Computational image enhancement of multimode fibre-based holographic endo-microscopy: harnessing the muddy modes

journal article in Web of Science

English

In imaging geometries, which employ wavefront-shaping to control the light transport through a multi-mode optical fibre (MMF), this terminal hair-thin optical component acts as a minimally invasive objective lens, enabling high resolution laser-scanning fluorescence microscopy inside living tissues at depths hardly accessible by any other light-based technique. Even in the most advanced systems, the diffraction-limited foci scanning the object across the focal plane are contaminated by a stray optical signal carrying typically few tens of % of the total optical power. The stray illumination takes the shape of a randomised but reproducible speckle, and is unique for each position of the focus. We experimentally demonstrate that the performance of imaging a fluorescent object can be significantly improved, when resulting images are computationally post-processed, utilising records of intensities of all speckle-contaminated foci used in the imaging procedure. We present two algorithms based on a regularised iterative inversion and regularised direct pseudo-inversion respectively which lead to enhancement of the image contrast and resolution. (C) 2021 Optical Society of America under the terms of the OSA Open Access Publishing Agreement

LIGHT; TRANSFORMATION; TRANSMISSION; RESOLUTION; PHASE

TUČKOVÁ, T.; ŠILER, M.; FLAES, D.; JÁKL, P.; TURTAEV, S.; KRÁTKÝ, S.; HEINTZMANN, R.; UHLÍŘOVÁ, H.; ČIŽMÁR, T.

8. 11. 2021

Optica Publishing Group

WASHINGTON

1094-4087

OPTICS EXPRESS

29

23

United States of America

38206

38220

15

https://www.osapublishing.org/oe/fulltext.cfm?uri=oe-29-23-38206&id=464465

http://hdl.handle.net/11012/203100