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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
Industrial Transformation Training Centres - Grant ID: IC170100016
Funder
Australian Research Council
Funding Amount
$3,123,492.00
Summary
ARC Training Centre for Personalised Therapeutics Technologies. The ARC Training Centre for Personalised Therapeutics Technologies aims to create and develop the skills and technology to benefit from the transformative impacts that cell/organ-on-a-chip technology will have on the medtech/pharma industries. By combining microfluidics-based/real-time technologies with personalised medicine the Training Centre will provide industry growth opportunities through improved screening of potential therap ....ARC Training Centre for Personalised Therapeutics Technologies. The ARC Training Centre for Personalised Therapeutics Technologies aims to create and develop the skills and technology to benefit from the transformative impacts that cell/organ-on-a-chip technology will have on the medtech/pharma industries. By combining microfluidics-based/real-time technologies with personalised medicine the Training Centre will provide industry growth opportunities through improved screening of potential therapeutics. The use of an individual patient’s cellular and molecular research findings will ultimately enable personalised diagnostic and therapeutic decisions.Read moreRead less
Nanoengineering materials to combat antimicrobial resistance. This project aims to understand how nanoengineered materials can be designed to kill bacteria and fungi without causing antimicrobial resistance. Resistance to antimicrobial drugs already leads to many thousands of deaths annually and costs society billions of dollars. Nanomaterials have unique abilities to attack microbes in multiple ways that could limit resistance. This project will engineer new antimicrobial nanomaterials tailored ....Nanoengineering materials to combat antimicrobial resistance. This project aims to understand how nanoengineered materials can be designed to kill bacteria and fungi without causing antimicrobial resistance. Resistance to antimicrobial drugs already leads to many thousands of deaths annually and costs society billions of dollars. Nanomaterials have unique abilities to attack microbes in multiple ways that could limit resistance. This project will engineer new antimicrobial nanomaterials tailored to selectively kill microbes with reduced likelihood of developing resistance by using synergies between inorganic nanoparticles and antimicrobial peptides. This technology could be used to prevent infections and biofilms on surfaces in a wide range of future applications, such as medical / veterinary devicesRead moreRead less
Drug Delivery Devices : Hydrogels manufactured utilising Dense Gas Technologies. Many drugs are rapidly eliminated from the human body, and would benefit from being released over a long period of time. In this study, formulations to deliver drugs will be developed, using hydrogels: highly cross-linked, water saturated polymers. The polymers to be investigated are based on ingredients suitable for ingestion. Hydrogels are in common use as external therapeutic devices, such as contact lenses or wo ....Drug Delivery Devices : Hydrogels manufactured utilising Dense Gas Technologies. Many drugs are rapidly eliminated from the human body, and would benefit from being released over a long period of time. In this study, formulations to deliver drugs will be developed, using hydrogels: highly cross-linked, water saturated polymers. The polymers to be investigated are based on ingredients suitable for ingestion. Hydrogels are in common use as external therapeutic devices, such as contact lenses or wound dressings. However, hydrogels are not commonly in use as ingested drug delivery devices due to problems with the existing technologies, such as toxicity of ingredients. These problems will be addressed in this study.Read moreRead less
Carbon Dioxide: Solvent, Carrier and Reagent, for novel polymer networks with controlled nano-architectures. The proposed environmentally friendly technology has broad applications for improving properties of various polymeric matrices used for biomedical applications. The process developed would value-add for manufacturing biomedical polymeric devices in Australia with licensing of existing fabrication methods as a best option. Moreover, the leading-edge polymer technology developed would mini ....Carbon Dioxide: Solvent, Carrier and Reagent, for novel polymer networks with controlled nano-architectures. The proposed environmentally friendly technology has broad applications for improving properties of various polymeric matrices used for biomedical applications. The process developed would value-add for manufacturing biomedical polymeric devices in Australia with licensing of existing fabrication methods as a best option. Moreover, the leading-edge polymer technology developed would minimise the organic solvent consumption and will attract business from international polymer and biotechnology companies for production of implant and drug delivery devices. The development of world-class research provides Australia with recognition as a world leader in the field and broadens the knowledge based of Australian scientist and engineers.Read moreRead less
