Spectrometer Module for Surface Enhanced Raman Scattering Spectroscopy in Glucose Analysis [ 2008 - 2008 ]

Research Grant

Researchers: Dr Paul Stoddart (Principal investigator)

Brief description 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.

Funding Amount $AUD 385,151.36

Funding Scheme NHMRC Development Grants

Notes Development Grant