Caveospheres: A versatile peptide delivery system. Nanotechnology has the potential to transform the way we treat many diseases. This project will investigate a new type of nanoparticle, the caveosphere, and tests its effectiveness as a peptide delivery system. Caveospheres can protect delicate cargo from degradation, target cargo to specific cells that induce the maximum therapeutic response, and can be synthesised in large-scale, cost-effective batch fermentation. This study will:
1: Engineer ....Caveospheres: A versatile peptide delivery system. Nanotechnology has the potential to transform the way we treat many diseases. This project will investigate a new type of nanoparticle, the caveosphere, and tests its effectiveness as a peptide delivery system. Caveospheres can protect delicate cargo from degradation, target cargo to specific cells that induce the maximum therapeutic response, and can be synthesised in large-scale, cost-effective batch fermentation. This study will:
1: Engineer biological function into caveospheres
2: Investigate the cellular behavior of the engineered caveospheres
3: Determine the therapeutic activity of caveospheres in vitro
It will develop a fundamental understanding of nanoparticles trafficking in cells, to make improved nanoparticle delivery systems.Read moreRead less
Next generation enzymes using stimuli responsive protein/polymer hybrids. Improved stability and control over activity are key to unlocking the full potential of enzymes. Advanced polymer synthesis and synthetic biology will be combined to engineer stable, bioresponsive enzyme/polymer hybrids. This study will:
1: Develop a rapid screening method to identify the optimal sites for polymer-to-enzyme attachment
2: Evaluate the stability and bioresponsive activity of enzyme/polymer hybrids
3: Formula ....Next generation enzymes using stimuli responsive protein/polymer hybrids. Improved stability and control over activity are key to unlocking the full potential of enzymes. Advanced polymer synthesis and synthetic biology will be combined to engineer stable, bioresponsive enzyme/polymer hybrids. This study will:
1: Develop a rapid screening method to identify the optimal sites for polymer-to-enzyme attachment
2: Evaluate the stability and bioresponsive activity of enzyme/polymer hybrids
3: Formulate enzyme/polymer hybrids into a targeted nanoparticle delivery system
This project will examine the performance of polymer-enzyme hybrids with cells, however these innovations will also have significant applications in other fields using enzymatic processes, such as food processing, biofuel production, and agriculture.Read moreRead less
Laser-free on-chip super-resolution microscopy. The project aims to develop a compact, cost-effective on-chip super-resolution microscope through an innovative combination of imaging algorithms, optics and integrated photonics. This project addresses limitations in imaging algorithms that increase laser system complexity and constrain imaging speed and applications, as well as nanostructure fabrication issues. Expected outcomes include the discovery of emitter self-interference microscopy, new k ....Laser-free on-chip super-resolution microscopy. The project aims to develop a compact, cost-effective on-chip super-resolution microscope through an innovative combination of imaging algorithms, optics and integrated photonics. This project addresses limitations in imaging algorithms that increase laser system complexity and constrain imaging speed and applications, as well as nanostructure fabrication issues. Expected outcomes include the discovery of emitter self-interference microscopy, new knowledge in imaging, photonics and biophysics, the world’s fastest super-resolution technology, compact on-chip nanoscopy that can be added to existing technology and proof of concept in three areas. Benefits are anticipated in commercialisation, improved photonics devices and usage in biophysics.Read moreRead less
Soft Plasmene Nanosheets for Stretchable Plasmonic Skins. Conventional plasmonic sensors and devices are rigid, planar, and not stretchable. This project aims to apply plasmene materials developed at Monash's Nanobionics lab to design highly stretchable plasmonic devices (artificial plasmonic skins). Systematic experimental and theoretical studies will be undertaken to understand how the plasmonic skins respond to strains and how they can be used for fabricating novel stretchable devices. Such s ....Soft Plasmene Nanosheets for Stretchable Plasmonic Skins. Conventional plasmonic sensors and devices are rigid, planar, and not stretchable. This project aims to apply plasmene materials developed at Monash's Nanobionics lab to design highly stretchable plasmonic devices (artificial plasmonic skins). Systematic experimental and theoretical studies will be undertaken to understand how the plasmonic skins respond to strains and how they can be used for fabricating novel stretchable devices. Such studies will generate important new knowledge of fabrication, characterisation, and modelling of stretchable plasmene, hence, contributing to further Australian standing in the field of nanotechnology and plasmonics. It may also incubate patentable technologies, bringing potential economic gains.Read moreRead less
