The Effect Of Loading On The Size, Shape And Strength Of Cortical Bone During Different Stages Of Maturation
Funder
National Health and Medical Research Council
Funding Amount
$180,000.00
Summary
Osteoporosis is a condition in which the skeleton becomes fragile and susceptible to fractures. It is a public health problem that affects both men and women over the age of sixty. Although osteoporosis affects the elderly, the most opportune time to prevent osteoporosis may be during childhood. Physical activity is a lifestyle factor known to affect the strength of the skeleton. Bone density is commonly used as a measure of bone strength because it is easily measured and is related to the break ....Osteoporosis is a condition in which the skeleton becomes fragile and susceptible to fractures. It is a public health problem that affects both men and women over the age of sixty. Although osteoporosis affects the elderly, the most opportune time to prevent osteoporosis may be during childhood. Physical activity is a lifestyle factor known to affect the strength of the skeleton. Bone density is commonly used as a measure of bone strength because it is easily measured and is related to the breaking strength of bones. However changes in the shape of bones can also affect bone strength with or without an increase in bone density. Changes in bone shape in response to exercise in children or adults have rarely been investigated, and little is known about the effects of exercise on bone shape during different stages of growth. This study is the first to investigate how exercise during childhood may affect bone strength by changing bone shape. 45 elite female tennis players aged between 6 to 18 years have completed two years of this study. 90 novice and competitive male tennis players aged between 6 to 20 years and 60 healthy age matched controls will be asked to participate in this study. Measurements will be made annually for three years. The bone shape and density of the dominant and non-dominant arms of the players will be compared with the children who don't play tennis - comparisons will also be made between i) different stages of puberty and ii) girls and boys. The findings of this study are important because the lifestyle of children today may predispose them to a greater risk of osteoporosis late in life. Physical activity may be the most important modifiable protective factor against fragile bones in old age. The findings of this study will be the first to provide insight into whether there is a unique time during growth when exercise will result in the greatest increase in bone strength by changing bone shape.Read moreRead less
Reversal Of Diabetes In Pigs Using Liver-directed Gene Therapy
Funder
National Health and Medical Research Council
Funding Amount
$573,807.00
Summary
Type I diabetes mellitus is caused by the autoimmune destruction of the beta cells of the pancreas that secrete insulin. We have shown that we can cure diabetes in spontaneously diabetic mice by delivery of the insulin gene to the liver using a non-pathogenic viral delivery system. The study aims to repeat this work in pigs which have similar physiology to humans. If successful this would be proof-of-principle that we could theoretically control blood glucose levels in humans.
Neuroendocrine Functions Of PrRP, A Novel Hypothalamic Peptide
Funder
National Health and Medical Research Council
Funding Amount
$183,928.00
Summary
This project investigates the role of a newly discovered chemical (peptide) that is found in a part of the brain called the hypothalamus which regulates the activity of the pituitary gland. The hypothalamus and pituitary gland work together to control many of the body?s essential processes such as growth, metabolism and reproduction. Some human diseases are caused by abnormalities of the hypothalamus and pituitary gland while many other diseases affect the functions of these glands, leading to w ....This project investigates the role of a newly discovered chemical (peptide) that is found in a part of the brain called the hypothalamus which regulates the activity of the pituitary gland. The hypothalamus and pituitary gland work together to control many of the body?s essential processes such as growth, metabolism and reproduction. Some human diseases are caused by abnormalities of the hypothalamus and pituitary gland while many other diseases affect the functions of these glands, leading to widespread complications such as weight loss, wasting, abnormal immune responses, infertility or failure of lactation. While many of the hormones and chemicals of the hypothalamus and pituitary gland have been extensively studied, recent advances in molecular biology have led to the discovery of new chemicals that may have important regulatory functions. One of these newly discovered substances which was named Prolactin-Releasing Peptide or PrRP is the topic of this project. PrRP will be tested in a series of experiments in animals in order to determine how important it is in regulating the pituitary gland, particularly in stress and during lactation which are conditions when PrRP could be secreted. It is hoped that this research will lead to a more detailed understanding of how the reproductive and endocrine system are controlled in humans and to new methods for the manipulation of these systems under normal and disease conditions.Read moreRead less
Epidermal Growth Control In Psoriasis And Normal Skin
Funder
National Health and Medical Research Council
Funding Amount
$451,980.00
Summary
