DEVELOPMENT OF A NOVEL BIOMATERIAL FOR BONE TISSUE ENGINEERING. Tissue engineering of bone is emerging as a viable therapy for treating large defects in load-bearing bone. We wish to develop methods for combining novel heparan sulphate molecules (known to deliver growth factors to cell surfaces and thereby cause changes in bone cell phenotype) with load-bearing, macro-porous, biodegradable mineral/polymer biomaterials. Through the study of release profiles, protein adsorption and cell responses ....DEVELOPMENT OF A NOVEL BIOMATERIAL FOR BONE TISSUE ENGINEERING. Tissue engineering of bone is emerging as a viable therapy for treating large defects in load-bearing bone. We wish to develop methods for combining novel heparan sulphate molecules (known to deliver growth factors to cell surfaces and thereby cause changes in bone cell phenotype) with load-bearing, macro-porous, biodegradable mineral/polymer biomaterials. Through the study of release profiles, protein adsorption and cell responses to these derivatised biomaterials, a novel approach to bone replacement materials can be developed.Read moreRead less
The dynamics of turbulent entrainment in sheared convective boundary layers. This project aims to develop general laws to enable the accurate prediction of boundary layer entrainment processes. This will be significant in a wide range of environmental and engineering applications. In particular, the current lack of understanding of this area is a major source of uncertainty in the latest generation of global climate models.
Surface Chemistry meets Cell Biology: Molecular Level Control of Surface Architecture for Cell Adhesion and Migration. Biotechnological applications such as tissue engineering, bone supports, implantable materials, cell assays and biosensors all require detailed knowledge of how cells interact with their environment. The proposed research aims to provide this knowledge by developing unique modified surfaces to investigate white blood cell migration and adhesion. Additional expected outcome will ....Surface Chemistry meets Cell Biology: Molecular Level Control of Surface Architecture for Cell Adhesion and Migration. Biotechnological applications such as tissue engineering, bone supports, implantable materials, cell assays and biosensors all require detailed knowledge of how cells interact with their environment. The proposed research aims to provide this knowledge by developing unique modified surfaces to investigate white blood cell migration and adhesion. Additional expected outcome will contribute to our understanding of the many fundamental cellular processes such as cell growth, differentiation and cell death as well as the molecular basis of diseases such as inflammation, cancer, cardiovascular diseases and wound healing. This research program will establish Australia as a leading force in this new research field.Read moreRead less
Dynamic Force Microscopy of small molecular assemblies. The possibility of manipulating a single molecule seems at first unreal, indeed 5 years ago it was pure science fiction. Through the gaining popularity of the Atomic Force Microscope (AFM) many perspectives about the molecular world are changing. Macroscopic effects such as adhesion and lubrication are now discussed in light of measurements made with this instrument. Newer work includes the observation of single protein unfolding experim ....Dynamic Force Microscopy of small molecular assemblies. The possibility of manipulating a single molecule seems at first unreal, indeed 5 years ago it was pure science fiction. Through the gaining popularity of the Atomic Force Microscope (AFM) many perspectives about the molecular world are changing. Macroscopic effects such as adhesion and lubrication are now discussed in light of measurements made with this instrument. Newer work includes the observation of single protein unfolding experiments. The biophysics oriented project detailed in this application will extend the AFM: into multi-molecular systems formed by self-assembly, such as cell membranes; into polyelectrolyte-surface interactions; and, finally into the sequencing of DNA.Read moreRead less
Nanotherapeutics: nanoparticles with high specificity for the delivery and controlled release of drugs. This technology will deliver therapeutic drugs and/or MRI contrast agents to individual diseased cells with very high specificity and selectivity. The cells can be interogated to determine when they are "loaded" and the site of the "loaded" cells precisely determined. Drugs can be released photochemically. The administered dosage can be decreased with no loss of efficacy, and side effects re ....Nanotherapeutics: nanoparticles with high specificity for the delivery and controlled release of drugs. This technology will deliver therapeutic drugs and/or MRI contrast agents to individual diseased cells with very high specificity and selectivity. The cells can be interogated to determine when they are "loaded" and the site of the "loaded" cells precisely determined. Drugs can be released photochemically. The administered dosage can be decreased with no loss of efficacy, and side effects reduced. Read moreRead less
Links between bushfires in Victoria and floods in Queensland. This project will investigate connections between bushfires in Victoria and floods in Queensland under the framework that atmospheric blocking can be thought of as a common link. High resolution runs using the Intergovernmental Panel on Climate Change future projections of the energetics of high impact weather will improve climate forecasts in sensitive coastal areas of the country.