Ultrastretchable, Highly Transparent, Wearable Gold Nanowire Generators. Next-generation wearable electronics should be thin, soft and even transparent, enabling applications impossible to achieve with traditional rigid electronics. Such future electronics will require disruptive soft skin-conformal energy devices to power. This project aims to develop a bi-modal gold nanowire percolation strategy to design ultrathin conductors that are electrically conductive, optically transparent and mechanic ....Ultrastretchable, Highly Transparent, Wearable Gold Nanowire Generators. Next-generation wearable electronics should be thin, soft and even transparent, enabling applications impossible to achieve with traditional rigid electronics. Such future electronics will require disruptive soft skin-conformal energy devices to power. This project aims to develop a bi-modal gold nanowire percolation strategy to design ultrathin conductors that are electrically conductive, optically transparent and mechanically stretchable. It expects to generate new knowledge in nanomaterials design and new technologies to fabricate skin-like invisible wearable generators. This should provide significant benefits in advancing Australian standing in the fields of nanotechnology and energy science, and bringing potential economic gains.Read moreRead less
Biomimetic Design and Fabrication of Smart Dry Adhesives. Gecko footpads have unique structures with amazing features; imitating these fine bio-structures will lead to a multitude of innovations. This project aims to study fundamental principles governing adhesion phenomena for creating entirely new biomimetic nanomaterials with tunable adhesion, self-cleaning and controlled release capabilities. The gecko-mimicking materials and the associated dynamic effects will be characterized quantitativel ....Biomimetic Design and Fabrication of Smart Dry Adhesives. Gecko footpads have unique structures with amazing features; imitating these fine bio-structures will lead to a multitude of innovations. This project aims to study fundamental principles governing adhesion phenomena for creating entirely new biomimetic nanomaterials with tunable adhesion, self-cleaning and controlled release capabilities. The gecko-mimicking materials and the associated dynamic effects will be characterized quantitatively at multiscales and the nanoscale phenomena will be linked to macroscopic performance. The results of this research should provide a fundamental understanding of tunable adhesion mechanisms for the design and development of optimized materials with superb performance of practical significance.
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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
Dynamic Microcages for Cells: Advanced Tools to Interrogate Cell Mechanics. This project aims to develop a suite of movable micro/nanostructures with integrated mechanical and biological sensors, which will be interfaced with cells to investigate how those cells respond to their surrounding physical environment. Expected outcomes are new technologies in micro/nanofabrication, sensing, and advanced imaging, and deep understanding of the biological processes that control tissue formation and repai ....Dynamic Microcages for Cells: Advanced Tools to Interrogate Cell Mechanics. This project aims to develop a suite of movable micro/nanostructures with integrated mechanical and biological sensors, which will be interfaced with cells to investigate how those cells respond to their surrounding physical environment. Expected outcomes are new technologies in micro/nanofabrication, sensing, and advanced imaging, and deep understanding of the biological processes that control tissue formation and repair. These outcomes would impact how 3D microsystems are developed and applied, informing the design of advanced in-vitro cell culture systems. Significant benefits are expected in 3D nano-microengineering, and in generating new knowledge underpinning future advances in stem cell and tissue engineering technologies.Read moreRead less
Establishing Design Principles Of Polymers For Intracellular Delivery . Engineered polymers have played a central role in the field of bionanotechnology by enabling targeted nanoscale cell interactions. Progress in the field of intracellular delivery is currently affected by a major bottleneck due to the absence of effective polymers that is applicable across the range of bimolecular cargoes. In essence depending on the type of cargo: DNA, RNA or protien, the polymer needs programmability. The l ....Establishing Design Principles Of Polymers For Intracellular Delivery . Engineered polymers have played a central role in the field of bionanotechnology by enabling targeted nanoscale cell interactions. Progress in the field of intracellular delivery is currently affected by a major bottleneck due to the absence of effective polymers that is applicable across the range of bimolecular cargoes. In essence depending on the type of cargo: DNA, RNA or protien, the polymer needs programmability. The limited tunability of traditional polymers agents makes them unsuitable for this particular application. The multidisciplinary project addresses this significant problem by engineering novel sequences of defined polymer based nanoscale agents to achieve efficient delivery in cells.Read moreRead less