Summary of ssbd-repos-000469

SSBD:database
URL

Name
ssbd-repos-000469 (469-Ishii-pulseSTED)
URL
DOI
-

Title
Super resolution image of dendritic spine taken by new STED microscopy
Description

Super-resolution in two-photon excitation (2PE) microscopy offers new approaches for visualizing the deep inside the brain functions at the nanoscale. In this study, the authors developed a novel 2PE stimulated-emission-depletion (STED) microscope with all-synchronized picosecond pulse light sources and time-gated fluorescence detection, namely, all-pulsed 2PE-gSTED microscopy. The implementation of time-gating is critical to excluding undesirable signals derived from brain tissues. Even in a case using subnanosecond pulses for STED, the impact of time-gating was not negligible; the spatial resolution in the image of the brain tissue was improved by approximately 1.4 times compared with non time-gated image. This finding demonstrates that time-gating is more useful than previously thought for improving spatial resolution in brain tissue imaging. This microscopy will facilitate deeper super-resolution observation of the fine structure of neuronal dendritic spines and the intracellular dynamics in brain tissue.

Submited Date
-
Release Date
2026-07-08
Updated Date
-
License
Funding information
-
File formats
Data size
78.6 MB

Organism
Mus musculus
Strain
B6.Cg-Tg(Thy1-YFP)HJrs/J
Cell Line
-
Genes
NA
Proteins
NA

GO Molecular Function (MF)
-
GO Biological Process (BP)
-
GO Cellular Component (CC)
dendritic spine
Study Type
NA
Imaging Methods
two-photon laser scanning microscopy, stimulated emission depletion

Method Summary
-
Related paper(s)

Hirokazu Ishii, Kohei Otomo, Ching-Pu Chang, Miwako Yamasaki, Masahiko Watanabe, Hiroyuki Yokoyama, Tomomi Nemoto (2023) All-synchronized picosecond pulses and time-gated detection improve the spatial resolution of two-photon STED microscopy in brain tissue imaging., PLOS ONE, Volume 18, Number 8

Published in 2023 (Electronic publication in Aug. 24, 2023, midnight )

(Abstract) Super-resolution in two-photon excitation (2PE) microscopy offers new approaches for visualizing the deep inside the brain functions at the nanoscale. In this study, we developed a novel 2PE stimulated-emission-depletion (STED) microscope with all-synchronized picosecond pulse light sources and time-gated fluorescence detection, namely, all-pulsed 2PE-gSTED microscopy. The implementation of time-gating is critical to excluding undesirable signals derived from brain tissues. Even in a case using subnanosecond pulses for STED, the impact of time-gating was not negligible; the spatial resolution in the image of the brain tissue was improved by approximately 1.4 times compared with non time-gated image. This finding demonstrates that time-gating is more useful than previously thought for improving spatial resolution in brain tissue imaging. This microscopy will facilitate deeper super-resolution observation of the fine structure of neuronal dendritic spines and the intracellular dynamics in brain tissue.

Contact(s)
Tomomi Nemoto
Organization(s)
National Institutes of Natural Sciences , Exploratory Research Center on Life and Living Systems , Exploratory Research Center on Life and Living Systems
Image Data Contributors
Quantitative Data Contributors

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