Perturbation of the extracellular architecture to promote the absorption and lymphatic transport of biological macromolecules. Macromolecules therapeutics such as proteins, antibodies or polymer conjugates pose a number of pharmaceutical challenges. Where the dose is high, drainage of that dose from a subcutaneous injection site into the circulation, poses a particular problem. Here the project aims to explore how recombinant hyaluronidase, an enzyme that breaks down a structural component (hya ....Perturbation of the extracellular architecture to promote the absorption and lymphatic transport of biological macromolecules. Macromolecules therapeutics such as proteins, antibodies or polymer conjugates pose a number of pharmaceutical challenges. Where the dose is high, drainage of that dose from a subcutaneous injection site into the circulation, poses a particular problem. Here the project aims to explore how recombinant hyaluronidase, an enzyme that breaks down a structural component (hyaluronan) of the interstitum, can be used promote absorption into the draining blood and lymph capillaries. The project aims to also explore the downstream effects of hyaluronidase on lymph nodes and evaluate whether the enzyme is able to temporarily disrupt the lymph node structure and promote drug penetration into the lymph node mass. This has significant potential for improved drug targeting.Read moreRead less
Artificial intelligence to explore and combat eukaryotic pathogens. The revolution in artificial intelligence (AI) provides unprecedented opportunities for integrative analyses of complex multi-omics data sets and for creating radically new strategies to control some of the world’s most serious animal diseases. In a strong partnership with international experts, we will use AI-based methods to make major conceptual advances in our understanding of eukaryotic pathogens and host-pathogen interacti ....Artificial intelligence to explore and combat eukaryotic pathogens. The revolution in artificial intelligence (AI) provides unprecedented opportunities for integrative analyses of complex multi-omics data sets and for creating radically new strategies to control some of the world’s most serious animal diseases. In a strong partnership with international experts, we will use AI-based methods to make major conceptual advances in our understanding of eukaryotic pathogens and host-pathogen interactions, discover the "choke-points" in biological pathways, and develop novel treatments, vaccines and diagnostics. This leap forward will substantially enhance the global profile of pathogen research in Australia, build major capacity in a priority area, and enable access to international research funding and networks.Read moreRead less
Synergising nanoemulsion and lipid biomimetic design for advanced delivery. This project aims to identify the critical design characteristics of lipid formulations of lipid-modified probes or drugs (lipid biomimetics) that together promote integration into lipid absorption pathways and target the lymphatic system that drains the small intestine. This has significant potential since the intestinal lymphatic system is a key immune tissue, the site of immune response to autoantigens and antigens de ....Synergising nanoemulsion and lipid biomimetic design for advanced delivery. This project aims to identify the critical design characteristics of lipid formulations of lipid-modified probes or drugs (lipid biomimetics) that together promote integration into lipid absorption pathways and target the lymphatic system that drains the small intestine. This has significant potential since the intestinal lymphatic system is a key immune tissue, the site of immune response to autoantigens and antigens derived from food and the microbiome. The project will deliver a design roadmap of the required characteristics for lymphatic targeting, and in particular, will identify novel lipid nanoemulsions that work synergistically with lipid biomimetics to enhance lymphatic imaging and delivery applications.Read moreRead less
Micro- and nano-particulate delivery systems for chemical and biological weapons: physical characterisation and risk assessment. Inert solid powder has been used as a carrier for chemical and biologically-active agents to increase their effectiveness in a range of applications such as chemical weapons, pesticides and insecticides. The aim of this research is to determine the influence of the physical characteristics of particulate delivery systems on their ability to deliver potentially toxic s ....Micro- and nano-particulate delivery systems for chemical and biological weapons: physical characterisation and risk assessment. Inert solid powder has been used as a carrier for chemical and biologically-active agents to increase their effectiveness in a range of applications such as chemical weapons, pesticides and insecticides. The aim of this research is to determine the influence of the physical characteristics of particulate delivery systems on their ability to deliver potentially toxic substances to exposed skin and through protective clothing. This data will provide the first step in the design and development of effective protective clothing/products and safety protocols to safeguard the health of Australians involved in the defence of Australia.Read moreRead less
Controlling the spatial distribution of targeting ligands on dendrimer surfaces as a means of dictating cellular recognition and fate. This project seeks to develop next generation targeted drug delivery systems that 'home' to specific target cells, including cancers. Targeted delivery systems have the potential to revolutionise therapy by providing bespoke drug distribution patterns that are tailored to specific diseases and result in enhanced activity and reduced toxicity.
A VAST potential for ion channel drug discovery. The purpose of this project is to bring innovation into the methods used for identifying and characterising novel carbohydrate-based compounds acting at ion channels. These molecules will have high potential to be developed as highly effective treatments for pain without the unpleasant side-effects associated with current treatments.
Efficacy profiling innovation in novel pain therapeutics discovery. The purpose of this project is to bring innovation into the methods used for selecting novel compounds with high potential for progression into development as highly effective pain-killers for improving the relief of chronic pain. This will result in new pain-killers that are highly effective without producing unpleasant side-effects.
Targeting particulate carriers to epithelial M cells. This project aims to develop and validate an advanced in vitro model of the human intestinal epithelium. The intestine-on-chip model should enable mechanistic studies of the uptake of nano- and micron-size particles by intestinal cells and deliver new insights into the way particulate carriers can be specifically targeted and transported across the intestinal epithelium. Project knowledge and technology are anticipated to generate new commerc ....Targeting particulate carriers to epithelial M cells. This project aims to develop and validate an advanced in vitro model of the human intestinal epithelium. The intestine-on-chip model should enable mechanistic studies of the uptake of nano- and micron-size particles by intestinal cells and deliver new insights into the way particulate carriers can be specifically targeted and transported across the intestinal epithelium. Project knowledge and technology are anticipated to generate new commercialisation opportunities in the oral delivery industry and ultimately, should drive the development of efficient oral formulations for biologics. The model should also reduce the need for animal studies.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
Drug Targeting to Immune Cells Using Modified Inulin Particles. Vaxine Pty Ltd is an Australian biotechnology company that has discovered specific particulate forms of inulin that are efficiently internalised by human immune cells. This project aims to exploit cell migration to injury and infection sites by attaching drugs to inulin particles creating a targeted drug delivery system. This system will transport drugs specifically to afflicted areas, reducing systemic concentrations of drugs and h ....Drug Targeting to Immune Cells Using Modified Inulin Particles. Vaxine Pty Ltd is an Australian biotechnology company that has discovered specific particulate forms of inulin that are efficiently internalised by human immune cells. This project aims to exploit cell migration to injury and infection sites by attaching drugs to inulin particles creating a targeted drug delivery system. This system will transport drugs specifically to afflicted areas, reducing systemic concentrations of drugs and hence the risks of dose related side effects. This project has potential both to improve healthcare and to encourage the growth of expertise in the biotechnology industry in Australia.Read moreRead less