Plasmon nanobiosensor for whole blood analysis. The new method will be able to detect specific disease markers or to identify subtle differences in protein content in complex dense analytes such as blood and other body fluids, of practical utility in diagnostic and clinical situations. It will also be relevant in other areas such as medical diagnostics of viral diseases, and for unsolved environmental monitoring problems such as the presence of specific microorganisms in industrial waste. Owing ....Plasmon nanobiosensor for whole blood analysis. The new method will be able to detect specific disease markers or to identify subtle differences in protein content in complex dense analytes such as blood and other body fluids, of practical utility in diagnostic and clinical situations. It will also be relevant in other areas such as medical diagnostics of viral diseases, and for unsolved environmental monitoring problems such as the presence of specific microorganisms in industrial waste. Owing to their design simplicity and low cost of components, the devices developed in this program will lend themselves well to the development of new commercial technologies for Australia.Read moreRead less
Advancing x-ray imaging into new dimensions using interferometry and phase-space tomography. Synchrotron science and nanofabrication technologies are priority investment areas for most industrial countries including Australia. This research program takes advantages of recent progress in these fields and aims to advance x-ray imaging techniques of high sensitivity and low radiation dose and retrieve all extractable information of an object encoded in a wavefield. The development of these techniqu ....Advancing x-ray imaging into new dimensions using interferometry and phase-space tomography. Synchrotron science and nanofabrication technologies are priority investment areas for most industrial countries including Australia. This research program takes advantages of recent progress in these fields and aims to advance x-ray imaging techniques of high sensitivity and low radiation dose and retrieve all extractable information of an object encoded in a wavefield. The development of these techniques is critical to future opportunities of frontier discoveries of the biological, nano and atomic world. Its application includes structural biology, medical diagnosis, biomedicine, material sciences and many other fields.Read moreRead less
Amplifying light emission with metal-fluorophore nanostructures for ultrasensitive biosensing. This proposal focuses on translating nanotechnology to ultrasensitive molecular monitoring for biomedicine. We will apply a new tool, amplified fluorophores to proteomics where they will provide an improved method for early detection and understanding of diseases through molecular fingerprints. The project will also generate an ultra-sensitive, rapid technology that can be used for personalized point ....Amplifying light emission with metal-fluorophore nanostructures for ultrasensitive biosensing. This proposal focuses on translating nanotechnology to ultrasensitive molecular monitoring for biomedicine. We will apply a new tool, amplified fluorophores to proteomics where they will provide an improved method for early detection and understanding of diseases through molecular fingerprints. The project will also generate an ultra-sensitive, rapid technology that can be used for personalized point-of-care diagnostics. The applications can include the detection of disease markers, pathogens or the determination of protein content in a clinical sample. These technologies will be applicable across a spectrum or of diseases all of which will benefit the broader community.Read moreRead less
Control of Protein Attachment and its Optical Detection. Protein array technologies have applications in the rapid diagnosis of disease. Biosensors can detect traces of biohazards. Before widespread implementation of these technologies can occur however, a rapid, sensitive and convenient readout method for the control and readout of attachment of proteins to antibodies is needed. I will use electric fields, combined with array imaging at surface plasmon resonance to achieve this aim. This protei ....Control of Protein Attachment and its Optical Detection. Protein array technologies have applications in the rapid diagnosis of disease. Biosensors can detect traces of biohazards. Before widespread implementation of these technologies can occur however, a rapid, sensitive and convenient readout method for the control and readout of attachment of proteins to antibodies is needed. I will use electric fields, combined with array imaging at surface plasmon resonance to achieve this aim. This protein diagnostic array technology will enable accurate and rapid diagnosis of disease, generating savings on health costs and improving public health. Manufacture in Australia will bring further economic benefits.Read moreRead less