Sample and substrate preparation for exploring living neurons in culture with quantitative-phase imaging.

Details

Serval ID
serval:BIB_3204F8AC5272
Type
Article: article from journal or magazin.
Collection
Publications
Title
Sample and substrate preparation for exploring living neurons in culture with quantitative-phase imaging.
Journal
Methods
Author(s)
Lévesque S.A., Mugnes J.M., Bélanger E., Marquet P.
ISSN
1095-9130 (Electronic)
ISSN-L
1046-2023
Publication state
Published
Issued date
01/03/2018
Peer-reviewed
Oui
Volume
136
Pages
90-107
Language
english
Notes
Publication types: Journal Article ; Research Support, Non-U.S. Gov't ; Review
Publication Status: ppublish
Abstract
Quantitative-phase imaging (QPI) has recently emerged as a powerful new quantitative microscopy technique suitable for the noninvasive exploration of the structure and dynamics of transparent specimens, including living cells in culture. Indeed, the quantitative-phase signal (QPS), induced by transparent living cells, can be detected with a nanometric axial sensitivity, and contains a wealth of information about both cell morphology and content. However, QPS is also sensitive to various sources of experimental noise. In this chapter, we emphasize how to properly and specifically measure the cell-mediated QPS in a wet-lab environment, when measuring with a digital holographic microscope (DHM). First, we present the substrate-requisite characteristics for properly achieving such cell-mediated QPS measurements at single-cell level. Then, we describe how quantitative-phase digital holographic microscopy (QP-DHM) can be used to numerically process holograms and subsequently reshape wavefronts in association with post-processing algorithms, thereby allowing for highly stable QPS obtainable over extended periods of time. Such stable QPS is a prerequisite for exploring the dynamics of specific cellular processes. We also describe experimental procedures that make it possible to extract important biophysical cellular parameters from QPS including absolute cell volume, transmembrane water permeability, and the movements of water in and out of the cell. To illustrate how QP-DHM can reveal the dynamics of specific cellular processes, we show how the monitoring of transmembrane water movements can be used to resolve the neuronal network dynamics at single-cell level. This is possible because QPS can measure the activity of electroneutral cotransports, including NKCC1 and KCC2, during a neuronal firing mediated by glutamate, the main excitatory neurotransmitter in the brain. Finally, we added a supplemental section, with more technical details, for readers who are interested in troubleshooting live-cell QP-DHM.
Keywords
Algorithms, Holography/methods, Microscopy, Phase-Contrast/methods, Nerve Net/ultrastructure, Neurons/ultrastructure, Single-Cell Analysis/methods, Imaging substrate, Label-free live-cell imaging, Neurons, QP-DHM, Quantitative-phase digital holographic microscopy
Pubmed
Web of science
Create date
27/02/2024 23:56
Last modification date
28/02/2024 7:15
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