Skin penetration of nanoparticles promoted by particle design, formulation and application method. This project seeks to better define the determinants of nanoparticle skin penetration and subsequent disposition in the body. The data would be used to guide minimal skin penetration of 'undesirable' nanoparticles and the properties required of 'safe' nanoparticles to enable effective human skin delivery in cosmetic and dermatological products.
Hierarchical assembly of graphene oxide nanoparticles as bionanointerface. This project aims to develop a state-of-the-art fabrication methodology to develop large area polymer/graphene hybrid nanoparticle patterns to precisely modulate cell guidance and regeneration by exogenous electrical stimulation. Polymers and graphene have emerged as the main contenders for the development of soft biocompatible platforms. However, their applicability has been limited due to difficulties in patterning and ....Hierarchical assembly of graphene oxide nanoparticles as bionanointerface. This project aims to develop a state-of-the-art fabrication methodology to develop large area polymer/graphene hybrid nanoparticle patterns to precisely modulate cell guidance and regeneration by exogenous electrical stimulation. Polymers and graphene have emerged as the main contenders for the development of soft biocompatible platforms. However, their applicability has been limited due to difficulties in patterning and their consequent integration under physiological conditions. This project will advance both fundamental and practical knowledge at the forefront of nanotechnology and cell biology, whilst providing training to the research community at the cutting edge of science. The project will also deliver intellectual property, which will position Australia at the forefront of bionanotechnology.Read moreRead less
Nanoparticles to combat cellular dysfunction. This project aims to design, synthesise and characterise nanoparticles that can mediate the adverse effects of reactive oxygen species. The project expects to develop nanoparticles with tailored chemical functionality to modulate the concentration of reactive oxygen species and develop a platform technology for addressing conditions where reactive species are overproduced. The project will research how nanoparticles’ physicochemical properties affect ....Nanoparticles to combat cellular dysfunction. This project aims to design, synthesise and characterise nanoparticles that can mediate the adverse effects of reactive oxygen species. The project expects to develop nanoparticles with tailored chemical functionality to modulate the concentration of reactive oxygen species and develop a platform technology for addressing conditions where reactive species are overproduced. The project will research how nanoparticles’ physicochemical properties affect their activity, and how they affect cellular function, tissue morphology and particle transport in a biological milieu. The project is expected to benefit the advanced manufacturing, veterinary and medical sectors and could lead to new chemotherapeutics.Read moreRead less
Multifunctional particles for biological applications. This project aims to engineer multifunctional particles, examine their biological interactions and create particles for cell targeting, cell internalisation, subcellular drug release and improved pharmacokinetics. Engineered particles are important for drug delivery in nanomedicine. Although various particle-based delivery systems have been developed, few have been commercialised, largely because of problems challenges associated with biolog ....Multifunctional particles for biological applications. This project aims to engineer multifunctional particles, examine their biological interactions and create particles for cell targeting, cell internalisation, subcellular drug release and improved pharmacokinetics. Engineered particles are important for drug delivery in nanomedicine. Although various particle-based delivery systems have been developed, few have been commercialised, largely because of problems challenges associated with biological barriers. This project will develop a platform for the assemble of particles with tailored properties which are expected to provide insights on particle-biological interactions for particle-based therapeutic delivery.Read moreRead less
Designer nano-carriers for targeted hydrophobic anticancer drug delivery with enhanced bioavailability. This project will prepare novel nano-carriers for water insoluble anticancer drug delivery with enhanced bioavailability and targeted therapy. The techniques developed in this project will advance the intellectual leadership of Australia and improve therapeutic efficacy, reduce side effects, and promote good health.
Fundamentals and applications of continuous-flow microprocessing systems based on supercritical fluids and gas expanded liquids. Microchemical systems have considerable potential in the area of chemical discovery and development. Practical application of these systems requires fundamental understanding and strategies for conversion to appropriate scale. The aim of this project is to overcome such challenges in the development of microstructured continuous-flow technology.