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
Nanoengineering materials to combat antimicrobial resistance. This project aims to understand how nanoengineered materials can be designed to kill bacteria and fungi without causing antimicrobial resistance. Resistance to antimicrobial drugs already leads to many thousands of deaths annually and costs society billions of dollars. Nanomaterials have unique abilities to attack microbes in multiple ways that could limit resistance. This project will engineer new antimicrobial nanomaterials tailored ....Nanoengineering materials to combat antimicrobial resistance. This project aims to understand how nanoengineered materials can be designed to kill bacteria and fungi without causing antimicrobial resistance. Resistance to antimicrobial drugs already leads to many thousands of deaths annually and costs society billions of dollars. Nanomaterials have unique abilities to attack microbes in multiple ways that could limit resistance. This project will engineer new antimicrobial nanomaterials tailored to selectively kill microbes with reduced likelihood of developing resistance by using synergies between inorganic nanoparticles and antimicrobial peptides. This technology could be used to prevent infections and biofilms on surfaces in a wide range of future applications, such as medical / veterinary devicesRead moreRead less
Orientated biointerfacing of cell-mimetic nanoparticles. The project aims to create next-generation cell-mimetic nanotechnology by providing in-depth understandings and precise control over cell membrane coating orientation of biomimetic nanoparticles. Our approach is to design and develop new synthetic and analytic strategies to construct and quantify orientated biointerfacing. This will generate new knowledge and patentable methodologies related to orientated biomimetic nanoparticles. Expected ....Orientated biointerfacing of cell-mimetic nanoparticles. The project aims to create next-generation cell-mimetic nanotechnology by providing in-depth understandings and precise control over cell membrane coating orientation of biomimetic nanoparticles. Our approach is to design and develop new synthetic and analytic strategies to construct and quantify orientated biointerfacing. This will generate new knowledge and patentable methodologies related to orientated biomimetic nanoparticles. Expected outcomes include significant contributions to Australia's scholarly outputs, enhanced national capacity in disruptive nanotechnology, new opportunities for national value-add material manufacturing, and long-term benefits to biomedical and veterinary industries through new materials and nanotechnologies.
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Discovery Early Career Researcher Award - Grant ID: DE210101666
Funder
Australian Research Council
Funding Amount
$395,588.00
Summary
Engineering nanoparticles with enhanced adhesion at the nano-bio interfaces. This project aims to develop a next-generation adhesive nanoparticle platform through in-depth understandings of nanoparticle interactions with bio-interfaces. This project expects to generate new knowledge in the multidisciplinary research field at nano-bio-interfaces by using a recently developed nano-colloidal probe technology, instructing the rational design of nanoparticles with enhanced interface adhesive properti ....Engineering nanoparticles with enhanced adhesion at the nano-bio interfaces. This project aims to develop a next-generation adhesive nanoparticle platform through in-depth understandings of nanoparticle interactions with bio-interfaces. This project expects to generate new knowledge in the multidisciplinary research field at nano-bio-interfaces by using a recently developed nano-colloidal probe technology, instructing the rational design of nanoparticles with enhanced interface adhesive properties. Expected outcomes include a family of adhesive nanoparticles designed for nanopesticide and animal feed applications, with the potential to deliver valuable intellectual property of commercial interest and economic benefit through technology advancement.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
Rational design of array-based nanozyme sensors. The project aims to obtain a deep understanding of molecular interactions at the nano-bio interface, and use this knowledge to develop a robust sensor technology for the rapid detection of foodborne pathogens in complex samples. The project proposes to employ an innovative approach that mimics the senses of smell and taste, where an array of aptamers are expected to work in synergy to precisely identify a target, providing an edge over current sen ....Rational design of array-based nanozyme sensors. The project aims to obtain a deep understanding of molecular interactions at the nano-bio interface, and use this knowledge to develop a robust sensor technology for the rapid detection of foodborne pathogens in complex samples. The project proposes to employ an innovative approach that mimics the senses of smell and taste, where an array of aptamers are expected to work in synergy to precisely identify a target, providing an edge over current sensing technologies. Expected outcomes include a ready-to-go analytical tool for the detection of food contaminants. This should provide significant economic, health, and social benefits through supporting Australian food and health sectors, and the potential commercialisation of sensor technologies.Read moreRead less
Clay nanoparticle-facilitated RNAi for non-transgenic modification of crops. This project aims to define the most effective spray formulations, consisting of clay nanoparticles and induced RNA interference (RNAi) to manipulate gene expression in plants. Topical application of double-stranded RNA (dsRNA) for RNAi represents an attractive alternative to genetically engineered crops. However, naked dsRNA is unstable and is not efficiently taken up by plants. For these reasons, topical application o ....Clay nanoparticle-facilitated RNAi for non-transgenic modification of crops. This project aims to define the most effective spray formulations, consisting of clay nanoparticles and induced RNA interference (RNAi) to manipulate gene expression in plants. Topical application of double-stranded RNA (dsRNA) for RNAi represents an attractive alternative to genetically engineered crops. However, naked dsRNA is unstable and is not efficiently taken up by plants. For these reasons, topical application of dsRNA has thus far produced only modest induction of RNAi in plants. Nanoparticle-facilitated manipulation of gene expression in plants will enable sustainable clean green strategies for protecting crops from diseases. This project will result in improved crop protection and productivity and boost the export potential of Australian crops.Read moreRead less