Miniaturised biosensors with high selectivity . This project aims to develop a technological platform for the fabrication of miniaturised and flexible sensors that enable the quantitative detection of important bioactive compounds such as fatty acids and biogenic amines. By utilising multi-enzymatic reactions in solid phase and engineering task-specific inks, chemiresistive sensors will be printed seamlessly as a whole. The sensors will respond to complex target biomolecules via a series of enzy ....Miniaturised biosensors with high selectivity . This project aims to develop a technological platform for the fabrication of miniaturised and flexible sensors that enable the quantitative detection of important bioactive compounds such as fatty acids and biogenic amines. By utilising multi-enzymatic reactions in solid phase and engineering task-specific inks, chemiresistive sensors will be printed seamlessly as a whole. The sensors will respond to complex target biomolecules via a series of enzymatic reactions through which the analyte will convert to much simpler, reactive and hence measurable molecules. This project will enable to design miniaturised sensors for point-of-care detection of biomolecules that cannot be yet evaluated by the end users.Read moreRead less
Manipulation of Biological Particles Using Dielectrophoresis. Dielectrophoretic manipulation and separation of particles has numerous biological and medical applications, e.g. identification and characterisation of individual cells, purification of cell subpopulations from mixture suspensions, etc. This research project aims to develop a high-efficiency and low-cost DEP device for bio-particle manipulation. It will contribute significantly to the advancements in the field of biological Micro-Ele ....Manipulation of Biological Particles Using Dielectrophoresis. Dielectrophoretic manipulation and separation of particles has numerous biological and medical applications, e.g. identification and characterisation of individual cells, purification of cell subpopulations from mixture suspensions, etc. This research project aims to develop a high-efficiency and low-cost DEP device for bio-particle manipulation. It will contribute significantly to the advancements in the field of biological Micro-Electrical-Mechanical-Systems (MEMS) and nanotechnology. Industry will benefit from the expertise on micro/nano-structures and micro/nano-manufacturing achieved by this project.Read moreRead less
On-site environmental DNA sensing with user-friendly test strips. Organisms shed their genes into the environment. This project aims to develop world-first field-portable biosensors for this environmental DNA. Based on a novel sensing principle, they will offer performance comparable with current laboratory-based techniques. They will be rapid (< 1 h), cost -effective (< $ 1 per strip) and robust. Project outcomes will include tube-based tests able to detect 1 DNA copy / microlitre and ultraligh ....On-site environmental DNA sensing with user-friendly test strips. Organisms shed their genes into the environment. This project aims to develop world-first field-portable biosensors for this environmental DNA. Based on a novel sensing principle, they will offer performance comparable with current laboratory-based techniques. They will be rapid (< 1 h), cost -effective (< $ 1 per strip) and robust. Project outcomes will include tube-based tests able to detect 1 DNA copy / microlitre and ultralight paper test strips, both with naked-eye readout. Applications of these sensors in water testing will be developed with an Australian industry partner Biopoint. Benefits will include strengthened protection against invasive pests and the spread of antimicrobial resistance without lab testing and sample logistics.Read moreRead less
Transport phenomena in foam fractionation. Foam fractionation has a number of immediate applications in mineral and food processing but its most exciting potential is as low cost alternative for recovering and purifying high value biosurfactants. These are materials used to stabilise interfaces in living systems, and can be used as antibiotics and antiviral agents. The affinity for biosurfactants to collect at an interface suggests that foam fractionation is an ideal process to concentrate valua ....Transport phenomena in foam fractionation. Foam fractionation has a number of immediate applications in mineral and food processing but its most exciting potential is as low cost alternative for recovering and purifying high value biosurfactants. These are materials used to stabilise interfaces in living systems, and can be used as antibiotics and antiviral agents. The affinity for biosurfactants to collect at an interface suggests that foam fractionation is an ideal process to concentrate valuable products. Clearly, a cost-effective and reliable method of enriching streams of biosurfactants will make their use even more attractive and will engender the development of more novel biomaterials, such as pepfactants.Read moreRead less
Underlying mechanisms of e-waste bioleaching and hydropyrolysis. The project will develop a reclamation technology with an ecologically sustainable solution to e-waste management. Focusing on printed circuit boards, we will use our novel bioleaching and hydropyrolysis methods to process e-wastes, recover base and precious metals and reclaim energy. This will create safe working methods, high recycling efficiencies and generation of products from e-wastes.
