'Multi-Coloured' Tracers for Magnetic Particle Imaging . Magnetic Particle Imaging (MPI) is predicted to be the future of imaging and will outperform all current imaging techniques by having 'colours', improved resolution and 3D precision. This project aims to create 'multi-coloured' high-performance MPI tracers by synthesising a range of the most effective magnetic nanoparticle structures. The expected outcome is the fundamental understanding of the relationships between nanoparticle structures ....'Multi-Coloured' Tracers for Magnetic Particle Imaging . Magnetic Particle Imaging (MPI) is predicted to be the future of imaging and will outperform all current imaging techniques by having 'colours', improved resolution and 3D precision. This project aims to create 'multi-coloured' high-performance MPI tracers by synthesising a range of the most effective magnetic nanoparticle structures. The expected outcome is the fundamental understanding of the relationships between nanoparticle structures and their magnetic properties for the formation of MPI signals with distinct ‘colours’. The benefits will be a library of MPI tracers that are able to provide ‘coloured’, high intensity, precise signals beyond what can be achieved with other imaging technologies.Read moreRead less
In-situ Scanning Probe Microscopy of biological redox processes: nanoscale structure and morphology. The science behind this project underpins the development of nanobiotechnology. Immediate applications foreseen, are the development of biosensors and diagnostic devices based on our intimate knowledge of the nature of the protein attachment to a surface. Use of synthetic membranes to create biomimetic surfaces will impact significantly on our understanding of the role and contribution membranes ....In-situ Scanning Probe Microscopy of biological redox processes: nanoscale structure and morphology. The science behind this project underpins the development of nanobiotechnology. Immediate applications foreseen, are the development of biosensors and diagnostic devices based on our intimate knowledge of the nature of the protein attachment to a surface. Use of synthetic membranes to create biomimetic surfaces will impact significantly on our understanding of the role and contribution membranes have on protein structure, function hence disease.Read moreRead less
Making Silicon Even More Useful: Functionalising Silicon to Produce Stable Electronic Devices in Aqueous Environments. Silicon is the wonder material of our time, being the foundation upon which our electronics and device industries are based. Silicon however would be even more useful if it could be stabilised so the surface did not oxidise in air and water. If this oxidation could be prevented silicon could be used in a whole range of new devices related to biotechnology, molecular electronics ....Making Silicon Even More Useful: Functionalising Silicon to Produce Stable Electronic Devices in Aqueous Environments. Silicon is the wonder material of our time, being the foundation upon which our electronics and device industries are based. Silicon however would be even more useful if it could be stabilised so the surface did not oxidise in air and water. If this oxidation could be prevented silicon could be used in a whole range of new devices related to biotechnology, molecular electronics and sensing. The project will develop a viable surface chemistry strategy for achieving this stabilisation and hence will greatly expand the scope of devices which can be fabricated from silicon. This will have significant scientific and economic benefits for Australia. We will exploit this new capability for cancer detection, cell engineering and biosensing.Read moreRead less
A Generic Solution for Interfacing Electrodes with Biological Media. Electrodes are the critical element of stimulating implantable devices such as cardiac pacemakers, bionic eyes and cochlear implants, the most commercially successful biosensors, and are emerging as key to new technologies for testing new drug leads using cells. In all these applications of electrodes in biology there has never been a solution to stopping unwanted adsorption of biological material onto the electrode that does ....A Generic Solution for Interfacing Electrodes with Biological Media. Electrodes are the critical element of stimulating implantable devices such as cardiac pacemakers, bionic eyes and cochlear implants, the most commercially successful biosensors, and are emerging as key to new technologies for testing new drug leads using cells. In all these applications of electrodes in biology there has never been a solution to stopping unwanted adsorption of biological material onto the electrode that does not dramatically decrease electrode performance. The proposed research finally provides a solution via surface modification. This strategy will enhance the performance of all the devices above and will open doors to new applications of electrochemistry within biology.Read moreRead less
Correlation between surface force and morphology of self-assembled monolayer. As a most potential solid support for biological molecules without denaturing their functions, gold thiol self-assembled monolayers (SAMs) have been studied extensively for surface fabrication. In this project we will prepare functional monolayers using newly synthesized thiol derivatives, evaluate correlation between surface force and surface morphology of the SAMs using the surface forces apparatus, and optimize the ....Correlation between surface force and morphology of self-assembled monolayer. As a most potential solid support for biological molecules without denaturing their functions, gold thiol self-assembled monolayers (SAMs) have been studied extensively for surface fabrication. In this project we will prepare functional monolayers using newly synthesized thiol derivatives, evaluate correlation between surface force and surface morphology of the SAMs using the surface forces apparatus, and optimize the condition to fabricate biological devices such as immune sensors.Read moreRead less
Biocompatible Ionic Liquids - Preserving Bioactive Structure and Function. A family of liquids recently discovered at Monash University has an ability to preserve bioactive molecules that represents a breakthrough in biotechnology. These new biocompatible ionic liquids will be investigated for applications in the treatment of diseases such as haemophilia. The ability of these liquids to stabilise a wide range of enzymes also opens up the potential of their use in a range of biosensors such as b ....Biocompatible Ionic Liquids - Preserving Bioactive Structure and Function. A family of liquids recently discovered at Monash University has an ability to preserve bioactive molecules that represents a breakthrough in biotechnology. These new biocompatible ionic liquids will be investigated for applications in the treatment of diseases such as haemophilia. The ability of these liquids to stabilise a wide range of enzymes also opens up the potential of their use in a range of biosensors such as blood glucose monitors for diabetes management. In collaborations with research groups worldwide, these materials will also be applied to the preservation of bioactivity in applications including cryopreservation of endangered species such as coral and in medical therapeutics. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775612
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Nanomaterials Optical Characterisation Facility. Nanotechnology is expected to revolutionize a wide variety of fields, from medicine to agriculture, communications and electronics. However, the small length scales involved present significant challenges with regard to characterising the nanomaterials produced. The Nanomaterials Optical Characterisation facility will provide state-of-the-art equipment for examining the properties of nanomaterials. The equipment will be pivotal in assisting the de ....Nanomaterials Optical Characterisation Facility. Nanotechnology is expected to revolutionize a wide variety of fields, from medicine to agriculture, communications and electronics. However, the small length scales involved present significant challenges with regard to characterising the nanomaterials produced. The Nanomaterials Optical Characterisation facility will provide state-of-the-art equipment for examining the properties of nanomaterials. The equipment will be pivotal in assisting the development of next-generation medicines, implants, optical devices and surface coatings, further strengthening Australia's formidable reputation in these areas.Read moreRead less
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
Molecular characterization of stem cell differentiation and oocyte maturation using synchrotron infrared spectroscopy and Atomic Force Microscopy/Raman imaging. There are currently no molecular based methods to assess oocyte maturation and stem cell differentiation at the single cell level. Consequently the need for such techniques is critical in placing Australia at the forefront in this rapidly expanding field. Such technology would give Australia a leading edge in stem cell and oocyte researc ....Molecular characterization of stem cell differentiation and oocyte maturation using synchrotron infrared spectroscopy and Atomic Force Microscopy/Raman imaging. There are currently no molecular based methods to assess oocyte maturation and stem cell differentiation at the single cell level. Consequently the need for such techniques is critical in placing Australia at the forefront in this rapidly expanding field. Such technology would give Australia a leading edge in stem cell and oocyte research and ultimately assist in discovering disease cures for debilitating neurodegenerative diseases and spinal chord injury, while techniques for determining the viability of oocytes may have important implications for future in vitro fertilization programs. The intellectual property and technologies developed from this research could also have potential to impact on the global market.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