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Controlling light propagation in multimode fibers for imaging, spectroscopy, and beyond. Adv. Opt. Photon., 15, 524?612 (2023202320232023).\par \par Hybrid multimode - multicore fibre based holographic endoscope for deep-tissue neurophotonics. Light: Advanced Manufacturing, 3, 1 (2022202220222022).\par \par Near perfect focusing through multimode fibres. Opt. Express, 30, 10645?10663 (2022202220222022).\par \par Neurophotonic tools for microscopic measurements and manipulation: status report. Neurophotonics, 9, (2022202220222022).\par \par Roadmap on wavefront shaping and deep imaging in complex media. Journal of Physics: Photonics, 4, 042501 (2022202220222022).\par \par All-optical manipulation of photonic membranes. Opt. Express, 29, 14260?14268 (2021202120212021).\par \par Computational image enhancement of multimode fibre-based holographic endo-microscopy: harnessing the muddy modes. Opt. Express, 29, 38206?38220 (2021202120212021).\par \par Side-view holographic endomicroscopy via a custom-terminated multimode fibre. Opt. Express, 29, 23083?23095 (2021202120212021).\par \par Thermal stability of wavefront shaping using a DMD as a spatial light modulator. Opt. Express, 29, 41808?41818 (2021202120212021).\par \par Time-averaged image projection through a multimode fiber. Opt. Express, 29, 28005?28020 (2021202120212021).\par \par Time-of-flight 3D imaging through multimode optical fibers. Science, 374, 1395-1399 (2021202120212021).\par \par Label-free CARS microscopy through a multimode fiber endoscope. Opt. Express, 27, 30055?30066 (2019201920192019).\par \par Nanobore fiber focus trap with enhanced tuning capabilities. Opt. Express, 27, 36221?36230 (2019201920192019).\par \par Wavelength dependent characterization of a multimode fibre endoscope. Opt. Express, 27, 28239?28253 (2019201920192019).\par \par High-fidelity multimode fibre-based endoscopy for deep brain in vivo imaging. Light: Sci. Appl., 7, 92 (2018201820182018).\par \par Robustness of Light-Transport Processes to Bending Deformations in Graded-Index Multimode Waveguides. Phys. Rev. Lett., 120, 233901:1-5 (2018201820182018).\par \par Subcellular spatial resolution achieved for deep-brain imaging in vivo using a minimally invasive multimode fiber. Light: Sci. Appl., 7, 110 (2018201820182018).\par \par Three-dimensional holographic optical manipulation through a high-numerical-aperture soft-glass multimode fibre. Nature Photon., 12, 33?39 (2018201820182018).\par \par Experimental demonstration of optical transport, sorting and self-arrangement using a `tractor beam'. Nature Photon., 7, 123-127 (2013201320132013).\par \par Speed enhancement of multi-particle chain in a travelingstanding wave. Appl. Phys. Lett., 100, 051103 (2012201220122012).\par \par Dynamic size tuning of multidimensional optically boundmatter. Appl. Phys. Lett., 99, 101105 (2011201120112011).\par \par The holographic optical micro-manipulation system basedon counter-propagating beams. Laser Phys. Lett., 8, 50?56 (2011201120112011).\par \par Experimental and theoretical determination of opticalbinding forces. Opt. Express, 18, 25389?25402 (2010201020102010).\par \par High quality quasi-Bessel beam generated by round-tipaxicon. Opt. Express, 16, 12688?12700 (2008200820082008).\par \par Long-range one-dimensional longitudinal opticalbinding. Phys. Rev. Lett., 101, 143601 (2008200820082008).\par \par Static optical sorting in a laser interference field. Appl. Phys. Lett., 92, 161110:1?3 (2008200820082008).\par \par Surface delivery of a single nanoparticle under movingevanescent standing-wave illumination. New. J. Phys., 10, 113010 (2008200820082008).\par \par Cellular and colloidal separation using optical forces. Methods in Cell Biology, 82, 467?495 (2007200720072007).\par \par Optical tracking of spherical micro-objects in spatially periodic interference fields. Opt. Express, 15, 2262?2272 (2007200720072007).\par \par Formation of long and thin polymer fiber using nondiffracting beam. Opt. Express, 14, 8506-8515 (2006200620062006).\par \par Optical forces generated by evanescent standing waves and their usage for sub-micron particle delivery. Appl. Phys. B, 84, 157?165 (2006200620062006).\par \par An optical nanotrap array movable over a milimetre range. Appl. Phys. B, 84, 197?203 (2006200620062006).\par \par Optical sorting and detection of sub-micron objects in a motional standing wave. Phys. Rev. B, 74, 035105:1-6 (2006200620062006).\par \par Sub-micron particle organization by self-imaging of non-diffracting beams. New. J. Phys., 8, 43 (2006200620062006).\par \par Optical conveyor belt for delivery of submicron objects. Appl. Phys. Lett., 86, 174101-1?174101-3 (2005200520052005).\par \par }