TeraHertz Cell Cluster Imaging. With this program, Australia will benefit from the interaction between physics, engineering, biology and medicine to develop a new TeraHertz imaging system. The project will identify the factors that contribute to TeraHertz contrast in soft tissue cell cultures, thereby developing a non-invasive imaging system to show contrast between diseased and healthy cells. This is a fundamental step towards a system for diagnosing disease states of skin cells, for example, t ....TeraHertz Cell Cluster Imaging. With this program, Australia will benefit from the interaction between physics, engineering, biology and medicine to develop a new TeraHertz imaging system. The project will identify the factors that contribute to TeraHertz contrast in soft tissue cell cultures, thereby developing a non-invasive imaging system to show contrast between diseased and healthy cells. This is a fundamental step towards a system for diagnosing disease states of skin cells, for example, the early detection of melanoma. Ultimately, Australia will benefit from a new technology, and new diagnostic biomedical techniques, for rapid, non-invasive and reliable skin cancer diagnosis.Read moreRead less
Multiphoton microscopy through tissue turbid media. The aim of this proposal is to conduct the collaborative project on multi-photon microscopic imaging through biological tissue, which has been recently initiated between Swinburne University of Technology (SUT) and Massachusetts Institute of Technology (MIT). It will integrate the special skills, two-photon fluorescence endoscopy and second-harmonic coherence tomography, investigated in the respective collaborating institutes, to develop a nove ....Multiphoton microscopy through tissue turbid media. The aim of this proposal is to conduct the collaborative project on multi-photon microscopic imaging through biological tissue, which has been recently initiated between Swinburne University of Technology (SUT) and Massachusetts Institute of Technology (MIT). It will integrate the special skills, two-photon fluorescence endoscopy and second-harmonic coherence tomography, investigated in the respective collaborating institutes, to develop a novel method for detecting/imaging cancer cells that are located at 1 mm below tissue surfaces, while they are still in the early stage to be cured. Consequently, a diagnostic method for early cancer detection particularly through skin tissue becomes possible.Read moreRead less
Breaking The Wavelength Barrier: Near-Field T-ray Imaging. Australia will benefit from the interaction between engineering, physics, and biology to develop a new T-ray imaging system that will ultimately be able to probe microstructures, biological single cells or even neurons. The project will exploit a powerful new electrooptical technique for obtaining chemical 'fingerprints' at the cellular level. This breakthrough will be a fundamental step towards a system for probing disease states of sin ....Breaking The Wavelength Barrier: Near-Field T-ray Imaging. Australia will benefit from the interaction between engineering, physics, and biology to develop a new T-ray imaging system that will ultimately be able to probe microstructures, biological single cells or even neurons. The project will exploit a powerful new electrooptical technique for obtaining chemical 'fingerprints' at the cellular level. This breakthrough will be a fundamental step towards a system for probing disease states of single cells and will open up new lines of scientific enquiry. Ultimately, Australia will benefit from a new technology and new diagnostic biomedical techniques. This is potentially an enabling technology for future customised medicine, where rapid biochip sensing becomes foreseeable.Read moreRead less
Towards a miniaturised on-chip terahertz biosensing system. Terahertz (or T-ray) radiation is highly sensitive to minute changes in the molecular structure of many substances. Furthermore most packing materials are transparent to this new form of radiation. This implies enormous potential for T-rays in a range of applications from quality control via non-invasive contact-less chemical fingerprinting through to safety and security applications. A detailed study of the molecular vibrations that gi ....Towards a miniaturised on-chip terahertz biosensing system. Terahertz (or T-ray) radiation is highly sensitive to minute changes in the molecular structure of many substances. Furthermore most packing materials are transparent to this new form of radiation. This implies enormous potential for T-rays in a range of applications from quality control via non-invasive contact-less chemical fingerprinting through to safety and security applications. A detailed study of the molecular vibrations that give rise to these fingerprints will help chemists and biologists to learn more about the underlying molecular binding forces, impacting on wide applications for safe non-invasive sensing in the medical, security, chemical and food industries.Read moreRead less