Nanopore sensors for multiplexed, ultra-fast gene detection. The aim of this research is to develop the application of protein nanopores for multiplex identification of DNA samples for ultrafast gene detection. This is a type of barcoding of organism DNA that allows for rapid gene identification. This technology aims to address a significant need for rapid, on-the-spot identification of organisms. Applications include rapid identification of pathogenic bacteria in infections and identification o ....Nanopore sensors for multiplexed, ultra-fast gene detection. The aim of this research is to develop the application of protein nanopores for multiplex identification of DNA samples for ultrafast gene detection. This is a type of barcoding of organism DNA that allows for rapid gene identification. This technology aims to address a significant need for rapid, on-the-spot identification of organisms. Applications include rapid identification of pathogenic bacteria in infections and identification of organisms in environmental sampling. Current methods are relative slow, require DNA amplification and specialised laboratories.
This proposal aims to fine tune the properties of the large nanopore, polyC9, with respect to size and charge, as well as to identify and characterise novel large nanopores. Read moreRead less
Bacterial detection and infection control using tethered membranes. This project will develop a rapid diagnostic tool to detect live bacteria, which will subsequently reduce risk of infection, increase efficiencies in patient care and hospital management, and produce savings in health care budgets. It also has the potential to save lives through addressing the serious and growing problem of antibiotic resistance.
Discovery Early Career Researcher Award - Grant ID: DE220100311
Funder
Australian Research Council
Funding Amount
$383,982.00
Summary
Shining nanoparticles for single microRNA detection in microfluidics. This project aims to extensively study the interface between nanoparticles and nucleic acids. It sets out to produce a novel ultrasensitive high-performance biosensing platform that will combine luminescent nanoparticles with microfluidics in a digital assay. This portable platform will detect biological fingerprints, or microRNAs, at a single-molecule level, delivering unprecedented levels of sensitivity and specificity. The ....Shining nanoparticles for single microRNA detection in microfluidics. This project aims to extensively study the interface between nanoparticles and nucleic acids. It sets out to produce a novel ultrasensitive high-performance biosensing platform that will combine luminescent nanoparticles with microfluidics in a digital assay. This portable platform will detect biological fingerprints, or microRNAs, at a single-molecule level, delivering unprecedented levels of sensitivity and specificity. The multiplexed platform has the potential to benefit the biomedical research of microRNAs and opens up a genuine commercialisation potential for portable biosensing of nucleic acids.Read moreRead less
Development of dense gas technology platforms for the formulation of oral vaccines. This project will aim to develop a technology platform that enables the formulation of vaccines that can be delivered orally and this research has the potential to radically change existing vaccination regimens. The availability of needle-free vaccination also has potential for considerable societal and economic impact in developing countries.
Each year more than one million people in the US alone suffer serious nerve injury significantly impairing quality of life and costing more than US$7 billion. This research will develop nerve conduits based on polymers and the natural constituents of nerve to provide an alternative to the current practice of nerve grafting. It is envisaged that this conduit will provide an effective platform for nerve repair and will expedite the development of regenerative platforms for other neural tissues.
