Caveospheres: A versatile peptide delivery system. Nanotechnology has the potential to transform the way we treat many diseases. This project will investigate a new type of nanoparticle, the caveosphere, and tests its effectiveness as a peptide delivery system. Caveospheres can protect delicate cargo from degradation, target cargo to specific cells that induce the maximum therapeutic response, and can be synthesised in large-scale, cost-effective batch fermentation. This study will:
1: Engineer ....Caveospheres: A versatile peptide delivery system. Nanotechnology has the potential to transform the way we treat many diseases. This project will investigate a new type of nanoparticle, the caveosphere, and tests its effectiveness as a peptide delivery system. Caveospheres can protect delicate cargo from degradation, target cargo to specific cells that induce the maximum therapeutic response, and can be synthesised in large-scale, cost-effective batch fermentation. This study will:
1: Engineer biological function into caveospheres
2: Investigate the cellular behavior of the engineered caveospheres
3: Determine the therapeutic activity of caveospheres in vitro
It will develop a fundamental understanding of nanoparticles trafficking in cells, to make improved nanoparticle delivery systems.Read moreRead less
Next generation enzymes using stimuli responsive protein/polymer hybrids. Improved stability and control over activity are key to unlocking the full potential of enzymes. Advanced polymer synthesis and synthetic biology will be combined to engineer stable, bioresponsive enzyme/polymer hybrids. This study will:
1: Develop a rapid screening method to identify the optimal sites for polymer-to-enzyme attachment
2: Evaluate the stability and bioresponsive activity of enzyme/polymer hybrids
3: Formula ....Next generation enzymes using stimuli responsive protein/polymer hybrids. Improved stability and control over activity are key to unlocking the full potential of enzymes. Advanced polymer synthesis and synthetic biology will be combined to engineer stable, bioresponsive enzyme/polymer hybrids. This study will:
1: Develop a rapid screening method to identify the optimal sites for polymer-to-enzyme attachment
2: Evaluate the stability and bioresponsive activity of enzyme/polymer hybrids
3: Formulate enzyme/polymer hybrids into a targeted nanoparticle delivery system
This project will examine the performance of polymer-enzyme hybrids with cells, however these innovations will also have significant applications in other fields using enzymatic processes, such as food processing, biofuel production, and agriculture.Read moreRead less
Development of dense gas technology platforms for the formulation of oral vaccines. This project will aim to develop a technology platform that enables the formulation of vaccines that can be delivered orally and this research has the potential to radically change existing vaccination regimens. The availability of needle-free vaccination also has potential for considerable societal and economic impact in developing countries.
Utilisation of dense gas technology for the development of controlled release active pharmaceutical ingredients (API) delivery systems. The aim of this project is to develop an orally administered drug formulation for the treatment of irritable bowel syndrome and other diseases of the colon. Irritable bowel syndrome is a debilitating condition and the cost to society is similar to that of asthma. As such, the project has the potential to have a major impact on society.
Interactive companion robot with nanowire-based electronic skin. Interactive companion robot with nanowire-based electronic skin. This project aims to design an interactive companion robot with electronic skin which can communicate with people by touch and enhance their psychological development. Interactive companion robots can improve the social life quality of people with communication disorders and help elderly people. Although touch is extremely important in human communication, most compan ....Interactive companion robot with nanowire-based electronic skin. Interactive companion robot with nanowire-based electronic skin. This project aims to design an interactive companion robot with electronic skin which can communicate with people by touch and enhance their psychological development. Interactive companion robots can improve the social life quality of people with communication disorders and help elderly people. Although touch is extremely important in human communication, most companion robots lack haptic sensing, which degenerates the human-robot interaction. The anticipated outcome is a touchable robot with developmental benefits for autistic children and psychological benefits for elderly people.Read moreRead less
Creation of a super-resolution map of the bacterial cytokinesis machinery . Cell division is a fundamental process essential for life. Yet our understanding of this process on a molecular level is limited, mostly hampered by the inability to visualize the different components of the division machinery inside these tiny cells with adequate resolution. To overcome this barrier, capitalizing on recent advancements in imaging and molecular technologies combined with innovative engineering, this proj ....Creation of a super-resolution map of the bacterial cytokinesis machinery . Cell division is a fundamental process essential for life. Yet our understanding of this process on a molecular level is limited, mostly hampered by the inability to visualize the different components of the division machinery inside these tiny cells with adequate resolution. To overcome this barrier, capitalizing on recent advancements in imaging and molecular technologies combined with innovative engineering, this project aims to create a spatial and temporal map of the division machinery inside bacterial cells at unprecedented resolution. The expected outcomes are new knowledge on the mechanism of bacterial division and technological advances in biological imaging, informing applications in a wide variety of sectors.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100295
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Computational modelling of nanostructures designed to mimic ion-selective biological channels. The project aims to design nanotubes (hollow tubes with nanometre diameters) constructed from various materials, such as carbon, to broadly mimic biological ion channels. This research will facilitate the development of efficient desalination membranes, potent antibiotics and pharmaceutical products for treatments of cancer and cystic fibrosis.
Bioinks that Advance 3D bioprinting of cells to the 4th dimension. The aim of this research is to provide a simple method for creating complex 3D cell cultures for in vitro cell based assays using 3D printing. A versatile polymer system as a bioink made from entirely commercially available components, will be advanced that gives a full range of soft tissue mimics and which can be dynamically change on-demand after printing of the 3D cell cultures. The latter will provide in vitro mimics of in vi ....Bioinks that Advance 3D bioprinting of cells to the 4th dimension. The aim of this research is to provide a simple method for creating complex 3D cell cultures for in vitro cell based assays using 3D printing. A versatile polymer system as a bioink made from entirely commercially available components, will be advanced that gives a full range of soft tissue mimics and which can be dynamically change on-demand after printing of the 3D cell cultures. The latter will provide in vitro mimics of in vivo events never previously possible with more realistic models of what is found in vivo. Applications are in fundamental cell biology, studying diseases and developing new drugs. The outcomes from this research will be new knowledge on designing cheap extracellular matrix mimics and high throughout 3D cell assays.Read moreRead less