Redefining tissue-specific endothelial cells through bioengineered matrices. This project aims to improve our understanding of the biological mechanisms that drive blood vessel formation and function. The endothelial cells that make up each blood vessel are inherently unique across different sites within the human body and this project expects to generate new knowledge regarding their organ specificity. Using advanced bioengineering approaches, this project will map human endothelial cell specif ....Redefining tissue-specific endothelial cells through bioengineered matrices. This project aims to improve our understanding of the biological mechanisms that drive blood vessel formation and function. The endothelial cells that make up each blood vessel are inherently unique across different sites within the human body and this project expects to generate new knowledge regarding their organ specificity. Using advanced bioengineering approaches, this project will map human endothelial cell specificity and develop state-of-the-art modelling technologies to improve knowledge of environmental influence on endothelial cell fate and function. This should provide a new framework to modulate the adaptive capacities of endothelial cells and can potentially enable more predictive and targeted drug efficacy and safety testing.Read moreRead less
Modular microfluidic platform for mimicking multi-organ system interactions. This project aims to develop a novel, modular microfluidic platform that overcomes current limitations of integrated systems in synchronising multi-tissue culture, imaging and operational complexity. Understanding multi-organ systemic crosstalk in human health and diseases demands dynamic culture systems that can mimic such interactions. This project will deliver a first-in-class platform technology and establish intern ....Modular microfluidic platform for mimicking multi-organ system interactions. This project aims to develop a novel, modular microfluidic platform that overcomes current limitations of integrated systems in synchronising multi-tissue culture, imaging and operational complexity. Understanding multi-organ systemic crosstalk in human health and diseases demands dynamic culture systems that can mimic such interactions. This project will deliver a first-in-class platform technology and establish international and disciplinary collaborations to develop different tissue and engineering modules relevant to applications in systemic nanotoxicology, drug bioactivation and chronic diseases. This will provide the cornerstone technology to develop a new generation of disease models and therapeutics targeting interaction dysfunctions.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100757
Funder
Australian Research Council
Funding Amount
$447,654.00
Summary
Engineering Tissue Organisation Using Intelligent Additive Biomanufacturing. This project aims to organize and shape the formation of lab-grown tissue by 3D printing structures which control the behaviour of cells. This cell behaviour control will be accomplished through an interdisciplinary and multiscale pipeline of additive micromanufacturing, bioreactor engineering, cell culture, single-cell imaging, and computational modelling. In contrast with current empirical approaches, this quantitativ ....Engineering Tissue Organisation Using Intelligent Additive Biomanufacturing. This project aims to organize and shape the formation of lab-grown tissue by 3D printing structures which control the behaviour of cells. This cell behaviour control will be accomplished through an interdisciplinary and multiscale pipeline of additive micromanufacturing, bioreactor engineering, cell culture, single-cell imaging, and computational modelling. In contrast with current empirical approaches, this quantitative and predictive understanding of how to control biological processes within 3D printed environments will design and engineer more robust, customisable, scalable, and economical cell culture platforms able to optimally manufacture bespoke and complex 3D tissues for future agricultural, pharmaceutical, or medical products.Read moreRead less
Bioelectronics: addressing the biointerface challenge. This project aims to develop bioelectronic materials with long operational stability in physiological conditions and enhanced electronic performance that will effectively interface with electroresponsive tissue. These new materials will be integrated into bioadhesives from which simple bioelectronics devices will be fabricated and assessed for their capability to modulate biosignals and to interact with tissue. Disruption in biosignals cause ....Bioelectronics: addressing the biointerface challenge. This project aims to develop bioelectronic materials with long operational stability in physiological conditions and enhanced electronic performance that will effectively interface with electroresponsive tissue. These new materials will be integrated into bioadhesives from which simple bioelectronics devices will be fabricated and assessed for their capability to modulate biosignals and to interact with tissue. Disruption in biosignals causes numerous medical conditions such as epilepsy and heart failure and the development of flexible and biocompatible medical electronics devices that interface with tissue is essential for regaining and modulating these signals.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101297
Funder
Australian Research Council
Funding Amount
$429,000.00
Summary
A novel, dictionary-free, multi-contrast MRI method for microscopic imaging. This project aims to develop a novel quantitative imaging technique for comprehensive in vitro and in vivo tissue characterisation on the microscopic scale. The technology innovated in the project could revolutionise microscopic imaging techniques by breaking through the sub-millimetre image resolution bottleneck of current magnetic resonance imaging (MRI) methods. This project expects to generate new knowledge in the e ....A novel, dictionary-free, multi-contrast MRI method for microscopic imaging. This project aims to develop a novel quantitative imaging technique for comprehensive in vitro and in vivo tissue characterisation on the microscopic scale. The technology innovated in the project could revolutionise microscopic imaging techniques by breaking through the sub-millimetre image resolution bottleneck of current magnetic resonance imaging (MRI) methods. This project expects to generate new knowledge in the emerging field of biological imaging and to deliver an integrated imaging platform for mapping various tissue microscopic components at the cellular level. Successful outcomes have the potential for commercialisation and will accelerate a range of fundamental science and engineering studies requiring imaging techniques.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100302
