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Novel Therapy For Enhancing Organ Maturation In Pre-term Babies
Funder
National Health and Medical Research Council
Funding Amount
$694,323.00
Summary
This project is developing a factor to enhance organ maturation and repair that may provide a new therapy for premature babies and fetuses with birth defects. This exciting new finding allows for the development of treatments of underdeveloped organs, in particular the lungs of premature and growth restricted babies. We are also trialing this factor in unborn babies with defects to the kidneys and lungs of which there is currently no cure.
Physical Determinants Of Lung Development Before And After Birth
Funder
National Health and Medical Research Council
Funding Amount
$442,500.00
Summary
Survival at birth is critically dependent upon the ability of the lungs to take on the role of exchanging gases; a role previously performed by the placenta. The lungs must, therefore, have grown and matured sufficiently during fetal life, before they are required at the time of birth. Inadequate development of the lungs during fetal life is the most common cause of death and disease in newborn babies. This may be due to premature birth, when the lungs have had insufficient time to develop, or i ....Survival at birth is critically dependent upon the ability of the lungs to take on the role of exchanging gases; a role previously performed by the placenta. The lungs must, therefore, have grown and matured sufficiently during fetal life, before they are required at the time of birth. Inadequate development of the lungs during fetal life is the most common cause of death and disease in newborn babies. This may be due to premature birth, when the lungs have had insufficient time to develop, or it may be due to inappropriate lung development during fetal life. It is important therefore, to understand the mechanisms that control growth and development of the lung both before and after birth. During fetal life the lungs are filled with liquid which expands the lungs and provides a stretch stimulus causing them to grow. Previously we have shown that a reduction in the degree of fetal lung expansion causes lung growth to cease. Likewise, if we increase the degree of lung expansion in the fetus, we induce a rapid increase in fetal lung growth and maturation. This stimulus is so potent that it can reverse an existing lung growth deficit, thus enabling survival of the newborn. In this application we will investigate the mechanisms by which alterations in lung expansion induce growth and maturation of the lung. Specifically we will investigate the role of calmodulin in fetal lung growth, because the genes that encode it are activated when the lung cells are growing most rapidly. In addition, we will identify other genes that are turned on or off during rapid growth of the lung because those genes are likely to play important roles in the regulation of fetal lung growth and development. We will also investigate the underlying differences in the control of lung growth at different stages of gestation, as well as investigate factors that regulate lung growth after birth, particularly in prematurely born animals.Read moreRead less
Alveolar Epithelial Cell Differentiation And Apoptosis: Effects Of Preterm Birth, Corticosteroids And Stretch.
Funder
National Health and Medical Research Council
Funding Amount
$484,500.00
Summary
In the lung, gas exchange takes place in small terminal airsacs called alveoli. The internal surface of the alveoli are lined with 2 types of specialist cells, the type-I and type-II cells. Both cells are essential for the normal functioning of the lung; type-I cells provide a thin barrier for the gas exchange, whereas type-II cells produce the surface-active material, surfactant. In order to survive after birth, the lungs of the newborn must have appropriate numbers of each of these cell types. ....In the lung, gas exchange takes place in small terminal airsacs called alveoli. The internal surface of the alveoli are lined with 2 types of specialist cells, the type-I and type-II cells. Both cells are essential for the normal functioning of the lung; type-I cells provide a thin barrier for the gas exchange, whereas type-II cells produce the surface-active material, surfactant. In order to survive after birth, the lungs of the newborn must have appropriate numbers of each of these cell types. However, babies that are born very prematurely have few, if any, mature cells as most are non-specialised cells that possess none of the characteristics of mature type-I and type-II cells. Therefore, the lungs of very preterm babies have low levels of surfactant, are prone to injury and infection and are not efficient in the exchange of oxygen and carbon dioxide. As such, these infants are at high risk of developing chronic lung disease which is a serious debilitating disease that has long term health implications. We believe that the non-specialised cells are more prone to injury and cell death than mature cells which makes the very premature infant more susceptible to the development of chronic lung disease. As the survival and respiratory health of these infants depends upon most type-I and type-II cells maturing after birth, it is critical to understand the factors that regulate their maturation. This information will allow the development of treatments that can enhance the maturation of these cell types. This application is focused towards understanding the factors that control maturation of type-I and type-II cells, as well as the role of the non-specialised cells in the development of chronic lung disease in babies that are born very prematurely.Read moreRead less
Understanding And Preventing Adverse Developmental Effects Of Perinatal Infection/inflammation
Funder
National Health and Medical Research Council
Funding Amount
$621,458.00
Summary
Exposure of babies to infection or inflammation within the womb is common and is associated with preterm delivery and illness in newborns. The biggest problem for these babies is lung disease due to inflammation of the lungs before birth and/or in response to lung injury after birth. We are investigating how inflammation alters lung development, and working on developing a novel cell therapy to prevent life-threatening newborn lung disease.
MECHANISMS OF ABNORMAL EXPRESSION OF THE IGF2 GENE IN DISORDERS AFFECTING FOETAL GROWTH
Funder
National Health and Medical Research Council
Funding Amount
$560,434.00
Summary
The IGF2 gene is crucial for foetal growth. Only the copy inherited from the father is active, a phenomenon named parental imprinting. In some children with foetal overgrowth or growth retardation, the deregulation of imprinting of the IGF2 gene during the first days of foetal development will influence subsequent growth and will also have major implications in post-natal and adult life. We will investigate the mechanisms resulting in abnormal imprinting of the IGF2 early in development.
Differential Effects On Fetal Growth And Development Of Repeated Fetal Or Maternal Corticosteroid Treatments
Funder
National Health and Medical Research Council
Funding Amount
$356,849.00
Summary
Injections of synthetic hormones (corticosteroids) to women at risk of early preterm birth reduce the rate of respiratory illness and death in the newborn infant. It is standard clinical practice prior to early preterm birth to give corticosteroids by intramuscular injection to the mother. For many women, however, preterm birth does not occur as expected and it has become common practice to give repeated courses of corticosteroids to women in whom the risk of preterm delivery recurs or continues ....Injections of synthetic hormones (corticosteroids) to women at risk of early preterm birth reduce the rate of respiratory illness and death in the newborn infant. It is standard clinical practice prior to early preterm birth to give corticosteroids by intramuscular injection to the mother. For many women, however, preterm birth does not occur as expected and it has become common practice to give repeated courses of corticosteroids to women in whom the risk of preterm delivery recurs or continues. Using the sheep model, we have shown that repeated doses of corticosteroids, given intramuscularly to the mother, are of benefit to newborn lung function, but also reduce the rate of fetal growth and adversely affect brain development. Evidence from the Western Australian Preterm Infant Cohort Study suggests that birthweight in humans is similarly affected by repeated corticosteroids and is followed by behavioral disorders in childhood. Using sheep, we have shown that repeated injections of corticosteroids given directly to the fetus cause no reduction in birthweight although maturation is still enhanced. This finding of a differential effect of corticosteroids by different routes of administration raises several exciting opportunities and questions. First is the possibility that direct fetal treatment may be of use in humans, if current human trials show that repeated doses cause effects similar to those we have seen in sheep. Secondly, the finding challenges our current understanding of how an individual may be programmed for subsequent health or illness by prenatal events. The proposed study will attempt to explain why corticosteroids given to the mother, but not the fetus, restrict fetal growth. Our hypothesis is that these hormones, when given repeatedly to the mother, adversely affect the ability of the placenta to transfer essential nutrients to the fetus. We will test this hypothesis using pregnant sheep in which catheters have been implanted surgically.Read moreRead less