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
Organic Bionics: Soft Materials to Solve Hard Problems in Neuroengineering. This project aims to combine innovations in organic conductors, nanotechnology, 3D biofabrication and neuroengineering to develop a bioelectronic system capable of wireless neuromodulation with unprecedented stability and precision. This project expects to generate new knowledge regarding the properties of materials that promote optical neuromodulation and new strategies to obtain long-term material stability in biologic ....Organic Bionics: Soft Materials to Solve Hard Problems in Neuroengineering. This project aims to combine innovations in organic conductors, nanotechnology, 3D biofabrication and neuroengineering to develop a bioelectronic system capable of wireless neuromodulation with unprecedented stability and precision. This project expects to generate new knowledge regarding the properties of materials that promote optical neuromodulation and new strategies to obtain long-term material stability in biological environments. The expected outcome is to generate new material design rules to facilitate wireless neuromodulation technologies in biomedical engineering. The project will position Australia as a leader in bionic devices by creating a new 3D bioprinting hub for low-cost fabrication of bioelectronic systems.Read moreRead less
Seeing the Bio-Nano "Talk" in the brain via real-time multiplex tracking. This project aims to develop new knowledge and smart tools that have the potential to greatly improve brain research. The blood-brain-barrier is the major physiological barrier that protects the brain from environmental toxins, bacteria and viruses, but limits the effectiveness of nanoparticle-based brain imaging agents. Expected outcomes of this project include a better understanding of the mechanisms that allow nanoparti ....Seeing the Bio-Nano "Talk" in the brain via real-time multiplex tracking. This project aims to develop new knowledge and smart tools that have the potential to greatly improve brain research. The blood-brain-barrier is the major physiological barrier that protects the brain from environmental toxins, bacteria and viruses, but limits the effectiveness of nanoparticle-based brain imaging agents. Expected outcomes of this project include a better understanding of the mechanisms that allow nanoparticles to penetrate the blood-brain-barrier, as well as improving brain imaging. Benefits of the project include the commercialisation of technologies and smarl tools developed in this projetct, and establishment of a new Australian biotechnology company that exports brain-imaging technologies to the world.Read moreRead less
Organic Bioelectronics: Solving Key Barriers to Precision Neuromodulation. This project aims to combine the principles of molecular electronics and neurobiology to create organic conductors with enhanced biocompatibility that enable optical neuromodulation. This project expects to generate new knowledge regarding the properties of materials that promote connectivity with neurons and the ability of new microscopy tools to visualise this bio-interface. The expected outcome of this project includes ....Organic Bioelectronics: Solving Key Barriers to Precision Neuromodulation. This project aims to combine the principles of molecular electronics and neurobiology to create organic conductors with enhanced biocompatibility that enable optical neuromodulation. This project expects to generate new knowledge regarding the properties of materials that promote connectivity with neurons and the ability of new microscopy tools to visualise this bio-interface. The expected outcome of this project includes new high performing materials, measurement tools and fabrication approaches to overcome the key challenges to precision neuromodulation. A significant benefit of the new materials is their printability, providing the opportunity to establish a sovereign capability to manufacture low-cost bioelectronic systems in Australia.Read moreRead less
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.
Micro-electrofluidic platforms for monitoring 3D human biological models. The ability to study living cells and human biological models (cell cultures) delivers greater understanding of basic biological function and response to applied (bio)chemical stimuli. Creating the physical environments to sustain biological models, and mimic natural conditions and fluidic pathways, is immensely challenging, yet essential to deliver meaningful observational data. This project will deliver this capability t ....Micro-electrofluidic platforms for monitoring 3D human biological models. The ability to study living cells and human biological models (cell cultures) delivers greater understanding of basic biological function and response to applied (bio)chemical stimuli. Creating the physical environments to sustain biological models, and mimic natural conditions and fluidic pathways, is immensely challenging, yet essential to deliver meaningful observational data. This project will deliver this capability through the convergence of expertise and innovation in analytical chemistry, materials science and cellular biology, ultilising the latest technology and understanding of 3D micro/electrofluidics, to enable the study and stimulation of advanced biological models, sustained within precisely controlled 3D micro-environments.Read moreRead less
Multiscale Study on Biomechanical Roles of Soft Tissue on Bone Remodelling. The project aims to increase our knowledge of the processes of bone remodelling and the role of soft tissue in this process. Mechanical force is a key stimulus for regulating bone remodelling. A significant question in biomechanics is why orthodontics only use very small forces (1 Newton) to generate significant oral bone remodelling, whereas prosthodontics that apply three orders of magnitude higher forces (~1000 Newton ....Multiscale Study on Biomechanical Roles of Soft Tissue on Bone Remodelling. The project aims to increase our knowledge of the processes of bone remodelling and the role of soft tissue in this process. Mechanical force is a key stimulus for regulating bone remodelling. A significant question in biomechanics is why orthodontics only use very small forces (1 Newton) to generate significant oral bone remodelling, whereas prosthodontics that apply three orders of magnitude higher forces (~1000 Newton) do not move dental implants. This project aims to develop new multiscale modelling and remodelling techniques in computational mechanics to explore the roles played by connective soft tissue in bone adaptation. Expected project outcomes would increase our understanding in biomechanics and affect health care disciplines such as orthodontics, prosthodontics and orthopaedics.Read moreRead less