Development And Pre-clinical Evaluation Of G-DSF Inhibitors For Inflammatory Joint Disease
Funder
National Health and Medical Research Council
Funding Amount
$88,329.00
Summary
G-CSF was originally identified as a cytokine regulating the production of neutrophils and haemopoietic stem cells from the bone marrow and it is currently used clinically for these properties in bone marrow transplant patients around the world. Anti-cytokine therapy with TNF blockade has recently been introduced for the treatment of rheumatoid arthritis. However, not all patients respond to TNF inhibition. We have gathered extensive data which shows that G-CSF also promotes inflammation in expe ....G-CSF was originally identified as a cytokine regulating the production of neutrophils and haemopoietic stem cells from the bone marrow and it is currently used clinically for these properties in bone marrow transplant patients around the world. Anti-cytokine therapy with TNF blockade has recently been introduced for the treatment of rheumatoid arthritis. However, not all patients respond to TNF inhibition. We have gathered extensive data which shows that G-CSF also promotes inflammation in experimental models of inflammatory joint disease. We propose to develop inhibitors of G-CSF as a novel form of anti-cytokine therapy for inflammatory joint disorders, such as rheumatoid arthritis.Read moreRead less
Prevention Of Neuron Death By Targeted Gene Delivery
Funder
National Health and Medical Research Council
Funding Amount
$195,691.00
Summary
Neurotrophic factors are potent proteins that have the ability to keep nerves alive. They have therefore been used in clinical trials to treat motor neuron disease, but without success. A major reason for this appears to be the way in which the neurotrophic factors are delivered. Direct injections into the blood stream are a convenient way of getting these large proteins into the bloodstream, but this is not their normal mode of action. These proteins are normally provided by cells adjacent to t ....Neurotrophic factors are potent proteins that have the ability to keep nerves alive. They have therefore been used in clinical trials to treat motor neuron disease, but without success. A major reason for this appears to be the way in which the neurotrophic factors are delivered. Direct injections into the blood stream are a convenient way of getting these large proteins into the bloodstream, but this is not their normal mode of action. These proteins are normally provided by cells adjacent to the nerves. We have designed a system that more closely resembles this physiological mode of action which involves the delivery of neurotrophic factor genes, via the bloodstream, to the affected nerves. Once inside the nerves the factors are produced on site and, following their secretion, act locally and directly on the injured nerves.Read moreRead less
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