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
Designer Nanoparticles Enable mRNA Protein Factories. Intracellular delivery of mRNA facilitates target protein production, which could build protein factories that are essential in biomanufacturing industries. However, the instability of mRNA greatly lowers the protein production performance, limiting the commercial translation potential. This project aims to develop a new generation of nanoparticle delivery system to enhance mRNA stability against intracellular unstable cue, enzymatic digestio ....Designer Nanoparticles Enable mRNA Protein Factories. Intracellular delivery of mRNA facilitates target protein production, which could build protein factories that are essential in biomanufacturing industries. However, the instability of mRNA greatly lowers the protein production performance, limiting the commercial translation potential. This project aims to develop a new generation of nanoparticle delivery system to enhance mRNA stability against intracellular unstable cue, enzymatic digestion and thermal stress. This will be achieved by tailoring the nanochemistry at multi-scales. Expected outcomes include new knowledge in custom-design of functional nanomaterials for mRNA delivery, and new technology that will bring commercial benefits to the partner organisation and the biopharma sector.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101542
Funder
Australian Research Council
Funding Amount
$450,154.00
Summary
Impact of humoral immunity on nanoparticle–biological interactions. This project aims to improve the biological applications of nanomaterials by understanding their fundamental interactions with proteins and cells in relevant biological environments. This will create new knowledge on how humoral (antibody-mediated) immunity affects nanomaterials using cutting-edge immunoassays, bio–nano characterisation techniques, and bioinformatics. Expected outcomes of the project include an understanding of ....Impact of humoral immunity on nanoparticle–biological interactions. This project aims to improve the biological applications of nanomaterials by understanding their fundamental interactions with proteins and cells in relevant biological environments. This will create new knowledge on how humoral (antibody-mediated) immunity affects nanomaterials using cutting-edge immunoassays, bio–nano characterisation techniques, and bioinformatics. Expected outcomes of the project include an understanding of how specific antibodies modulate the protein coatings on nanomaterials, which will shed light on how immune cells interact with nanomaterials. This will lead to design principles for nanomaterial properties to improve their effectiveness in delivering drugs and gene therapies.Read moreRead less
Biofabricated tissue mimics for nanoparticle design and development. Nanoparticles are widely used in commercial applications spanning biotechnology, health and environmental monitoring, and drug delivery. Materials scientists can generate large libraries of nanoparticles, but the toolbox available to test these nanoparticles is limited. We will use biofabrication to comprehensively evaluate the fate of polymer grafted nanocellulose across simulated tissue barriers. Model blood vessels with reci ....Biofabricated tissue mimics for nanoparticle design and development. Nanoparticles are widely used in commercial applications spanning biotechnology, health and environmental monitoring, and drug delivery. Materials scientists can generate large libraries of nanoparticles, but the toolbox available to test these nanoparticles is limited. We will use biofabrication to comprehensively evaluate the fate of polymer grafted nanocellulose across simulated tissue barriers. Model blood vessels with recirculating flow will help understand permeation; tunable matrices will establish ‘matrix structure—nanoparticle diffusion’ criteria. The outcome from this project will be an understanding of how plastic nanoparticles penetrate tissue, to guide nanomaterials design and mitigate risk associated with toxicity. Read moreRead less
Deciphering lipid-RNA nanocarrier structure upon RNA complexation. This project aims to decipher the nanostructure evolution, at a millisecond timescale, of lipid self-assembly upon coupling with RNAs and track the nanocarrier structural changes induced by biologically relevant acidic environments. This project will generate new knowledge of the interplay between the self-assembled lipid-RNA nanostructures and cellular objects for successful payload release. The expected outcome of this project ....Deciphering lipid-RNA nanocarrier structure upon RNA complexation. This project aims to decipher the nanostructure evolution, at a millisecond timescale, of lipid self-assembly upon coupling with RNAs and track the nanocarrier structural changes induced by biologically relevant acidic environments. This project will generate new knowledge of the interplay between the self-assembled lipid-RNA nanostructures and cellular objects for successful payload release. The expected outcome of this project is identification of the fundamental mechanisms of lipid-RNA molecular self-assembly and intracellular nucleic acid delivery. This should provide significant advances in the field of lipid nanoparticle engineering for the delivery of RNA therapeutics. Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100042
Funder
Australian Research Council
Funding Amount
$462,846.00
Summary
Developing a multimodal imaging pipeline for antisense technology. Antisense molecules represent a revolutionary drug discovery platform for life science, but to understand their distributions in cells and tissues is challenging. By integrating nanobiotechnology approaches, this project expects to develop and apply innovative imaging workflow to track antisense molecules in cells and tissues with nanoscale precision. Expected outcomes include new knowledge of the trafficking of these molecules a ....Developing a multimodal imaging pipeline for antisense technology. Antisense molecules represent a revolutionary drug discovery platform for life science, but to understand their distributions in cells and tissues is challenging. By integrating nanobiotechnology approaches, this project expects to develop and apply innovative imaging workflow to track antisense molecules in cells and tissues with nanoscale precision. Expected outcomes include new knowledge of the trafficking of these molecules across cells and tissues and refined imaging methods. This project should provide more strategic delivery of antisense molecules to specific cells and tissue, which will have significant downstream economic and social benefits to the Australian community. 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