Development Of A Simple Chemical Test For Detecting DNA-interacting Compounds For Medical And
Funder
National Health and Medical Research Council
Funding Amount
$315,450.00
Summary
The project exploits a simple chemical reaction to detect and measure the interaction of compounds with DNA. The test will be useful in the early screening of drug candidates for genotoxicity, identifying new anticancer drugs and also find application in the environmental, cosmetic and food industries. Work will focus on establishing peak conditions for the test, determining the scope of application, testing a panel of control compounds and performing a blind study to provide proof of concept.
Spectrometer Module For Surface Enhanced Raman Scattering Spectroscopy In Glucose Analysis
Funder
National Health and Medical Research Council
Funding Amount
$385,151.00
Summary
Scientists have developed a number of incredibly powerful and sophisticated techniques to identify chemicals and measure their concentrations in the laboratory. However, it remains a major challenge to perform these measurements under everyday circumstances. For example, surface-enhanced Raman scattering (SERS) has gained widespread recognition as a technique for trace chemical detection, but it remains confined to a small number of specialist laboratories. For this reason, Dr Paul Stoddart at S ....Scientists have developed a number of incredibly powerful and sophisticated techniques to identify chemicals and measure their concentrations in the laboratory. However, it remains a major challenge to perform these measurements under everyday circumstances. For example, surface-enhanced Raman scattering (SERS) has gained widespread recognition as a technique for trace chemical detection, but it remains confined to a small number of specialist laboratories. For this reason, Dr Paul Stoddart at Swinburne University of Technology recognised a need for more practical SERS probes for field applications. His team has now developed a proprietary SERS probe, based on an optical fibre that is little thicker than a hair. These optical fibres can form the core element of field-portable SERS spectrometers. This work has recently been boosted by the discovery in the United States that SERS can be used to monitor glucose in blood. The development of a continuous glucose monitor has long been a holy grail of sensor research, because of the millions of diabetes sufferers who regularly perform the painful finger prick test. For SERS to provide a practical solution to glucose monitoring, it is recognised that SERS optical fibres are needed for minimally invasive probes. With support from Biopharmica and the Diabetes Australia Research Trust, Dr Stoddart's team has now demonstrated that sensitive SERS probes can be produced in large quantities. The next objective is to develop a prototype low-cost SERS spectrometer for use as part of a continuous glucose monitoring system. This will require the development of a laser source and spectroscopic system that can interface to the SERS probes. It is proposed to use an Australian designed and manufactured laser system based on a low-power narrow-linewidth laser diode. The project plans to bring together Swinburne University, OptoTech and Grey Innovation in order to develop a commercially scaleable and robust device.Read moreRead less
We will conduct a clinical trial of the effectiveness of a continuous auditory display of an anesthetized patient's respiratory status. Expired carbon dioxide monitoring has helped reduce respiratory incidents since its widespread introduction in the late 1980s, but a continuous auditory display of respiratory status may reduce incidents further. We will conduct a clinical trial with 10 anaesthetists of continuous auditory respiratory monitoring. Successful outcome may lead to commercial uptake.
Development Of A Prototype Production System For Optical Fibre Diagnostic Probes
Funder
National Health and Medical Research Council
Funding Amount
$191,598.00
Summary
Advances in nanotechnology have led to new techniques for the precise fabrication of nanometre scale structures. A recent breakthrough by the applicants now allows high-quality nanostructures to be stamped onto the tip of low-cost optical fibre probes. When coated with silver, these sensitive probes can be used for continuous monitoring of blood glucose in diabetics and in critical care situations. This project aims to develop a prototype manufacturing system for optical fibre glucose probes.
Development Of A PET Detection System Prototype With Depth Of Interaction Capability
Funder
National Health and Medical Research Council
Funding Amount
$360,906.00
Summary
This development project invovles the development of a slim-line Positron Emission Tomogrphy (PET) detection sub-module, the crucial component of PET scanners, that is small and extremely flexible. It is planned to utilize this module in the design of customized new commercial PET scanners ideal for diagnosing human brain and breast disorders. The development will proceed in collaboration with Insight Oceania-ADAC, Sydney. Insight Oceania-ADAC are very excited by the potential applications and f ....This development project invovles the development of a slim-line Positron Emission Tomogrphy (PET) detection sub-module, the crucial component of PET scanners, that is small and extremely flexible. It is planned to utilize this module in the design of customized new commercial PET scanners ideal for diagnosing human brain and breast disorders. The development will proceed in collaboration with Insight Oceania-ADAC, Sydney. Insight Oceania-ADAC are very excited by the potential applications and future markets (Australia and overseas) of the newly developing PET detection sub-modules for dedicated PET scanners. Positron Emission Tomography (PET) is a functional imaging tool, which is able to quantify physiological and biochemical processes in vivo, using short-lived cyclotron-produced radiotracers. PET is emerging as an extremely important diagnostic procedure used in the early detection of cancers, neurological diseases and as an aid in treatment monitoring and drug development. The unique advantage of PET over anatomical imaging techniques, such as X-ray CT and MRI, arises from its ability to measure changes in tumour biology, at the molecular level, prior to anatomical changes in involved tissues, using trace amounts of a radiolabelled compound (radiotracer). The full potential of PET however, is not being completely utilized due to constraints within the current designs of PET scanners. When used to its full potential PET, in principle, would be an excellent diagnostic and treatment monitoring tool for breast cancer, brain tumours and other neurological conditions such as epilepsy, Alzheimer's, Parkinson's disease, post stress disorder, dementia, and depression. Lack of flexibility in current PET scanner designs to date has meant that no commercial human brain or breast imaging scanners exist. Pilot project data proved the feasibility of our new flexible PET detection module design.Read moreRead less