Review



inverted microscope body  (Nikon)


Bioz Verified Symbol Nikon is a verified supplier  
  • Logo
  • About
  • News
  • Press Release
  • Team
  • Advisors
  • Partners
  • Contact
  • Bioz Stars
  • Bioz vStars
  • 99

    Structured Review

    Nikon inverted microscope body
    a Beam paths of the excitation laser used for imaging samples (red) and the emitted photons from the sample (gray); b 2D and ( c ) 3D SDDWP detection setup. The dotted box is a blown-up view of the SDDWP assembly; d Illustration of the <t>microscope</t> port adaptor, 3D printed holder, and SDDWP assembly; e Simulated ±1 st order images on the sCMOS, with the reconstructed virtual spatial image in the middle; f Spectral calibration curve of the SDDWP assembly (blue), dispersion of the system (red); g Axial calibration curve of the SDDWP assembly (red). Widths of different focal spots associated with each z -position set on the microscope (blue). The red arrow shows the axial separation of 500 nm between the planes in 3D-SDDWP.
    Inverted Microscope Body, supplied by Nikon, used in various techniques. Bioz Stars score: 99/100, based on 57094 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/product/inverted+microscope+body/pmc13039816-49-16-20?v=Nikon
    Average 99 stars, based on 57094 article reviews
    inverted microscope body - by Bioz Stars, 2026-06
    99/100 stars

    Images

    1) Product Images from "Maximizing photon utilization in spectroscopic single-molecule localization microscopy using symmetrically dispersed dual-wedge prisms"

    Article Title: Maximizing photon utilization in spectroscopic single-molecule localization microscopy using symmetrically dispersed dual-wedge prisms

    Journal: npj Imaging

    doi: 10.1038/s44303-026-00152-z

    a Beam paths of the excitation laser used for imaging samples (red) and the emitted photons from the sample (gray); b 2D and ( c ) 3D SDDWP detection setup. The dotted box is a blown-up view of the SDDWP assembly; d Illustration of the microscope port adaptor, 3D printed holder, and SDDWP assembly; e Simulated ±1 st order images on the sCMOS, with the reconstructed virtual spatial image in the middle; f Spectral calibration curve of the SDDWP assembly (blue), dispersion of the system (red); g Axial calibration curve of the SDDWP assembly (red). Widths of different focal spots associated with each z -position set on the microscope (blue). The red arrow shows the axial separation of 500 nm between the planes in 3D-SDDWP.
    Figure Legend Snippet: a Beam paths of the excitation laser used for imaging samples (red) and the emitted photons from the sample (gray); b 2D and ( c ) 3D SDDWP detection setup. The dotted box is a blown-up view of the SDDWP assembly; d Illustration of the microscope port adaptor, 3D printed holder, and SDDWP assembly; e Simulated ±1 st order images on the sCMOS, with the reconstructed virtual spatial image in the middle; f Spectral calibration curve of the SDDWP assembly (blue), dispersion of the system (red); g Axial calibration curve of the SDDWP assembly (red). Widths of different focal spots associated with each z -position set on the microscope (blue). The red arrow shows the axial separation of 500 nm between the planes in 3D-SDDWP.

    Techniques Used: Imaging, Microscopy, Dispersion



    Similar Products

    99
    Nikon inverted microscope body
    a Beam paths of the excitation laser used for imaging samples (red) and the emitted photons from the sample (gray); b 2D and ( c ) 3D SDDWP detection setup. The dotted box is a blown-up view of the SDDWP assembly; d Illustration of the <t>microscope</t> port adaptor, 3D printed holder, and SDDWP assembly; e Simulated ±1 st order images on the sCMOS, with the reconstructed virtual spatial image in the middle; f Spectral calibration curve of the SDDWP assembly (blue), dispersion of the system (red); g Axial calibration curve of the SDDWP assembly (red). Widths of different focal spots associated with each z -position set on the microscope (blue). The red arrow shows the axial separation of 500 nm between the planes in 3D-SDDWP.
    Inverted Microscope Body, supplied by Nikon, used in various techniques. Bioz Stars score: 99/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/product/inverted+microscope+body/pmc13039816-49-16-20?v=Nikon
    Average 99 stars, based on 1 article reviews
    inverted microscope body - by Bioz Stars, 2026-06
    99/100 stars
      Buy from Supplier

    Image Search Results


    a Beam paths of the excitation laser used for imaging samples (red) and the emitted photons from the sample (gray); b 2D and ( c ) 3D SDDWP detection setup. The dotted box is a blown-up view of the SDDWP assembly; d Illustration of the microscope port adaptor, 3D printed holder, and SDDWP assembly; e Simulated ±1 st order images on the sCMOS, with the reconstructed virtual spatial image in the middle; f Spectral calibration curve of the SDDWP assembly (blue), dispersion of the system (red); g Axial calibration curve of the SDDWP assembly (red). Widths of different focal spots associated with each z -position set on the microscope (blue). The red arrow shows the axial separation of 500 nm between the planes in 3D-SDDWP.

    Journal: npj Imaging

    Article Title: Maximizing photon utilization in spectroscopic single-molecule localization microscopy using symmetrically dispersed dual-wedge prisms

    doi: 10.1038/s44303-026-00152-z

    Figure Lengend Snippet: a Beam paths of the excitation laser used for imaging samples (red) and the emitted photons from the sample (gray); b 2D and ( c ) 3D SDDWP detection setup. The dotted box is a blown-up view of the SDDWP assembly; d Illustration of the microscope port adaptor, 3D printed holder, and SDDWP assembly; e Simulated ±1 st order images on the sCMOS, with the reconstructed virtual spatial image in the middle; f Spectral calibration curve of the SDDWP assembly (blue), dispersion of the system (red); g Axial calibration curve of the SDDWP assembly (red). Widths of different focal spots associated with each z -position set on the microscope (blue). The red arrow shows the axial separation of 500 nm between the planes in 3D-SDDWP.

    Article Snippet: The SDDWP imaging setup was built on our previously reported sSMLM system , which uses an inverted microscope body (Ti2-E; Nikon) with a 100× total-internal reflection fluorescence (TIRF) objective (MRD01995; Nikon).

    Techniques: Imaging, Microscopy, Dispersion