Neurological cell replacement therapies: improving outcomes by matching developmental profiles of transplanted cells with the damaged brain area. Stem cell transplantation offers a way to replace nerve cells lost due to acute CNS injury or chronic degenerative conditions such as Parkinson's Disease. However, to date, results have been disappointing because of poor differentiation, survival and integration of stem cells confounded by ethical issues associated with the use of embryos as the source ....Neurological cell replacement therapies: improving outcomes by matching developmental profiles of transplanted cells with the damaged brain area. Stem cell transplantation offers a way to replace nerve cells lost due to acute CNS injury or chronic degenerative conditions such as Parkinson's Disease. However, to date, results have been disappointing because of poor differentiation, survival and integration of stem cells confounded by ethical issues associated with the use of embryos as the source of stem cells. The experiments conducted in this study will provide strategies to improve the efficacy of stem cell transplantation into the damaged CNS as well as developing the use of autologous bone marrow stem cells for repair. Outcomes will be improved transplant methodologies and expertise for the bio-technology industry. Read moreRead less
Using magnetic nanotechnology to aid recovery from neurotrauma. Nanotechnology is an exciting new field that holds great promise to solve challenging health issues including neurotrauma associated with brain and spinal cord injury. Current methods to deliver drugs and stimulate tissue repair after neurotrauma do not work effectively and new approaches are urgently need. The recently established research team brings together expertise in nanotechnology and neuroscience to develop new, safe ways t ....Using magnetic nanotechnology to aid recovery from neurotrauma. Nanotechnology is an exciting new field that holds great promise to solve challenging health issues including neurotrauma associated with brain and spinal cord injury. Current methods to deliver drugs and stimulate tissue repair after neurotrauma do not work effectively and new approaches are urgently need. The recently established research team brings together expertise in nanotechnology and neuroscience to develop new, safe ways to deliver drugs and stimulate tissue repair after neurotrauma, and provide quality research training. Specifically designed nanomaterials will deliver drugs slowly over time and act as scaffolds to stop cells dying and stimulate them to restore broken connections and work again. Read moreRead less
Targeted enzymatic treatment of the injured central nervous system using innovative nanotechnology. Nanotechnology and other frontier areas in science have exciting potential to solve major challenges of the 21st century, including health. The proposed research provides the real possibility of discovering ways to alleviate the many complex problems associated with neurotrauma following, for example, brain and spinal cord injury. Current delivery of therapeutics do not work effectively and new ap ....Targeted enzymatic treatment of the injured central nervous system using innovative nanotechnology. Nanotechnology and other frontier areas in science have exciting potential to solve major challenges of the 21st century, including health. The proposed research provides the real possibility of discovering ways to alleviate the many complex problems associated with neurotrauma following, for example, brain and spinal cord injury. Current delivery of therapeutics do not work effectively and new approaches are urgently needed. The recently established powerful multidisciplinary research team combines expertise in nanotechnology, glycobiology and neuroscience to develop novel, safe ways to deliver therapeutic enzymes over biological time-courses. We aim to make broken connections work again, while providing quality research training.Read moreRead less
A shared genetic basis for development of the nervous system and glands. Fruit flies possess strikingly similar versions of the genes that promote normal human development. The list of systems with genetic parallels between humans and fruit flies includes the respiratory and circulatory systems; cardiovascular development and disease; sleep; learning and memory; brain development and disease; taste, sight, smell and hearing. This project could add at least some human glands, the mucous-secreting ....A shared genetic basis for development of the nervous system and glands. Fruit flies possess strikingly similar versions of the genes that promote normal human development. The list of systems with genetic parallels between humans and fruit flies includes the respiratory and circulatory systems; cardiovascular development and disease; sleep; learning and memory; brain development and disease; taste, sight, smell and hearing. This project could add at least some human glands, the mucous-secreting goblet cells, to this list, providing a potentially useful model for studying human diseases associated with gland dysfunction. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668413
Funder
Australian Research Council
Funding Amount
$723,000.00
Summary
The Nanoscale Characterisation Centre WA Analytical Biological Transmission Electron Microscope Facility. A new regional analytical biological TEM (BioTEM) will provide critical support to acclaimed medical and biological groups researching nationally significant age-related health, agricultural and environmental questions. The BioTEM, for example, will allow a unique opportunity to detect metal uptake and accumulation in bone-forming cells. This research will provide insight into metal induce ....The Nanoscale Characterisation Centre WA Analytical Biological Transmission Electron Microscope Facility. A new regional analytical biological TEM (BioTEM) will provide critical support to acclaimed medical and biological groups researching nationally significant age-related health, agricultural and environmental questions. The BioTEM, for example, will allow a unique opportunity to detect metal uptake and accumulation in bone-forming cells. This research will provide insight into metal induced afflictions, such as nasal ulcer, lung cancer, contact dermatitis and hypersensitivity reactions like asthma. The BioTEM will also be used to study how plants take up nutrients and how they use these compounds for growth, development and reproduction. Successes in this research will transfer to the important development of salt-tolerant plant species.Read moreRead less