Development of a Novel Process for the Formation of Polymer Vesicles. The project would provide an increased understanding of polymer structures, polymer-drug interactions and dense gas processing of polymers. The novel process developed would be beneficial on a manufacturing level since it dramatically reduces processing time and minimises energy requirements. The research to be conducted is leading-edge technology that will attract business from international polymer, drug and biotechnology co ....Development of a Novel Process for the Formation of Polymer Vesicles. The project would provide an increased understanding of polymer structures, polymer-drug interactions and dense gas processing of polymers. The novel process developed would be beneficial on a manufacturing level since it dramatically reduces processing time and minimises energy requirements. The research to be conducted is leading-edge technology that will attract business from international polymer, drug and biotechnology companies. The development of world-class research provides Australia with recognition as a world leader in the field and strengthens and broadens the knowledge base of Australian scientists and engineers.Read moreRead less
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
An Integrated Biotechnological Process for Production of Lactic Acid from Carbohydrate-Waste Streams by Rhizopus sp. Lactic acid is the most widely occurring multifunctional organic acid. It has enormous applications in food and food-related industries, and great potential use for production of biodegradable and biocompatible polylactate polymers. The aim of this research is to develop an innovative biotechnological process, incorporating simultaneous saccharification and fermentation, which int ....An Integrated Biotechnological Process for Production of Lactic Acid from Carbohydrate-Waste Streams by Rhizopus sp. Lactic acid is the most widely occurring multifunctional organic acid. It has enormous applications in food and food-related industries, and great potential use for production of biodegradable and biocompatible polylactate polymers. The aim of this research is to develop an innovative biotechnological process, incorporating simultaneous saccharification and fermentation, which integrates the production of lactic acid with the treatment of high strength food industry ?effluent? streams - carbohydrate waste streams. The proposed SSF process will cultivate an identified fungal Rhizopus sp strain on the waste streams, as production substrates, leading to an environmentally friendly and economically sustainable new technology for the food industry.Read moreRead less
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.
Degradable hollow microspheres for liver cancer treatment. The expected outcome of this multidisciplinary approach is a controlled drug delivery system for the treatment of liver cancer. We aim to increase the understanding of drug release using polymeric microspheres and the influence of the polymer properties on the release kinetics resulting in the tailored drug release for liver cancer treatment. An indepth knowledge in drug delivery can lead to optimised release kinetics leding to an increa ....Degradable hollow microspheres for liver cancer treatment. The expected outcome of this multidisciplinary approach is a controlled drug delivery system for the treatment of liver cancer. We aim to increase the understanding of drug release using polymeric microspheres and the influence of the polymer properties on the release kinetics resulting in the tailored drug release for liver cancer treatment. An indepth knowledge in drug delivery can lead to optimised release kinetics leding to an increased patient convenience and life prolonging treatments.Read moreRead less
Oral Insulin Delivery facilitated by Enteric Coating using Dense Gas Technologies. Insulin dependant diabetes is a rapidly growing disease. The current method for insulin delivery to the patient is by injection, which is inconvenient. Oral delivery of insulin is a more acceptable method. It is proposed to develop a dense gas technique to coat insulin with a pH sensitive polymer to protect it from the acidic environment of the stomach. Insulin can then be released at the high pH of the intestin ....Oral Insulin Delivery facilitated by Enteric Coating using Dense Gas Technologies. Insulin dependant diabetes is a rapidly growing disease. The current method for insulin delivery to the patient is by injection, which is inconvenient. Oral delivery of insulin is a more acceptable method. It is proposed to develop a dense gas technique to coat insulin with a pH sensitive polymer to protect it from the acidic environment of the stomach. Insulin can then be released at the high pH of the intestine when the polymer is dissolved. Particle size control is feasible by dense gas processes by manipulating operating parameters. Advantages include low residual solvent and manufacture at ambient temperatures.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
Nano-mechanical and nano-structural investigation of dentine: unravelling a novel nano-scale regulator of high durability of mineralised tissues. This project proposes that proteoglycans (PG) are key regulators of the high durability of dentine. PGs are primarily responsible for the structural organization of collagen in all vertebrates, however virtually nothing is known about their role on the biomechanics of mineralized tissues. This study aims to thoroughly address this question.
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.