Multifunctional and Multimodal Theranostics: Manipulating Material Properties for Advanced Diagnostics. The utilisation of polymers in nanomedicine requires a bottom-up approach, where the fundamental chemistry is well-established and understood before it enables an application. This project develops branched polymers as new nanomaterials for theranostics; imaging modalities that “switch-on” when miRNA is released will quantify how much nanomaterial gets to a specific site, while a built-in sens ....Multifunctional and Multimodal Theranostics: Manipulating Material Properties for Advanced Diagnostics. The utilisation of polymers in nanomedicine requires a bottom-up approach, where the fundamental chemistry is well-established and understood before it enables an application. This project develops branched polymers as new nanomaterials for theranostics; imaging modalities that “switch-on” when miRNA is released will quantify how much nanomaterial gets to a specific site, while a built-in sensor based on physical changes in the nanomaterial will measure the onset and progression of necrosis. The aim is to develop a fundamental understanding of how polymer architecture and functionality can be utilised to drive device performance, providing a platform to probe new technology and methodologies for development of next generation theranostics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100488
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Cellular dynamics of nanoengineered particles. Nanotechnology has the capacity to drive a new wave of biological innovation through engineering materials at the nanoscale. This project will advance understanding of how nanoengineered materials interact with biological systems to enable the development of nanomaterials for future translational research.
Discovery Early Career Researcher Award - Grant ID: DE130100922
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Diamond cybernetics: nanocrystalline diamond for interfacing bionic devices with the human nervous system. Bionic devices will soon be used to treat disorders such as epilepsy, Parkinson's and depression. We will use diamond to create high resolution, permanent electrical connections between devices and the human nervous system. These diamond connections will preserve nerve health and make bionic devices more effective and able to last a lifetime.
Discovery Early Career Researcher Award - Grant ID: DE150101518
Funder
Australian Research Council
Funding Amount
$345,000.00
Summary
Cellular responses to nanoparticles from cells on micropatterned surfaces. The mechanisms underlying cell-nanoparticle interactions remain largely unknown. It has hampered the design and development of innovative nano devices to be used for drug delivery, biomarkers and diagnostics. This project aims to explore the influences of cell size, density, geometry, intercellular communication and substrate properties on cell-nanoparticle interactions. A micropatterning technology is applied to precisel ....Cellular responses to nanoparticles from cells on micropatterned surfaces. The mechanisms underlying cell-nanoparticle interactions remain largely unknown. It has hampered the design and development of innovative nano devices to be used for drug delivery, biomarkers and diagnostics. This project aims to explore the influences of cell size, density, geometry, intercellular communication and substrate properties on cell-nanoparticle interactions. A micropatterning technology is applied to precisely control cell behaviour and provide a novel in vitro cellular model for nanoparticle studies. This project aims to significantly improve the understanding of cell-nanoparticle interactions to provide new insight into nanoparticle design and improve the efficacy of nano devices.Read moreRead less
Microglia and the inflammation spectrum - not just good or bad. Cell-mediated tissue clearance following brain injury is a universal mechanism. However, our understanding of the cells that perform these tasks is very limited. Our project will characterise this inflammatory response at a single-cell level using the zebrafish spinal cord as a versatile experimental model. The project is expected to strongly contribute to the molecular understanding of the mechanisms underlying debris removal and w ....Microglia and the inflammation spectrum - not just good or bad. Cell-mediated tissue clearance following brain injury is a universal mechanism. However, our understanding of the cells that perform these tasks is very limited. Our project will characterise this inflammatory response at a single-cell level using the zebrafish spinal cord as a versatile experimental model. The project is expected to strongly contribute to the molecular understanding of the mechanisms underlying debris removal and will advance innovative technologies that facilitate intellectual progress in neuroscience. It will produce new insights into the process of neuronal degeneration, promote Australia’s growing reputation as a global leader in neuroscience, and provide high quality training for early career researchers.Read moreRead less
Synergistic nanostimulation of nerve cells using atomic force microscopy technology. The research will develop multifunctional nanoelectrodes for neural prosthetic devices of the future. They will be smaller and more effective, enabling integration with single neural networks in the body, to improve the clinical treatment of severe neurological disorders and loss of sensory (hearing and vision) and motor functions.
Short silk nanofibre based 3D scaffolds with enhanced biomimicry. This project aims to understand the behaviour of haematopoietic stem cells (HSC) in novel 3D scaffolds based on short silk nanofibres. This will lead to highly functional 3D scaffolding materials that support efficient HSC renewal in vitro. This project aims to overcome the key problem with existing in vitro systems, which lack the morphological and biochemical complexities of native HSC-niche. Since haematopoietic stem cells are ....Short silk nanofibre based 3D scaffolds with enhanced biomimicry. This project aims to understand the behaviour of haematopoietic stem cells (HSC) in novel 3D scaffolds based on short silk nanofibres. This will lead to highly functional 3D scaffolding materials that support efficient HSC renewal in vitro. This project aims to overcome the key problem with existing in vitro systems, which lack the morphological and biochemical complexities of native HSC-niche. Since haematopoietic stem cells are the precursors to all blood cells, this project has the potential of engineering a high yield artificial ‘blood factory’, which will help save the lives of many thousands of people who rely on bone marrow transplants to treat life-threatening illness such as leukaemia.Read moreRead less
Improved effectiveness of cochlear implants through new simultaneous stimulation techniques. Cochlear implants have brought the gift of hearing to 250,000 people worldwide and are an excellent example of Australian innovation. This project will examine an improved "high fidelity" stimulation strategy with the objective of defining a safe stimulus range for clinical use and providing a commercial advantage for Cochlear Ltd.
PET imaging of learning-related plasticity in awake behaving rats. The objective of the project is to combine an investigation of basic learning paradigms with functional Positron emission tomography (PET) imaging in rats in order to answer critical questions about the neurobiological basis of learning and decision-making in the brain. MicroPET technology provides PET images without the confounds induced by anaesthesia. Using this technology, the project intends to observe whole-brain changes in ....PET imaging of learning-related plasticity in awake behaving rats. The objective of the project is to combine an investigation of basic learning paradigms with functional Positron emission tomography (PET) imaging in rats in order to answer critical questions about the neurobiological basis of learning and decision-making in the brain. MicroPET technology provides PET images without the confounds induced by anaesthesia. Using this technology, the project intends to observe whole-brain changes in dopamine neurotransmission in awake, behaving rats while they learn to predict motivationally relevant outcomes based on environmental cues and on their own actions (ie during Pavlovian and instrumental conditioning, respectively). The outcomes of this research may improve our understanding of the neural changes responsible for debilitating disorders of the brain and mind.Read moreRead less
Towards a new understanding of the reproductive system. The proposed analysis of the reproductive system will provide important new knowledge of gene regulation driving organ development. The insights and technologies developed in this program will be widely applicable in biotechnological and pharmacogenomic research in Australia and worldwide, and assert Australia's leadership in this area of research.