaw, which requires invasive surgery for treatment. We identified that defects in blood vessel development in the jaw underlie some cases of these craniofacial defects. We found that factors secreted from the major artery in the jaw can promote jaw growth, and our research proposal aims to identify what exactly these factors are. These factors have the potential to be used to therapeutically treat children with a small jaw to help it grow correctly.
Tuberous Sclerosis And Epilepsy: Using Resected Tissue To Understand Pathogenesis And Inform Management
Funder
National Health and Medical Research Council
Funding Amount
$339,261.00
Summary
Epilepsy is the commonest neurological disorder in childhood and seizures cannot be fully controlled by medications in 30%, often leading to developmental consequences. A major cause of drug-resistant epilepsy is a malformation of the brain’s surface. Surgery is sometimes used to remove these lesions to treat the epilepsy. We will study this tissue to understand its architecture, genetic basis and how it causes seizures. Our results will guide treatment including the best surgical approach.
Functional Screening Of Novel Genes In Craniofacial Development
Funder
National Health and Medical Research Council
Funding Amount
$540,075.00
Summary
Our faces are central to our ability to communicate, feed, breath and interact with each other. Birth defects that impact on the normal development of the face are common and affect not only the child but have a dramatic impact on the child's family as well. The genetic causes of most facial birth defects are unknown. This project will develop a method for determining how development of the face is controlled and will help identify genes that are responsible for facial birth defects.