High-definition macro to micro confocal imaging |
The AZ-C2+ enables high-definition confocal imaging during macro observation as well as micro observation.
Sharp wide field of view images with unprecedentedly high S/N ratios allow for imaging of whole-mount specimens such as embryos and large tissue slices that are commonly used in developmental and systems biology studies.
Moreover, the AZ-C2+ offers a combination of low and high magnification objective lenses and a scanning zoom function, enabling continuous imaging from macro to micro with a single microscope.
The macro in vivo imaging capabilities allow for the capture of confocal images that were previously not possible with traditional stereoscopic microscopes.
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TT2 ES cells
Anti-Nanog antibody (Cy3), anti-Oct3/4 antibody (Alexa488) and DAPI localized in cell nuclei
Photographed with the cooperation of: Hiroshi Kiyonari, Laboratory for Animal Resources and Genetic
Engineering, RIKEN Center for Developmental Biology |
Photo courtesy of: Director and Professor Masatoshi Yamamoto, Drosophila Genetic Resource Center, Kyoto Institute of Technology
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Comparison of same specimen regions captured by the AZ-C2+ and an epi-fluorescence microscope
The AZ-C2+ eliminates out-of-focus light and flare to deliver highly resolved confocal fluorescence images and optical sections. |
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Confocal fluorescence Standard wide-field Confocal fluorescence Standard wide天field |
| maximum projection fluorescence image maximum projection fluorescence image |
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Specimen: 7.5-day-old mouse embryo expressing H2B-EGFP. (Plan Fluor 2x used)
Photos courtesy of: Dr. Toshihiko Fujimori*1*2, Dr. Go Shioi*2
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Specimen: Zebrafish eye double-stained with GFP and mCherry
Photos courtesy of: 2008 Physiology Course, Marine Biological Laboratory |
*1Division of Embryology, Developmental Biology, National Institute for Basic Biology
*2Genetic Engineering Unit, Laboratory for Animal Resources and Genetic Engineering, Center for Developmental Biology, RIKEN |
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One天shot天whole specimen天macro confocal imaging
High NA objectives for macro observation enable fast, high-resolution, single-image capture of a wide specimen area. Because the objectives cover a field of view larger than 1 cm, imaging of embryos during late stages of development and the dynamics of cell populations in whole organs are possible.
[Note] When Plan Apochromat 1x and AZ100 optical zoom 4x are used, the diagonal diameter of the real field of view is 5.3 mm.
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The AZ-C2+ can capture wide-field, optical sections at high resolution in a single scan. With a conventional confocal microscope, image stitching is necessary because the field of view that can be captured in a single scan is small.
Photos courtesy of: Dr. Yoshiko Takahashi, Molecular and Developmental Biology, Graduate School of Biological Science, NAIST |
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Specimen: Rabbit hyaline cartilage cells embedded in atelocollagen gel and cultured for 21 days; live cells (green) and type II collagen (red)
Photos courtesy of: Dr. Masahiro Kino-oka, Laboratory of Bioprocess Systems Engineering, Department of Biotechnology, Division of Advanced Science and Biotechnology, Graduate School of Engineering, Osaka University
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The AZ-C2+ allows time-lapse observation of the dynamic behavior of cell populations.
Specimen: Chick embryo in stage IV (Plan Fluor 2x used) expressing GAP43-eGFP to label plasma membrane.
Photos courtesy of: Dr. Yukiko Nakaya, Laboratory for Early Embryogenesis, Center for Developmental Biology, RIKEN |
Continuous imaging from low magnification to high magnification
With five different objective lenses, optical zoom and confocal scan zoom, the AZ-C2+ makes imaging possible from very low magnification to high magnification. Macro imaging, such as whole-section imaging, and micro imaging, including imaging of a single cell, can be done using a single microscope.
High magnification imaging offers clear and sharp images of single cells.
Specimen: Human breast cancer cell line MDA-MB-231 (Plan Fluor 5x used)
Photos courtesy of: Dr. Kazuyuki Itoh, Department of Biology, Osaka Medical Center for Cancer and Cardiovascular Diseases
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Zoom 1x Zoom 2x Zoom 4x Zoom 8x |
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Specimen: BPAE cells (Plan Fluor 5x and C1 confocal scan zoom used) |
Deep imaging of whole specimens
The AZ-C2+ allows imaging deep into the specimen天difficult to achieve with conventional confocal microscopes. The AZ-C2+ efficiently captures fluorescence signals from deep within a specimen in macro and in-vivo imaging.
Nerve cells (red) 2 mm beneath the surface of the embryo can be imaged clearly.
Specimen: 2.5-day-old chick embryo
Photo courtesy of: Dr. Yoshiko Takahashi, Molecular and Developmental Biology, Graduate School of Biological Science, NAIST |
Confocal laser microscope system C2+/C2si+ Ready/C2si+
The Nikon C2+ series offers the optimum confocal system to meet both your research and your budgetary needs.
C2+: Standard model boasts high resolution, high sensitivity, and high contrast. Suited for single laboratories or large research groups.
C2si+ Ready: Upgrade to C2si+ is possible by adding a spectral detector.
C2si+: Spectral confocal system featuring a 32-ch multianode spectral detector. A spectral bandwidth of 320 nm can be captured in a single scan.
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[Note] Upgrade to the macro confocal microscope system is through a combination of the C2+ series and the AZ100 microscope. The AZ100M and A1+ series are not compatible.
Sample images captured with AZ-C1
To learn more about these products, please see the C2+ brochure. |
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