GM-CSF Regulation Of Preimplantation Embryo Development
Funder
National Health and Medical Research Council
Funding Amount
$481,320.00
Summary
Treatment of infertility using IVF technology has been enormously successful. However, there are major concerns regarding the high incidence of multiple pregnancies (caused by the transfer of more than one embryo) and the potential adverse health outcome of adults conceived from this technology. Multiple pregnancies place both mother and infant at enormous risks, with increased obstetrics care, prematurity, increased neonatal care and neurological disorders such as cerebral palsy. This can be ov ....Treatment of infertility using IVF technology has been enormously successful. However, there are major concerns regarding the high incidence of multiple pregnancies (caused by the transfer of more than one embryo) and the potential adverse health outcome of adults conceived from this technology. Multiple pregnancies place both mother and infant at enormous risks, with increased obstetrics care, prematurity, increased neonatal care and neurological disorders such as cerebral palsy. This can be overcome simply by the transfer of a single embryo. However, patient and clinical expectations are that single embryo transfer should be achieved with little to no reduction in pregnancy rate, and currently this is not possible because our methods for culturing embryos are inadequate. Studies in animals suggest that laboratory growth of mammalian embryos can lead to small-for-gestational age babies (even when the effect of multiple births is taken into consideration). This backed by recent studies which agree that babies born from IVF are smaller than expected. This might lead to health problems in later life, as smallness at birth is associated with higher risks of cardiovascular disease and diabetes, especially as age progresses beyond 40 years. However, the oldest IVF child is currently 23 years of age. Previously we have shown that a protein growth factor, called granulocyte-macrophage colony-stimulating factor (GM-CSF), found normally in the reproductive tract, has dramatic beneficial effects on human and mouse embryos grown in the laboratory. Furthermore, we have shown in mice that embryo exposure to GM-CSF alleviates the detrimental side effects of in vitro culture on foetal growth and body structure after birth. Our research is now focussed on understanding why this protein is beneficial to embryo growth and to test if we can increase pregnancy rates and produce normal healthy infants from the transfer of single embryos treated with GM-CSF.Read moreRead less
Macrophages In Developmental Programming Of Reproductive Health
Funder
National Health and Medical Research Council
Funding Amount
$532,386.00
Summary
Programming of reproductive health in women begins long before sexual maturity. Development during childhood, puberty and adulthood produces a fully functional reproductive system capable of conceiving, gestating and nurturing a child. This project will investigate the role of immune cells known as macrophages in the reproductive system, and investigate how their disruption might influence developmental programming and have lifetime consequences for the reproductive health of the individual.
Therapeutic Potential Of Transforming Growth Factor-beta Proteins For The Diagnosis And Treatment Of Female Infertility
Funder
National Health and Medical Research Council
Funding Amount
$942,961.00
Summary
We discovered and manufactured a growth factor produced uniquely by the egg. We named this growth factor cumulin. It is a powerful regulator of ovarian function and egg quality. This project will study the basic mechanisms of how cumulin works in the ovary. We will then develop an assay to measure it as a biomarker of human egg quality and quantity. New approaches in fertility preservation for cancer survivors will be developed using cumulin.
Activation Of GDF9 Regulates Human Folliculogenesis
Funder
National Health and Medical Research Council
Funding Amount
$531,690.00
Summary
GDF9 is a key regulator of fertility in female mammals, as it controls the process of folliculogenesis. In this grant, we will demonstrate the importance of GDF9 in human folliculogenesis, determine the mechanisms that activate GDF9 and show why aberrant GDF9 activation leads to ovarian disorders. Collectively, the outcomes of this proposal will increase our understanding of the fundamental mechanisms that regulate ovarian folliculogenesis and provide new avenues to manipulate this process.
The Role Of Stem-progenitor Cells In Regeneration Of Mouse Endometrium.
Funder
National Health and Medical Research Council
Funding Amount
$311,938.00
Summary
The endometrium (lining of the uterus) undergoes breakdown and re-growth each month as part of the menstrual cycle. This restorative process is not well understood. For the first time stem cells have been identified within human endometrium that are likely to be responsible for its remarkable regeneration. The aim of this project is to identify stem cells within the mouse endometrium, to use as a model to understand how the endometrium restores each month after menstruation.