Komplexní fotonika
Understanding life has huge implications on our development and wellbeing. The outstanding complexity of living organisms brings questions we can’t answer, because there are strong limitations of available technologies giving sufficiently detailed insight through scattering tissues.
Amongst other activities we develop a new class of endoscopes that can break through this barrier. This technology can potentially go as far as reaching super-resolution with instruments having a footprint comparable to the dimensions of a single cell. Project Gate2μ is supported from European Regional Development Fund (No. CZ.02.1.01/0.0/0.0/15_003/0000476) and progresses in synergy with ERC-Consolidator grant LIFEGATE hosted by Leibniz Institute of Photonic Technology in Jena.
Technological boost is essential for all aspect of our research agenda. Our activities focus on imaging with new types of multimode optical fibers. We focus mainly on gradient-index fibers, which offer low dispersion as well as high resilience to bending. |
Better understanding of light-transport processes will enable faster and more precise light control especially in highly dynamic regimes of imaging. Multimode fibres deliver light signals in the form of apparently random speckled patterns, in a very similar fashion to other random media. Although multimode fibres feature remarkably faithful cylindrical symmetry they are frequently classified as unpredictable optical systems. Our research challenges this commonly held notion. We develop holographic geometries for complete and accurate analysis of light signals traveling throughout the fibre and verify the observations by advanced numerical modelling. Harnessing the predictability of multimode waveguides in endoscopy will allow for numerous enhancements of deep tissue imaging. |
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Stephen Simpson |
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Label-free imaging with chemical contrast allows for the detection of the composition of tissues without the need of further chemical interventions (staining). It is based on the principles of Raman spectroscopy and it has been exploited in applications such as identifying bacteria and imaging lipid distribution in cells (relevant for cell metabolism and related disease conditions). Combined with holographic endoscopy, it has a great promise as a method for diagnosing tumors in sensitive and inaccessible locations such as pancreas and ovary, without performing a biopsy and associated time consuming histopathology. |
In-vivo applications represents the culmination of our efforts to introduce new imaging platform for observations inside living organisms. The methodology of holographic endoscopy utilises light transport through standard multimode optical fibres to perform lensless minimally invasive micro-endoscopy. These possibilities represent a great promise for in-vivo bio-medical imaging, allowing advanced methods such microscopy to be introduced into deep regions of unrestraint and awake animal models. Our current research efforts focus on allowing these methods in flexible geometries, increasing the speed of acquisition and first in-vivo experiments in animal models. |
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Johanna Trägårdh |
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Latest publications:
Sergey Turtaev, Ivo T. Leite, Kevin J. Mitchell, Miles J. Padgett, David B. Phillips, & Tomáš Čižmár, "Comparison of nematic liquid-crystal and DMD based spatial light modulation in complex photonics," Opt. Express 25, 29874-29884 (2017)
Ivo T. Leite, Sergey Turtaev, Xin Jiang, Martin Šiler, Alfred Cuschieri, Philip St.J. Russell, & Tomáš Čižmár, "3-D holographic optical manipulation through high-NA soft-glass multimode fibre,” Nature Photonics (advanced online publication) (2017)
Team leader: Tomáš Čižmár
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