Quantification of the Remineralisation of Enamel. This project has three specific aims:
1. To quantify the ultrastructure and mechanisms of remineralisation of enamel using scanning and transmission electron microscopy.
2. To determine the mechanical properties of remineralised tissue and compare with those of sound enamel.
3. To develop an in-vivo optical fibre probe for monitoring and quantifying the changes of mineralised carious tissue during remineralisation.
This project will enable ....Quantification of the Remineralisation of Enamel. This project has three specific aims:
1. To quantify the ultrastructure and mechanisms of remineralisation of enamel using scanning and transmission electron microscopy.
2. To determine the mechanical properties of remineralised tissue and compare with those of sound enamel.
3. To develop an in-vivo optical fibre probe for monitoring and quantifying the changes of mineralised carious tissue during remineralisation.
This project will enable patients prone to orthodontic induced root resorption to be identified and also to assist with validating repair of enamel tooth structure in a non-surgical manner. It is anticipated to result in the development of a novel fibre optic instrument with applications beyond dentistry.
Read moreRead less
Survival mechanisms of teeth. The patterns of fracture in teeth can be used to infer bite forces and dietary habits in human ancestors and other animals, yet the link between the fracture pattern and forces is not yet well understood. This project will enable new developments in the field of evolutionary biology by providing mathematical models that can predict these forces.
Discovery Early Career Researcher Award - Grant ID: DE120101666
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Endogenous bone regenerative technique to repair hard tissue defects in congenital craniofacial clefts. This project aims to develop an endogenous bone regenerative technique to repair the bony defects in congenital craniofacial clefts, through stimulating patients' latent self-repair mechanisms and reviving their innate capacity for regeneration. The novel technique would replace the existing and controversial surgical bone grafting method.
Three-Dimensional Polymer Fibre Scaffolds with Functional Nano-structured Surface. The Partner Organisation to this research, CyGenics Ltd, is a world leader in cell biotechnology. A key challenge faced by the CyGenics and other biotech companies is the provision of tissue scaffolding materials that have the right three-dimensional macroscopic structure plus a suitable nano-structured surface micro-environment, similar to the natural extracellular matrix. This joint project combines expertise in ....Three-Dimensional Polymer Fibre Scaffolds with Functional Nano-structured Surface. The Partner Organisation to this research, CyGenics Ltd, is a world leader in cell biotechnology. A key challenge faced by the CyGenics and other biotech companies is the provision of tissue scaffolding materials that have the right three-dimensional macroscopic structure plus a suitable nano-structured surface micro-environment, similar to the natural extracellular matrix. This joint project combines expertise in polymer fibres, surface engineering and cell culture to tackle the key challenge. The outcome will help position the local polymer fibre and cell culture industries at the forefront of tissue scaffolding materials research and development. Read moreRead less
Development of Acid Degradable Polymeric Nanoparticles for Intracellular and Tumour Site Selective Delivery of Drugs. There is an enormous need to develop effective anticancer drug delivery systems to reduce the social and economic impact of cancer. One of the most critical problems in tumour treatment is the lack of selective toxicity of anticancer drugs against tumour tissues. Our multidisciplinary team will aim to develop a novel polymer based system for tumour site-selective delivery of anti ....Development of Acid Degradable Polymeric Nanoparticles for Intracellular and Tumour Site Selective Delivery of Drugs. There is an enormous need to develop effective anticancer drug delivery systems to reduce the social and economic impact of cancer. One of the most critical problems in tumour treatment is the lack of selective toxicity of anticancer drugs against tumour tissues. Our multidisciplinary team will aim to develop a novel polymer based system for tumour site-selective delivery of anticancer drugs. Development of such advanced drug delivery systems will significantly enhance Australia`s power in biotechnology. Development and/or formation of strategies to improve the health quality of Australians, is an important anticipated outcome of this innovative project.Read moreRead less
Development and Evaluation of Well-Defined Polymer-RNA Conjugates as Improved Therapeutics. Gene-based drugs offer an enormous potential to treat a wide range of diseases including, but not limited to, AIDS, hepatitis, and cancer. However, effective delivery of these drugs in body is needed to convert their therapeutic potential to clinically applicable treatments. Our multidisciplinary team will aim to develop novel, polymer-gene hybrid materials for efficient delivery of gene based therapeuti ....Development and Evaluation of Well-Defined Polymer-RNA Conjugates as Improved Therapeutics. Gene-based drugs offer an enormous potential to treat a wide range of diseases including, but not limited to, AIDS, hepatitis, and cancer. However, effective delivery of these drugs in body is needed to convert their therapeutic potential to clinically applicable treatments. Our multidisciplinary team will aim to develop novel, polymer-gene hybrid materials for efficient delivery of gene based therapeutics. Development of such advanced drug delivery systems will significantly enhance Australia`s power in biotechnology. Development and/or formation of new materials and strategies to improve the health quality of Australians, is an important anticipated outcome of this innovative project. Read moreRead less
Nanoporous siloxane membranes for ultrasound mediated ophthalmic drug delivery. This project will develop tailored polymers for use in a novel non-invasive ocular drug delivery device which treats vision threatening conditions such as age-related macular degeneration (AMD). The outcomes of this project will enable an entirely new ocular drug delivery technology, thereby delivering significant benefit to ophthalmic healthcare.