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Fluorescence microscopy shadow imaging for neuroscience

Fluorescence microscopy shadow imaging for neuroscience
Fluorescence microscopy shadow imaging for neuroscience

Fluorescence microscopy remains one of the single most widely applied experimental approaches in neuroscience and beyond and is continuously evolving to make it easier and more versatile. The success of the approach is based on synergistic developments in imaging technologies and fluorophore labeling strategies that have allowed it to greatly diversify and be used across preparations for addressing structure as well as function. Yet, while targeted labeling strategies are a key strength of fluorescence microscopy, they reciprocally impose general limitations on the possible types of experiments and analyses. One recent development that overcomes some of these limitations is fluorescence microscopy shadow imaging, where membrane-bound cellular structures remain unlabeled while the surrounding extracellular space is made to fluoresce to provide a negative contrast shadow image. When based on super-resolution STED microscopy, the technique in effect provides a positive image of the extracellular space geometry and entire neuropil in the field of view. Other noteworthy advantages include the near elimination of the adverse effects of photobleaching and toxicity in live imaging, exhaustive and homogeneous labeling across the preparation, and the ability to apply and adjust the label intensity on the fly. Shadow imaging is gaining popularity and has been applied on its own or combined with conventional positive labeling to visualize cells and synaptic proteins in their parenchymal context. Here, we highlight the inherent limitations of fluorescence microscopy and conventional labeling and contrast these against the pros and cons of recent shadow imaging approaches. Our aim is to describe the brief history and current trajectory of the shadow imaging technique in the neuroscience field, and to draw attention to its ease of application and versatility.

brain extracellular space, fluorescence microscopy, neuroscience, shadow imaging, STED microscopy, super-resolution microscopy, SUSHI, two-photon imaging
1662-5102
Inavalli, V.V.G. Krishna
db7ab576-a272-4f04-b938-3d1772ffbd01
Puente Muñoz, Virginia
2cb93ee7-9b75-4fcf-952e-73257c061499
Draffin, Jonathan E.
192a9fa2-03e7-485d-831f-d53ce0b98311
Tønnesen, Jan
30c73d5c-558e-4e3a-bd4a-ada172e1211d
Inavalli, V.V.G. Krishna
db7ab576-a272-4f04-b938-3d1772ffbd01
Puente Muñoz, Virginia
2cb93ee7-9b75-4fcf-952e-73257c061499
Draffin, Jonathan E.
192a9fa2-03e7-485d-831f-d53ce0b98311
Tønnesen, Jan
30c73d5c-558e-4e3a-bd4a-ada172e1211d

Inavalli, V.V.G. Krishna, Puente Muñoz, Virginia, Draffin, Jonathan E. and Tønnesen, Jan (2024) Fluorescence microscopy shadow imaging for neuroscience. Frontiers in Cellular Neuroscience, 18, [1330100]. (doi:10.3389/fncel.2024.1330100).

Record type: Review

Abstract

Fluorescence microscopy remains one of the single most widely applied experimental approaches in neuroscience and beyond and is continuously evolving to make it easier and more versatile. The success of the approach is based on synergistic developments in imaging technologies and fluorophore labeling strategies that have allowed it to greatly diversify and be used across preparations for addressing structure as well as function. Yet, while targeted labeling strategies are a key strength of fluorescence microscopy, they reciprocally impose general limitations on the possible types of experiments and analyses. One recent development that overcomes some of these limitations is fluorescence microscopy shadow imaging, where membrane-bound cellular structures remain unlabeled while the surrounding extracellular space is made to fluoresce to provide a negative contrast shadow image. When based on super-resolution STED microscopy, the technique in effect provides a positive image of the extracellular space geometry and entire neuropil in the field of view. Other noteworthy advantages include the near elimination of the adverse effects of photobleaching and toxicity in live imaging, exhaustive and homogeneous labeling across the preparation, and the ability to apply and adjust the label intensity on the fly. Shadow imaging is gaining popularity and has been applied on its own or combined with conventional positive labeling to visualize cells and synaptic proteins in their parenchymal context. Here, we highlight the inherent limitations of fluorescence microscopy and conventional labeling and contrast these against the pros and cons of recent shadow imaging approaches. Our aim is to describe the brief history and current trajectory of the shadow imaging technique in the neuroscience field, and to draw attention to its ease of application and versatility.

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fncel-18-1330100 - Version of Record
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Accepted/In Press date: 1 February 2024
e-pub ahead of print date: 15 February 2024
Published date: 15 February 2024
Additional Information: Publisher Copyright: Copyright © 2024 Inavalli, Puente Muñoz, Draffin and Tønnesen.
Keywords: brain extracellular space, fluorescence microscopy, neuroscience, shadow imaging, STED microscopy, super-resolution microscopy, SUSHI, two-photon imaging

Identifiers

Local EPrints ID: 488298
URI: http://eprints.soton.ac.uk/id/eprint/488298
ISSN: 1662-5102
PURE UUID: 74f235c3-f2f5-4957-8db8-9630a5cb7b9a
ORCID for V.V.G. Krishna Inavalli: ORCID iD orcid.org/0000-0002-7100-0214

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Date deposited: 19 Mar 2024 18:12
Last modified: 02 May 2024 01:58

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Contributors

Author: V.V.G. Krishna Inavalli ORCID iD
Author: Virginia Puente Muñoz
Author: Jonathan E. Draffin
Author: Jan Tønnesen

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