New Surfaces for the Control of Endothelial Cell Function: Application in the Design of Biocompatible Stents. Using dewetting of thin polymer films, the present proposal will develop new structured biocompatible surfaces with controlled chemistry and topography, which will allow the growth of a normal (non-activated) monolayer of endothelial cells. Sophisticated molecular parameters will be used to assess that endothelial cells maintain their normal quiescent phenotype. The project sets the grou ....New Surfaces for the Control of Endothelial Cell Function: Application in the Design of Biocompatible Stents. Using dewetting of thin polymer films, the present proposal will develop new structured biocompatible surfaces with controlled chemistry and topography, which will allow the growth of a normal (non-activated) monolayer of endothelial cells. Sophisticated molecular parameters will be used to assess that endothelial cells maintain their normal quiescent phenotype. The project sets the ground work for the design of improved, more biocompatible structured stents to minimise the abnormal growth of cells on and around the stent, thereby reducing the occurrence of vascular complications. Thus this research could improve the success rate of stents implanted into patients with cardiovascular disease and reduce health costs.Read moreRead less
Quest for trace biomarkers in complex media through innovative nanoscale science of fluids, molecules, particles and light. This project will break new ground in the detection of rare molecules in biological samples by exploiting the interactions of fluids, molecules and particles confined in nanoscale channels. By revealing yet unknown biomarkers the project will bring a radical change in medical diagnostics and in the science and technology used to map the Human Proteome.
Contribution of Comammox Process to Sustainable Wastewater Treatment. This project aims to understand the versatility, activity and physiological features of comammox bacteria, the newly-discovered complete nitrifiers, in Australian wastewater treatment systems, and to model and evaluate their contributions to biological nitrogen removal process. Nitrogen transformations are crucial microbial processes in the wastewater treatment ecosystems, with nitrification largely responsible for ammonium ox ....Contribution of Comammox Process to Sustainable Wastewater Treatment. This project aims to understand the versatility, activity and physiological features of comammox bacteria, the newly-discovered complete nitrifiers, in Australian wastewater treatment systems, and to model and evaluate their contributions to biological nitrogen removal process. Nitrogen transformations are crucial microbial processes in the wastewater treatment ecosystems, with nitrification largely responsible for ammonium oxidation but comammox previously overlooked. The expected outcomes will develop new knowledge on the comammox process and provide novel insight and technological solution to refine strategies to manipulate nitrification processes for achieving improved biological nitrogen removal and sustainable wastewater management.Read moreRead less
Synthetic phenazines for enhanced biogas production from renewable and non-renewable resources. Methane (biogas) has a large role to play in meeting the energy needs of the human race globally whilst reducing greenhouse gas emissions. Microbial communities are responsible for biogas production from non-renewable (coal) and renewable (food waste) resources. This project seeks to: increase biogas yields by redirecting electron flow towards biogas producing microbes using electrochemically active p ....Synthetic phenazines for enhanced biogas production from renewable and non-renewable resources. Methane (biogas) has a large role to play in meeting the energy needs of the human race globally whilst reducing greenhouse gas emissions. Microbial communities are responsible for biogas production from non-renewable (coal) and renewable (food waste) resources. This project seeks to: increase biogas yields by redirecting electron flow towards biogas producing microbes using electrochemically active phenazines; understand the molecular mechanism by which phenazines increase biogas yields; and, assess the environmental consequence of phenazine application to coal seam gas production and anaerobic digestion of food waste. Phenazines are likely to emerge as a safe and cost-effective technology for improved biogas generation.Read moreRead less
Microfluidic device for microbial separation and concentration. This project will enhance Australia's capabilities and presence in the rapidly expanding field of chemical and biological analysis systems on a chip. We will develop and build handheld devices for microbial concentration that will facilitate earlier and easier detection of potentially pathogenic organisms in critical situations such as epidemiological crises or forensics. The portability and ease of operation of our integrated micro ....Microfluidic device for microbial separation and concentration. This project will enhance Australia's capabilities and presence in the rapidly expanding field of chemical and biological analysis systems on a chip. We will develop and build handheld devices for microbial concentration that will facilitate earlier and easier detection of potentially pathogenic organisms in critical situations such as epidemiological crises or forensics. The portability and ease of operation of our integrated microfluidic devices and their increased resilience to blockages make them ideal for use in remote areas and non-laboratory settings. Application areas will include disease detection, microbial contamination in food industries and water quality monitoring.Read moreRead less