Bessel Light Sheet Structured Illumination Microscopy

Biomedical study researchers using animals to model disease and treatment need fast, deep, noninvasive, and inexpensive multi-channel imaging methods. Traditional fluorescence microscopy meets those criteria to an extent. Specifically, two-photon and confocal microscopy, the two most commonly used m...

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Main Author: Noshirvani Allahabadi, Golchehr
Other Authors: Visscher, Koen
Language:en_US
Published: The University of Arizona. 2016
Subjects:
Online Access:http://hdl.handle.net/10150/621810
http://arizona.openrepository.com/arizona/handle/10150/621810
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spelling ndltd-arizona.edu-oai-arizona.openrepository.com-10150-6218102016-12-23T03:00:31Z Bessel Light Sheet Structured Illumination Microscopy Noshirvani Allahabadi, Golchehr Noshirvani Allahabadi, Golchehr Visscher, Koen Peng, Leilei Peng, Leilei Visscher, Koen Mansuripur, Masoud Manne, Srinivas Wolgemuth, Charles Bio medical imaging Fluorescence Microscopy Light Sheet Imaging Physics Bessel Light Sheet Biomedical study researchers using animals to model disease and treatment need fast, deep, noninvasive, and inexpensive multi-channel imaging methods. Traditional fluorescence microscopy meets those criteria to an extent. Specifically, two-photon and confocal microscopy, the two most commonly used methods, are limited in penetration depth, cost, resolution, and field of view. In addition, two-photon microscopy has limited ability in multi-channel imaging. Light sheet microscopy, a fast developing 3D fluorescence imaging method, offers attractive advantages over traditional two-photon and confocal microscopy. Light sheet microscopy is much more applicable for in vivo 3D time-lapsed imaging, owing to its selective illumination of tissue layer, superior speed, low light exposure, high penetration depth, and low levels of photobleaching. However, standard light sheet microscopy using Gaussian beam excitation has two main disadvantages: 1) the field of view (FOV) of light sheet microscopy is limited by the depth of focus of the Gaussian beam. 2) Light-sheet images can be degraded by scattering, which limits the penetration of the excitation beam and blurs emission images in deep tissue layers. While two-sided sheet illumination, which doubles the field of view by illuminating the sample from opposite sides, offers a potential solution, the technique adds complexity and cost to the imaging system. We investigate a new technique to address these limitations: Bessel light sheet microscopy in combination with incoherent nonlinear Structured Illumination Microscopy (SIM). Results demonstrate that, at visible wavelengths, Bessel excitation penetrates up to 250 microns deep in the scattering media with single-side illumination. Bessel light sheet microscope achieves confocal level resolution at a lateral resolution of 0.3 micron and an axial resolution of 1 micron. Incoherent nonlinear SIM further reduces the diffused background in Bessel light sheet images, resulting in confocal quality images in thick tissue. The technique was applied to live transgenic zebra fish tg(kdrl:GFP), and the sub-cellular structure of fish vasculature genetically labeled with GFP was captured in 3D. The superior speed of the microscope enables us to acquire signal from 200 layers of a thick sample in 4 minutes. The compact microscope uses exclusively off-the-shelf components and offers a low-cost imaging solution for studying small animal models or tissue samples. 2016 text Electronic Dissertation http://hdl.handle.net/10150/621810 http://arizona.openrepository.com/arizona/handle/10150/621810 en_US Copyright © is held by the author. Digital access to this material is made possible by the University Libraries, University of Arizona. Further transmission, reproduction or presentation (such as public display or performance) of protected items is prohibited except with permission of the author. The University of Arizona.
collection NDLTD
language en_US
sources NDLTD
topic Bio medical imaging
Fluorescence Microscopy
Light Sheet Imaging
Physics
Bessel Light Sheet
spellingShingle Bio medical imaging
Fluorescence Microscopy
Light Sheet Imaging
Physics
Bessel Light Sheet
Noshirvani Allahabadi, Golchehr
Noshirvani Allahabadi, Golchehr
Bessel Light Sheet Structured Illumination Microscopy
description Biomedical study researchers using animals to model disease and treatment need fast, deep, noninvasive, and inexpensive multi-channel imaging methods. Traditional fluorescence microscopy meets those criteria to an extent. Specifically, two-photon and confocal microscopy, the two most commonly used methods, are limited in penetration depth, cost, resolution, and field of view. In addition, two-photon microscopy has limited ability in multi-channel imaging. Light sheet microscopy, a fast developing 3D fluorescence imaging method, offers attractive advantages over traditional two-photon and confocal microscopy. Light sheet microscopy is much more applicable for in vivo 3D time-lapsed imaging, owing to its selective illumination of tissue layer, superior speed, low light exposure, high penetration depth, and low levels of photobleaching. However, standard light sheet microscopy using Gaussian beam excitation has two main disadvantages: 1) the field of view (FOV) of light sheet microscopy is limited by the depth of focus of the Gaussian beam. 2) Light-sheet images can be degraded by scattering, which limits the penetration of the excitation beam and blurs emission images in deep tissue layers. While two-sided sheet illumination, which doubles the field of view by illuminating the sample from opposite sides, offers a potential solution, the technique adds complexity and cost to the imaging system. We investigate a new technique to address these limitations: Bessel light sheet microscopy in combination with incoherent nonlinear Structured Illumination Microscopy (SIM). Results demonstrate that, at visible wavelengths, Bessel excitation penetrates up to 250 microns deep in the scattering media with single-side illumination. Bessel light sheet microscope achieves confocal level resolution at a lateral resolution of 0.3 micron and an axial resolution of 1 micron. Incoherent nonlinear SIM further reduces the diffused background in Bessel light sheet images, resulting in confocal quality images in thick tissue. The technique was applied to live transgenic zebra fish tg(kdrl:GFP), and the sub-cellular structure of fish vasculature genetically labeled with GFP was captured in 3D. The superior speed of the microscope enables us to acquire signal from 200 layers of a thick sample in 4 minutes. The compact microscope uses exclusively off-the-shelf components and offers a low-cost imaging solution for studying small animal models or tissue samples.
author2 Visscher, Koen
author_facet Visscher, Koen
Noshirvani Allahabadi, Golchehr
Noshirvani Allahabadi, Golchehr
author Noshirvani Allahabadi, Golchehr
Noshirvani Allahabadi, Golchehr
author_sort Noshirvani Allahabadi, Golchehr
title Bessel Light Sheet Structured Illumination Microscopy
title_short Bessel Light Sheet Structured Illumination Microscopy
title_full Bessel Light Sheet Structured Illumination Microscopy
title_fullStr Bessel Light Sheet Structured Illumination Microscopy
title_full_unstemmed Bessel Light Sheet Structured Illumination Microscopy
title_sort bessel light sheet structured illumination microscopy
publisher The University of Arizona.
publishDate 2016
url http://hdl.handle.net/10150/621810
http://arizona.openrepository.com/arizona/handle/10150/621810
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