Funder
Australian Research Council
Funding Amount
$461,300.00
Summary
A long-lasting interface for communicating with the brain. This project aims to address the most urgent challenges in developing the next generation of implantable devices for communicating with the brain. Using a new type of carbon-based electrode, along with light therapy, this project expects to build innovative technologies that can greatly enhance the functionality and longevity of these devices. Expected outcomes include a novel tool that can be implemented to obtain detailed insights into ....A long-lasting interface for communicating with the brain. This project aims to address the most urgent challenges in developing the next generation of implantable devices for communicating with the brain. Using a new type of carbon-based electrode, along with light therapy, this project expects to build innovative technologies that can greatly enhance the functionality and longevity of these devices. Expected outcomes include a novel tool that can be implemented to obtain detailed insights into neural circuits, advancing our understanding of neural function and pioneering feedback and closed-loop neuroscience. This project should provide significant benefits in neuroscience research and the neural interface industry, both of which have the ultimate goal to unlock the mysteries of the brain.Read moreRead less
Multiplexed surface signals to inhibit mixed bacterial biofilm formation. This project aims to investigate a novel class of multifunctional surfaces that can be used to coat biomaterials with antimicrobial properties. This combines advanced polymer synthesis with a new colloidal particle self-assembly technique to modify surfaces. Expected project outcomes are generation of new knowledge of the molecular mechanisms of biofilm formation in complex microbial communities, which may facilitate futur ....Multiplexed surface signals to inhibit mixed bacterial biofilm formation. This project aims to investigate a novel class of multifunctional surfaces that can be used to coat biomaterials with antimicrobial properties. This combines advanced polymer synthesis with a new colloidal particle self-assembly technique to modify surfaces. Expected project outcomes are generation of new knowledge of the molecular mechanisms of biofilm formation in complex microbial communities, which may facilitate future research exploring the development of biomaterials that resist attachment of infectious microbes, which is desperately needed in many biomedical application areas. This can assist entrepreneurs and researchers in the medical technologies sector, allowing them to explore how to reduce infection rates on medical devices.Read moreRead less
Oscillations as a mechanism for neural communication. The project aims to answer how billions of cells in the brain can work together to allow us to perceive the world. By using novel electrophysiological and engineering techniques, the project tests if a brain signal called the local field potential provides a way for different areas in the brain to communicate. The hypothesis is that the local field potential is used by cells to synchronise their activity to be most effective. This project wou ....Oscillations as a mechanism for neural communication. The project aims to answer how billions of cells in the brain can work together to allow us to perceive the world. By using novel electrophysiological and engineering techniques, the project tests if a brain signal called the local field potential provides a way for different areas in the brain to communicate. The hypothesis is that the local field potential is used by cells to synchronise their activity to be most effective. This project would be a paradigm shift in how we currently understand how the brain works. Expected outcomes include answering long held questions about how we see and perceive the world. This should provide significant benefit to fields such as computer vision and the development of neural engineering devices.Read moreRead less
Engineering approaches towards atomic imaging of bacterial cells. This project aims to develop novel approaches for analysis of single biological cells at atomic scale. The project will first develop an approach by utilising nanoscale ion beam to interact with the frozen cells in a controllable manner, followed by performing nanoscale dissection and analyses. By introducing engineered two-dimensional materials, namely graphene, atomic resolution three-dimensional imaging of the cellular chemistr ....Engineering approaches towards atomic imaging of bacterial cells. This project aims to develop novel approaches for analysis of single biological cells at atomic scale. The project will first develop an approach by utilising nanoscale ion beam to interact with the frozen cells in a controllable manner, followed by performing nanoscale dissection and analyses. By introducing engineered two-dimensional materials, namely graphene, atomic resolution three-dimensional imaging of the cellular chemistry will become feasible, which will shed light on various fundamental mechanisms inside the cells. This will provide significant benefits upon success, and will impact a wide spectrum of fields from understanding cellular functions to developing effective drugs.Read moreRead less
Combined Terahertz Imaging and Optical Coherence Tomography. This project aims to exploit the synergies between terahertz imaging and optical coherence tomography. These novel imaging modalities will be combined into a single multi-modality technique which will have application in numerous industry sectors like manufacturing, non-destructive testing, pharmaceutical and medicine. The intended outcome of the project is to create an internationally leading position for Australia in cutting-edge res ....Combined Terahertz Imaging and Optical Coherence Tomography. This project aims to exploit the synergies between terahertz imaging and optical coherence tomography. These novel imaging modalities will be combined into a single multi-modality technique which will have application in numerous industry sectors like manufacturing, non-destructive testing, pharmaceutical and medicine. The intended outcome of the project is to create an internationally leading position for Australia in cutting-edge research in optical and terahertz imaging. This innovative, fundamental research will expand Australia’s research capacity in imaging with wide ranging applications. The anticipated goal of the project is to build a prototype imaging system with industry partners ready for the next step to commercialisation. Read moreRead less