Development of novel therapies for the treatment of cancer. Both aging and obesity are significant risk factors for cancer and are becoming a burden on the health care budget. The proposed novel cancer therapy will improve current cancer treatments by enhancing their efficacy, thereby reducing the required dose and minimizing side effects. Such an outcome would not only benefit the well being of the individual but would achieve significant health care cost savings.
Dissecting the physiology of multipotent mesenchymal stromal cells to develop vaccine candidates for respiratory disease. The project aims to gain an understanding of how a type of adult stem cell inhibits immune responses that cause asthma. The project will produce new stem cell products and facilitate the design of a vaccine for asthma and other respiratory diseases, which would greatly reduce the burden of such conditions.
Biophysical identification of natural human antibody targets. A natural human antibody, PAT-SM6, isolated using technology developed by the partner organisation (Patrys), offers promise as a therapy to reduce mortalities due to cancer, the leading cause of death in Australia. The novelty of the approach pioneered by Patrys is the direct production of human antibodies which avoids undesirable side effects associated with the use of antibodies containing non-human components. This project is to ....Biophysical identification of natural human antibody targets. A natural human antibody, PAT-SM6, isolated using technology developed by the partner organisation (Patrys), offers promise as a therapy to reduce mortalities due to cancer, the leading cause of death in Australia. The novelty of the approach pioneered by Patrys is the direct production of human antibodies which avoids undesirable side effects associated with the use of antibodies containing non-human components. This project is to discover the specificity of PAT-SM6 for proteins and protein complexes and how these interactions lead to tumour cell death. This work will enhance the effectiveness of human antibody therapies and help in the development of this fast growing area within the biotechnology industry in Australia.Read moreRead less
Rational structure-based drug design of protein tyrosine kinase inhibitors. Protein tyrosine kinases (PTK) are a large, pivotal family of signalling molecules implicated in diseases such as cancer and immune-related disorders, that cause significant morbidity and mortality within the population. This research proposal aims to develop PTK-specific small molecule inhibitors to combat such diseases. Cytopia's drug discovery capability, coupled with the X-ray crystallographic expertise within Monas ....Rational structure-based drug design of protein tyrosine kinase inhibitors. Protein tyrosine kinases (PTK) are a large, pivotal family of signalling molecules implicated in diseases such as cancer and immune-related disorders, that cause significant morbidity and mortality within the population. This research proposal aims to develop PTK-specific small molecule inhibitors to combat such diseases. Cytopia's drug discovery capability, coupled with the X-ray crystallographic expertise within Monash University, will permit a rational, structure-based drug discovery platform to be established. The ultimate goal of this innovative and mutlidisciplinary approach, namely a portfolio of phase I therapeutics, will be of substantial benefit in the medical health area.Read moreRead less
Rational structure-based drug design of protein tyrosine kinase inhibitors. This research project is focussed on understanding the physiological roles of a group of enzymes within the cell, as well as developing therapeutics to combat significant diseases. It will achieve this by developing compounds to enzymes that are implicated in the disease process. The research project represents a continuation of a collaboration between academic researchers at Monash University, and an Australian biotec ....Rational structure-based drug design of protein tyrosine kinase inhibitors. This research project is focussed on understanding the physiological roles of a group of enzymes within the cell, as well as developing therapeutics to combat significant diseases. It will achieve this by developing compounds to enzymes that are implicated in the disease process. The research project represents a continuation of a collaboration between academic researchers at Monash University, and an Australian biotechnology company, Cytopia Ltd.Read moreRead less
Studies of the pi3-kinase enzyme family using selective inhibitors. The objective of this project is to study the function of the PI3-kinase enzyme family in blood platelets. To do this, inhibitors which block the action of specific family members, will be evaluated for their effects in assays of platelet function. The results will enhance our understanding of the way in which platelets and other cells respond to stimuli, and lead new approaches to designing novel drugs that block these response ....Studies of the pi3-kinase enzyme family using selective inhibitors. The objective of this project is to study the function of the PI3-kinase enzyme family in blood platelets. To do this, inhibitors which block the action of specific family members, will be evaluated for their effects in assays of platelet function. The results will enhance our understanding of the way in which platelets and other cells respond to stimuli, and lead new approaches to designing novel drugs that block these responses.Read moreRead less
Functional characterisation of neurons derived from embryonic stem cells and NS cells. The ability to obtain specific neurons from NS cells will revolutionise the study of nerve function, will allow the establishment of much-improved models for discovery of new drugs, and will define how enriched populations of neural cells can be obtained for applications in treatment of neurodegenerative diseases. The project will provide vital data for the emerging biotechnology industry associated will appl ....Functional characterisation of neurons derived from embryonic stem cells and NS cells. The ability to obtain specific neurons from NS cells will revolutionise the study of nerve function, will allow the establishment of much-improved models for discovery of new drugs, and will define how enriched populations of neural cells can be obtained for applications in treatment of neurodegenerative diseases. The project will provide vital data for the emerging biotechnology industry associated will applications of stem cell biology, and will stimulate clinical researchers to investigate the therapeutic potential of cell derived from NS cells.Read moreRead less
Switching the light on cartilage repair. Osteoarthritis is a leading cause of pain and disability in adults and affects 15 per cent of the Australian population. This project will develop a revolutionary new approach to treat joint disorders using smart materials and stem cells. The novel materials and techniques developed will help Australia maintain its leading edge in biotechnology.
Development of new systems for the commercial collection, processing and storage of adipose stem cells. This project is aimed at developing a standardised method to commercially extract and expand stem cells from adipose tissue. This product will then be available commercially as a therapeutic treatment.
Neurons isolated from embryonic stem cells as functional models for drug discovery. By using gene expression-based selection criteria embryonic stem cells can be driven to differentiate into specific neuronal lineages which show many of the morphological characteristics and immunocytochemical features of neurons in culture. There is, however, comparatively little evidence indicating that these stem cell-derived neurons actually behave as neurons. Our aim is to characterise and contrast four ne ....Neurons isolated from embryonic stem cells as functional models for drug discovery. By using gene expression-based selection criteria embryonic stem cells can be driven to differentiate into specific neuronal lineages which show many of the morphological characteristics and immunocytochemical features of neurons in culture. There is, however, comparatively little evidence indicating that these stem cell-derived neurons actually behave as neurons. Our aim is to characterise and contrast four neuronal cell cultures established with gene-based selection criteria. These cultures will be characterised by gene expression, immunocytochemistry, radiolabelled neurotransmitter release, electrophysiology and Ca2+ imaging studies. This study will highlight the functional effects of gene selection procedures upon stem cell-derived neurons.Read moreRead less