Bridging the interface between nanoengineered materials and biological systems. Advances in nanotechnology have the potential to revolutionise how we treat many diseases. Nanoengineered drug carriers can deliver drugs to the areas in the body where they are required, limiting harmful side effects. This project will investigate how nanomaterials interact with biological systems and understand any potential side effects.
Discovery Early Career Researcher Award - Grant ID: DE130101550
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Functional polymer encapsulation to enhance biological performance of implantable materials. This project will develop biomaterial films from essential oils using a low-cost 'green' technology. Applied to commercial biomaterials, these films will minimise infections and inflammations commonly associated with implants. These films will also enable clinical use of metallic resorbable implants for tissue engineering and function restoration.
Discovery Early Career Researcher Award - Grant ID: DE130100922
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Diamond cybernetics: nanocrystalline diamond for interfacing bionic devices with the human nervous system. Bionic devices will soon be used to treat disorders such as epilepsy, Parkinson's and depression. We will use diamond to create high resolution, permanent electrical connections between devices and the human nervous system. These diamond connections will preserve nerve health and make bionic devices more effective and able to last a lifetime.
New generation microfluidic devices using light responsive hydrogels. This project aims to develop a new way of fabricating microfluidic devices using light-degradable hydrogels as its core element. This approach would allow researchers to rapidly construct and modify microfluidic devices within their own laboratories, without the need for specialised clean rooms or expensive equipment. The versatility of the microfluidic device is designed to be demonstrated by the manufacture of mature T cells ....New generation microfluidic devices using light responsive hydrogels. This project aims to develop a new way of fabricating microfluidic devices using light-degradable hydrogels as its core element. This approach would allow researchers to rapidly construct and modify microfluidic devices within their own laboratories, without the need for specialised clean rooms or expensive equipment. The versatility of the microfluidic device is designed to be demonstrated by the manufacture of mature T cells, which continues to be a major challenge in stem cell science and which could have fundamental biological and commercial significance.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101308
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
An in vitro model of biomaterial-induced thrombosis. This project intends to use bioengineering strategies to develop new methods to understand material interactions with proteins and cells. The project plans to develop microfluidic channels to contain test materials and immobilise a key enzyme associated with thrombosis by plasma immersion ion implantation. This knowledge may increase our understanding of material-biomolecule interactions and have implications for manipulating biological foulin ....An in vitro model of biomaterial-induced thrombosis. This project intends to use bioengineering strategies to develop new methods to understand material interactions with proteins and cells. The project plans to develop microfluidic channels to contain test materials and immobilise a key enzyme associated with thrombosis by plasma immersion ion implantation. This knowledge may increase our understanding of material-biomolecule interactions and have implications for manipulating biological fouling across multiple fields.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100131
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
Biomaterials characterisation facility. The convergence of nanotechnology and biotechnology offers new opportunities to prepare nanoengineered materials for applications in biomedicine. The Biomaterials Characterisation Facility will provide equipment to characterise such nanoengineered materials to underpin advances in therapeutic drug delivery and tissue engineering.
Soft materials containing hierarchy via 3D sacrificial micro-moulding. The project seeks to develop sophisticated new polymeric materials and devices not possible using current manufacturing techniques. Biomaterials based on hydrogels are ideal substrates for synthetic extra-cellular matrices due to their high water content. However, one of the challenges hindering the use of hydrogels is reproducing the transport properties found in natural tissue with hierarchical features such as vascularisat ....Soft materials containing hierarchy via 3D sacrificial micro-moulding. The project seeks to develop sophisticated new polymeric materials and devices not possible using current manufacturing techniques. Biomaterials based on hydrogels are ideal substrates for synthetic extra-cellular matrices due to their high water content. However, one of the challenges hindering the use of hydrogels is reproducing the transport properties found in natural tissue with hierarchical features such as vascularisation. To address this, the project plans to develop a 3D moulding process for generating soft materials containing precise channels decorated with defined molecules. Intended outcomes include a fundamental understanding of the 3D moulding process, and new polymers and advanced tools for bioengineers for future applications such as tissue transplants, cell guides for treating spinal cord injuries, soft robotics and microfluidic devices to study cancer metastasis. Read moreRead less
Establishing nanoscale design principles for non-viral genome engineering. This project aims to develop a bio-nanotechnology platform for non-viral genome engineering using dendronised polymers. The project will advance both fundamental and practical knowledge at the forefront of nanotechnology and cell biology, whilst providing training to the research community. Outcomes from the project will also provide significant benefits, such as positioning Australia at the forefront of genome engineerin ....Establishing nanoscale design principles for non-viral genome engineering. This project aims to develop a bio-nanotechnology platform for non-viral genome engineering using dendronised polymers. The project will advance both fundamental and practical knowledge at the forefront of nanotechnology and cell biology, whilst providing training to the research community. Outcomes from the project will also provide significant benefits, such as positioning Australia at the forefront of genome engineering.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101755
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Regulation of cell reprogramming to pluripotency by complex topographies. This project aims to use nanotopography approaches to improve the efficiency of generating induced Pluripotent Stem Cells (iPSCs) by changing cell behaviour at biomaterial surfaces. The significance is that iPSCs have enormous potential in stem cell therapy, regenerative medicine, and disease-specific treatment, with the potential to replace other stem cell types. The expected outcomes are that cellular reprogramming proce ....Regulation of cell reprogramming to pluripotency by complex topographies. This project aims to use nanotopography approaches to improve the efficiency of generating induced Pluripotent Stem Cells (iPSCs) by changing cell behaviour at biomaterial surfaces. The significance is that iPSCs have enormous potential in stem cell therapy, regenerative medicine, and disease-specific treatment, with the potential to replace other stem cell types. The expected outcomes are that cellular reprogramming process for iPSCs generation will be improved and the canonical reprogramming factors might be reduced using surface nanotopographies of self-assembled colloidal crystals. The benefits are the promotion of productivity, the reduction of costs, and the application of iPSC derivatives, aimed at future clinical applications.Read moreRead less
Effect of a novel immobilised antimicrobial peptide on bacteria. This project plans to investigate a novel cationic peptide that prevents microbial colonisation of surfaces. The ability of bacteria to colonise surfaces affects almost all aspects of human life – from water to food and medical devices. As microbes become increasingly resistant to traditional biocides, the design of effective antimicrobial surfaces to prevent microbial colonisation and biofilm formation is critically important. The ....Effect of a novel immobilised antimicrobial peptide on bacteria. This project plans to investigate a novel cationic peptide that prevents microbial colonisation of surfaces. The ability of bacteria to colonise surfaces affects almost all aspects of human life – from water to food and medical devices. As microbes become increasingly resistant to traditional biocides, the design of effective antimicrobial surfaces to prevent microbial colonisation and biofilm formation is critically important. The novel cationic peptide may provide a solution, but the mechanism of action of surface-bound peptides on bacteria is poorly understood. This project aims to combine biophysics, biochemistry, microbiology and molecular biology to study interactions with the surface of two model bacteria. This may facilitate optimal design of new coatings.Read moreRead less