Interaction of light with tissues: A hyper-spectral approach . This project aims to address an important problem of noncontact assessment of tissue including skin and cartilage. By using extremely wide spectrum – between the terahertz and the near infrared – the effects of scattering and absorption arising from the variation of tissue properties from macro- to nano-scale will be explored. Spatial variations of tissue properties will be addressed in model and experiment by combining spectroscopy ....Interaction of light with tissues: A hyper-spectral approach . This project aims to address an important problem of noncontact assessment of tissue including skin and cartilage. By using extremely wide spectrum – between the terahertz and the near infrared – the effects of scattering and absorption arising from the variation of tissue properties from macro- to nano-scale will be explored. Spatial variations of tissue properties will be addressed in model and experiment by combining spectroscopy with the novel terahertz and mid-infrared Scanning Near field Optical Microscopy. The outcomes will advance fundamental understanding of light interaction with multi-layered tissues. This will provide a tool for advancing bioengineering research, terahertz technology, and development in biomedical devices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101331
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Fundamental electromagnetic modelling of light-biological tissue interactions: a platform for future medical microscopy. Methods for modelling the fundamental electromagnetic interaction of light with biological tissue will be developed. This will allow a range of biomedical optical images to be properly interpreted ultimately leading to the holy grail of quick and minimally invasive methods for detecting cancer.
Computed microscopy: solving the inverse problem of optical microscopy to image deeper into biological tissue. This project aims to enable 3D optical microscopy to image deeper within tissue, ultimately aiding research fields such as neurobiology. This will be achieved by a foundational approach called computed cicroscopy that combines novel numerical methods, high performance computing and optical microscopy. This project aims to develop a 3D quantitative imaging method that will provide unprec ....Computed microscopy: solving the inverse problem of optical microscopy to image deeper into biological tissue. This project aims to enable 3D optical microscopy to image deeper within tissue, ultimately aiding research fields such as neurobiology. This will be achieved by a foundational approach called computed cicroscopy that combines novel numerical methods, high performance computing and optical microscopy. This project aims to develop a 3D quantitative imaging method that will provide unprecedented insight into the structure of tissue with sub-cellular detail. This information can then be used to computationally reverse light scattering within the sample, allowing fluorescence microscopy at unprecedented depths within tissue.Read moreRead less