A skin-on-a-chip device for investigating wound healing. This project aims to research the mechanism of skin wound healing. It will design a skin-on-a-chip microfluidic device that mimics human skin in vitro. This device will reduce the need for animal studies and assess how active compounds heal wounds. This project will design smart polymers with superior properties for controlled delivery of multiple active compounds in this device and choose the most effective combination of compounds to boo ....A skin-on-a-chip device for investigating wound healing. This project aims to research the mechanism of skin wound healing. It will design a skin-on-a-chip microfluidic device that mimics human skin in vitro. This device will reduce the need for animal studies and assess how active compounds heal wounds. This project will design smart polymers with superior properties for controlled delivery of multiple active compounds in this device and choose the most effective combination of compounds to boost skin healing rate. This knowledge may ultimately be used to develop wound dressings that maximise healing rate for various skin defects such as chronic wounds and decrease health care costs.Read moreRead less
Drug-delivery coating for a new generation of orthopaedic implants. In Australia, the number of people using artificial implants in orthopaedic and dental surgeries is rapidly increasing due to the higher average age of the population and higher expectations for an active and healthy life. The project will enhance the success rate of titanium implants by increasing the strength and stability of tissue at the interface between implant and host, particularly in case of hip joint implants, reducing ....Drug-delivery coating for a new generation of orthopaedic implants. In Australia, the number of people using artificial implants in orthopaedic and dental surgeries is rapidly increasing due to the higher average age of the population and higher expectations for an active and healthy life. The project will enhance the success rate of titanium implants by increasing the strength and stability of tissue at the interface between implant and host, particularly in case of hip joint implants, reducing the need for revision surgery. Read moreRead less
Blood component interactions with polysaccharide biomaterials for vascular applications. Heart disease is the major killer of people in Australia and the Western world. It is due mainly to the blockage of vessels supplying the muscle of the heart with blood and nutrients, which can be replaced or by-passed but the supply of native vessels in the body is limited. Tissue engineering laboratories have been trying to develop blood vessels for this use for many years without significant success. T ....Blood component interactions with polysaccharide biomaterials for vascular applications. Heart disease is the major killer of people in Australia and the Western world. It is due mainly to the blockage of vessels supplying the muscle of the heart with blood and nutrients, which can be replaced or by-passed but the supply of native vessels in the body is limited. Tissue engineering laboratories have been trying to develop blood vessels for this use for many years without significant success. This application plans to understand the molecular signals contained within the sugar sequences used in a commonly used biomaterial chitosan that may be used in the construction of synthetic vascular grafts. If we can understand how blood cells interact with this biomaterial, we may be able to develop a blood vessel in the laboratory.Read moreRead less
Nanoparticle formulations for DNA-targeted radiotherapy and imaging: combinations with chromatin-modifying compounds. This project will develop a new approach for treating and imaging cancer using nanoparticles which target specific cells for cancer therapy and diagnostic imaging. The nanoparticles will be combined with compounds that alter the architecture of DNA to make therapy more effective and to improve the safety of imaging.
Discovery Early Career Researcher Award - Grant ID: DE150101518
Funder
Australian Research Council
Funding Amount
$345,000.00
Summary
Cellular responses to nanoparticles from cells on micropatterned surfaces. The mechanisms underlying cell-nanoparticle interactions remain largely unknown. It has hampered the design and development of innovative nano devices to be used for drug delivery, biomarkers and diagnostics. This project aims to explore the influences of cell size, density, geometry, intercellular communication and substrate properties on cell-nanoparticle interactions. A micropatterning technology is applied to precisel ....Cellular responses to nanoparticles from cells on micropatterned surfaces. The mechanisms underlying cell-nanoparticle interactions remain largely unknown. It has hampered the design and development of innovative nano devices to be used for drug delivery, biomarkers and diagnostics. This project aims to explore the influences of cell size, density, geometry, intercellular communication and substrate properties on cell-nanoparticle interactions. A micropatterning technology is applied to precisely control cell behaviour and provide a novel in vitro cellular model for nanoparticle studies. This project aims to significantly improve the understanding of cell-nanoparticle interactions to provide new insight into nanoparticle design and improve the efficacy of nano devices.Read moreRead less