Abstract
Non-linear microscopy, such as multi-photon excitation microscopy, offers spatial localities of excitations, thereby achieving 3D cross-sectional imaging with low phototoxicity even in thick biological specimens. We had developed a multi-point scanning two-photon excitation microscopy system using a spinning-disk confocal scanning unit. However, its severe color cross-talk has precluded multi-color simultaneous imaging. Therefore, in this study, we introduced a mechanical switching system to select either of two NIR laser light pulses and an image-splitting detection system for 3- or 4-color imaging. As a proof of concept, we performed multi-color fluorescent imaging of actively dividing human HeLa cells and tobacco BY-2 cells. We found that the proposed microscopy system enabled time-lapse multi-color 3D imaging of cell divisions while avoiding photodamage. Moreover, the application of a linear unmixing method to the 5D dataset enabled the precise separation of individual intracellular components in multi-color images. We thus demonstrated the versatility of our new microscopy system in capturing the dynamic processes of cellular components that could have multitudes of application.
Highlights
Non-linear microscopy, such as multi-photon excitation microscopy, offers spatial localities of excitations, thereby achieving 3D cross-sectional imaging with low phototoxicity even in thick biological specimens
Two-photon excitation laser scanning microscopy (TPLSM) acquires such cross-sectional images because the fluorophores are excited in the focal volume of the objective lens by near-infrared (NIR) laser light pulses[4]
The fluorophores are excited throughout the optical path of an excitation light beam in confocal laser scanning microscopy (CLSM), while only fluorophores at the cross-sectional focal plane are excited in TPLSM
Summary
Non-linear microscopy, such as multi-photon excitation microscopy, offers spatial localities of excitations, thereby achieving 3D cross-sectional imaging with low phototoxicity even in thick biological specimens. Two-photon excitation laser scanning microscopy (TPLSM) acquires such cross-sectional images because the fluorophores are excited in the focal volume of the objective lens by near-infrared (NIR) laser light pulses[4]. We successfully demonstrated high-speed 4-channels imaging by introducing a mechanical fast-selecting system for either of the two types of NIR laser light beams and an image-splitting detection system into our TPLSM by utilizing a spinning-disk scanner (TPLSM-SD).
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