Our skin protects us from damage, dehydration, infection and harmful UV radiation. At the same time, we expect it to remain healthy, smooth and looking good. How the skin, and more particularly its upper layer, the epidermis, adapts to all these requirements is a complex problem yet to be fully understood. This question forms the basis of our project proposal. The epidermis is a continuously self-renewing tissue, in which cells have an average life of 30 days before they are invisibly shed to th ....Our skin protects us from damage, dehydration, infection and harmful UV radiation. At the same time, we expect it to remain healthy, smooth and looking good. How the skin, and more particularly its upper layer, the epidermis, adapts to all these requirements is a complex problem yet to be fully understood. This question forms the basis of our project proposal. The epidermis is a continuously self-renewing tissue, in which cells have an average life of 30 days before they are invisibly shed to the outside. In normal states and when responding to injury or disease, this cell turnover speed can be finely tuned, for example accelerated in the case of a healing wound. In contrast, if damaged by the sun, epidermal cells undergo a form of cell suicide (apoptosis) to prevent tumours forming from cells with damaged genes. This changing turnover speed is controlled by a series of growth factors, or cytokines. Insulin-like growth factor-I (IGF-I) is a unique cytokine that can control both cell turnover rate, and cell death. We aim to uncover the complex biochemical interactions that allow the epidermal IGF-I system to achieve this seemingly contradictory task. This study is important because when the epidermis loses the ability to finely tune its turnover speed, ulcers, sun damage, the common skin disorder psoriasis, or worse still, skin tumours, arise. This project explores ways of manipulating the IGF-I system to prevent this, and builds on some technology developed by the research group that has already proven effective in the control of psoriasis. The project also promises to discover undiscovered growth regulators that could be used in new gene therapies for skin overgrowth diseases.Read moreRead less
Regulation And Effect Of The Growth Hormone, IGF-I, And IGF-Binding Protein Response To Acute Exercise
Funder
National Health and Medical Research Council
Funding Amount
$367,197.00
Summary
The body's ability to respond to physiological stress is vital to survival. This series of studies aims to examine the hormonal responses to physical exercise. In studies recently completed to determine how to detect Growth Hormone (GH) abuse in the Olympics, we have discovered a new system of hormones that respond to exercise. These Insulin-like Growth Factors (IGF) and their IGF-Binding Proteins (IGF-BP) are normally controlled by GH. The IGF-IGF-BP system normally acts to control of many cell ....The body's ability to respond to physiological stress is vital to survival. This series of studies aims to examine the hormonal responses to physical exercise. In studies recently completed to determine how to detect Growth Hormone (GH) abuse in the Olympics, we have discovered a new system of hormones that respond to exercise. These Insulin-like Growth Factors (IGF) and their IGF-Binding Proteins (IGF-BP) are normally controlled by GH. The IGF-IGF-BP system normally acts to control of many cellular and organ functions in many different tissues of the body. For example they stimulate protein accumulation and muscle growth, and have actions to control blood glucose in conditions like diabetes. Little is known about what regulates the production of the IGF and IGF-BPs in response to physical exercise. We aim to examine whether GH, either as an acute pulse as occurs naturally, or a direct effect of exercise that is not GH-mediated, is responsible for the increase in IGF and IGFBPs. This may uncover a new means of controlling this powerful hormonal system. In addition, we will examine whether GH or IGF-I, alone and together, influence the body's ability to respond to the stress of exercise (e.g., controlling fuel use, cardiovascular and kidney responses). Such information will allow greater understanding of this important hormonal system, so that in novel therapies may be developed for conditions such as normal ageing, the wasting states that accompany severe surgical or infectious stress, or conditions with abnormal blood glucose regulation such as diabetes. In addition, this information will permit greater sophistication in the detection of GH and related compounds in elite athletes. Unfortunately, GH is also being abused by non-elite athletes and high-school children. We believe our efforts will asist in the detection and prevention of these more general societal health issues.Read moreRead less
Mechanisms Of Hypoglycaemic Damage In Developing Brain- A Protective Role For The Insulin-like Growth Factor System
Funder
National Health and Medical Research Council
Funding Amount
$408,055.00
Summary
The developing brain in the newborn infant or young child is vulnerable to many damaging influences. It is highly dependent on its essential fuel, glucose. Hypoglycemia, or lack of glucose availability, is therefore among the most damaging insults to the young brain, potentially leading to learning difficulties, developmental delay, cerebral palsy or epilepsy. Babies born premature or very small are at risk, as are those exposed to excessive insulin, such as infants of diabetic mothers. Children ....The developing brain in the newborn infant or young child is vulnerable to many damaging influences. It is highly dependent on its essential fuel, glucose. Hypoglycemia, or lack of glucose availability, is therefore among the most damaging insults to the young brain, potentially leading to learning difficulties, developmental delay, cerebral palsy or epilepsy. Babies born premature or very small are at risk, as are those exposed to excessive insulin, such as infants of diabetic mothers. Children with diabetes are also at risk, when their therapy with insulin may at times be excessive, leading to hypoglycaemia and impaired glucose availability for the brain. This proposal is examining at the cellular level the mechanisms involved in loss of brain cells in the face of glucose starvation in these various conditions. We are using several in vitro models where we can grow segments of developing mouse brain or human nerve cells in a dish, compared to studies with mice subjected to low blood glucose (hypoglycemia). After establishing that our laboratory models are representative of the whole animal, we will explore the cellular mechanisms involved in neuronal death following hypoglycaemia, particularly the interaction between the insulin-like growth factor (IGF) and other cell survival genes. We will also examine the possibility that treatment with IGF will reduce the loss of nerves in the brain after an episode of hypoglycemia. This may offer new and effective early treatment for this damaging brain injury in both newborn babies and children with insulin-dependent diabetes.Read moreRead less