Exploiting bacterial metal resistance machinery for metal ion nano-biosensors development. This project aims to integrate advanced materials chemistry, molecular biology, bio-electrochemical and synchrotron imaging approaches to understand the role of silver resistance machinery of bacteria in their ability to form silver nanoparticles. This aims to enable discovery of new metal-specific reductase enzymes. The fundamental biomolecular understanding of bacterial silver resistance will allow the u ....Exploiting bacterial metal resistance machinery for metal ion nano-biosensors development. This project aims to integrate advanced materials chemistry, molecular biology, bio-electrochemical and synchrotron imaging approaches to understand the role of silver resistance machinery of bacteria in their ability to form silver nanoparticles. This aims to enable discovery of new metal-specific reductase enzymes. The fundamental biomolecular understanding of bacterial silver resistance will allow the use of a silver-binding protein to develop a series of next-generation nano-biosensors. These biosensing platforms will provide high-throughput, cost-effective, selective, sensitive and continuous monitoring of heavy metal ions in effluents from mining and mineral processing industries in a real-time fashion.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100177
Funder
Australian Research Council
Funding Amount
$440,000.00
Summary
National Live Cell Scanning Platform for Nanoparticle Tracking. National live cell scanning platform for nanoparticle tracking: The aim of the project is to establish a multi-disciplinary, multi-user, self-correlated scanning facility to reach a new level of temporal and spatial precision for real-time tracking and quantification of biomolecules and nanoparticles within large populations of living cells. The facility will consist of a live-cell spinning-disc confocal microscope, a correlated bio ....National Live Cell Scanning Platform for Nanoparticle Tracking. National live cell scanning platform for nanoparticle tracking: The aim of the project is to establish a multi-disciplinary, multi-user, self-correlated scanning facility to reach a new level of temporal and spatial precision for real-time tracking and quantification of biomolecules and nanoparticles within large populations of living cells. The facility will consist of a live-cell spinning-disc confocal microscope, a correlated biological atomic force microscope, and remote access facilities. It is expected that with superior optical characterisation and mechanical manipulation, the automated orthogonal scanning facility will open new avenues to reveal unprecedented information from biological and pathological processes. The collaborative facility will support world-class researchers in the multi-disciplinary areas of physical, material and life sciences, placing Australia at the forefront of nanoscale biophotonics.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL220100185
Funder
Australian Research Council
Funding Amount
$3,269,608.00
Summary
Nanostructured Silicon-Based Wearable and Implantable Biosensors. The aim is to gain a deep understanding of the interface between nanostructured-silicon-based nanomaterials and biological systems, to develop a new generation of biosensor technologies applied on and in the body. Using innovative nanofabrication techniques, the team will integrate porous silicon nanomaterials with highly controllable optical and electrochemical properties into wearable and implantable biosensors for detecting bio ....Nanostructured Silicon-Based Wearable and Implantable Biosensors. The aim is to gain a deep understanding of the interface between nanostructured-silicon-based nanomaterials and biological systems, to develop a new generation of biosensor technologies applied on and in the body. Using innovative nanofabrication techniques, the team will integrate porous silicon nanomaterials with highly controllable optical and electrochemical properties into wearable and implantable biosensors for detecting bioanalytes directly and continuously in interstitial fluid, sweat, and blood; critically, they will be capable of long-term monitoring. The outcomes are expected to enable development of downstream applications across medical diagnostics, sports sciences, workplace testing as well as defence and space technologies.Read moreRead less
Precise, Cytosolic Dendrimer Delivery Systems. This project aims to use precisely targeted dendrimer technology to improve the delivery of poorly permeable molecules to their subcellular sites of action. Our cutting edge approach combines innovative phage screening techniques and advanced dendrimer synthesis. The outcomes of this proposal will be: 1) a targeting system that is manufacturable at scale and reasonable cost, 2) a dendrimer delivery system that is rapidly internalised into specifc ta ....Precise, Cytosolic Dendrimer Delivery Systems. This project aims to use precisely targeted dendrimer technology to improve the delivery of poorly permeable molecules to their subcellular sites of action. Our cutting edge approach combines innovative phage screening techniques and advanced dendrimer synthesis. The outcomes of this proposal will be: 1) a targeting system that is manufacturable at scale and reasonable cost, 2) a dendrimer delivery system that is rapidly internalised into specifc target cells and 3) bio-responsive dendrimers that promote delivery of their cargo into the cytosol. This work will strengthen a highly successful collaboration between the Australian biotech company Starpharma and Monash University, to design the next generation of nanomaterials delivery systems.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100321
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
Optical Metasurface for Single Small Extracellular Vesicle Analysis. This project aims to develop an innovative nanobiotechnology to study small extracellular vesicles (sEVs) – small biological particles that are important in intercellular communication. The technology will enable unprecedented depth of analysis and single particle resolution. It will generate new knowledge in both engineering and biological sciences by improving sEV image resolution and collecting information regarding the dist ....Optical Metasurface for Single Small Extracellular Vesicle Analysis. This project aims to develop an innovative nanobiotechnology to study small extracellular vesicles (sEVs) – small biological particles that are important in intercellular communication. The technology will enable unprecedented depth of analysis and single particle resolution. It will generate new knowledge in both engineering and biological sciences by improving sEV image resolution and collecting information regarding the distribution of different sEV subpopulations based on their protein phenotypes. Expected outcomes include a universal and ultrasensitive platform with many applications in analytical biochemistry such as disease diagnostics, environmental sciences, food safety and agriculture.Read moreRead less