Biomagnification of the biotoxin BMAA in the environment. Using unique models and technics, the project aims to demonstrate that long-term exposure to the blue green algae toxin β-N-methylamino-l-alanine (BMAA) leads to uptake, accumulation and toxicity within the central nervous system. The risks for heath, mechanisms of contamination and toxicity of BMAA are very poorly understood. Algal blooms cost the Australian community more than $250 million each year and represent a major health issue fo ....Biomagnification of the biotoxin BMAA in the environment. Using unique models and technics, the project aims to demonstrate that long-term exposure to the blue green algae toxin β-N-methylamino-l-alanine (BMAA) leads to uptake, accumulation and toxicity within the central nervous system. The risks for heath, mechanisms of contamination and toxicity of BMAA are very poorly understood. Algal blooms cost the Australian community more than $250 million each year and represent a major health issue for human and fauna. This project aims to be the first to fully characterise BMAA mechanisms of contamination and neurotoxicity and to highlight the major environmental risk of exposure of human to BMAA. It also aims to develop new and unique detection and quantification tools for BMAA.Read moreRead less
The Southern Ocean boundary layer: winds, turbulence, sea spray and clouds. Both satellite products and climate models have large biases in the energy and water budgets over the Southern Ocean (SO). This is a direct consequence of a poor understanding of the structure and dynamics of the SO atmospheric boundary layer, which has arisen from an inability to make the necessary observations in this harsh environment. Due to the availability of new Australian research infrastructure, large steps forw ....The Southern Ocean boundary layer: winds, turbulence, sea spray and clouds. Both satellite products and climate models have large biases in the energy and water budgets over the Southern Ocean (SO). This is a direct consequence of a poor understanding of the structure and dynamics of the SO atmospheric boundary layer, which has arisen from an inability to make the necessary observations in this harsh environment. Due to the availability of new Australian research infrastructure, large steps forward are now possible with modest investment. This project will conduct and combine observations from the recently acquired marine vessel, RV Investigator, and the collocated airborne and surface observations to understand the structure and evolution of the unique, pristine SO boundary layer and to evaluate satellites and climate models.Read moreRead less
GBR as a significant source of climatically relevant aerosol particles. Every cloud drop is formed from a microscopic aerosol particle, known as a cloud condensation nuclei (CCN). In unpolluted environments the CCN particles originate from biogenic sources. Determining the magnitude and driving factors of biogenic aerosol production in different ecosystems is crucial to the development and improvement of climate models. This project aims to determine the mechanisms of new particle production fro ....GBR as a significant source of climatically relevant aerosol particles. Every cloud drop is formed from a microscopic aerosol particle, known as a cloud condensation nuclei (CCN). In unpolluted environments the CCN particles originate from biogenic sources. Determining the magnitude and driving factors of biogenic aerosol production in different ecosystems is crucial to the development and improvement of climate models. This project aims to determine the mechanisms of new particle production from one of the biggest ecosystems in Australia, the Great Barrier Reef. It is expected that the project will establish whether marine aerosol along the Queensland coast is coral-derived and show that this aerosol can affect the CCN concentration and therefore cloud formation and the hydrological cycle.Read moreRead less
New metal-molecule binding motifs for self-assembled monolayers and nanodevices. The goal of this research is to investigate technologically interesting electronic materials using new molecular assemblies. We explore their application in some fundamental components of molecular electronic systems and anticipate that knowledge gained from our investigations will have significant impact on the field of nanotechnology, especially in the area of molecular electronics. Our basic research will contrib ....New metal-molecule binding motifs for self-assembled monolayers and nanodevices. The goal of this research is to investigate technologically interesting electronic materials using new molecular assemblies. We explore their application in some fundamental components of molecular electronic systems and anticipate that knowledge gained from our investigations will have significant impact on the field of nanotechnology, especially in the area of molecular electronics. Our basic research will contribute to Australia's reputation as a source of innovative research and ideas in an area where there is growing international momentum.Read moreRead less