80i compound microscope

Manufactured by Nikon

Sourced in United States

The Nikon 80i compound microscope is a versatile laboratory instrument designed for detailed observation and analysis. It features a high-quality optical system, including LED illumination, to provide clear and consistent images. The 80i is capable of magnifying specimens up to 1000x, making it suitable for a wide range of applications in research, education, and quality control settings.

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Lab products found in correlation

A1r si confocal eclipse ti series, by Nikon (2 mentions) Nis elements advanced research image acquisition and analysis system, by Nikon (2 mentions) Blocking reagent, by Roche (1 mentions) Alexa fluor 488 phalloidin, by Thermo Fisher Scientific (1 mentions) Anti digoxigenin ap fab fragment, by Roche (1 mentions) Ds fi1 camera, by Nikon (1 mentions) Sp8 clsm, by Leica (1 mentions) Vectashield, by Vector Laboratories (1 mentions) Illustrator cs6, by Adobe (1 mentions)

Close spelling variants of this product

80i wide-field compound microscope Nikon 80i compound light microscope Eclipse 80i compound microscope Eclipse 80i Compound Fluorescent Microscope Eclipse 80i compound light microscope Nikon 80i microscope Compound microscope

7 protocols using 80i compound microscope

In situ Hybridization and Phalloidin Staining

Cited 1 time

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In situ hybridization was performed as described previously (Kraus et al., 2016 (link)) with a single change: the embryos were fixed for 1 h at room temperature in 4%PFA/PBS, washed several times in PTw (1× PBS and 0.1% Tween 20), then in 100% methanol and finally stored in 100% methanol at −20°C. Digoxigenin-labelled RNA probes were detected with anti-digoxigenin-AP Fab fragments (Roche) diluted 1:4000 in 0.5% blocking reagent (Roche) in 1× MAB. After unbound antibody was removed by a series of ten PTw washes of 10 min each, the embryos were stained with a mixture of NBT/BCIP, embedded in 86% glycerol and imaged using a Nikon 80i compound microscope equipped with the Nikon DS-Fi1 camera. For phalloidin staining, the embryos were fixed in 4%PFA/PTwTx (1× PBS, 0.1% Tween 20 and 0.2% Triton X-100) for 1 h at room temperature, washed five times with PTwTx, incubated in 100% acetone pre-cooled to −20°C for 7 min on ice and washed three more times with PTwTx. 2 µl of phalloidin-AlexaFluor488 (ThermoFisher) was added per 100 µl PTwTx, and the embryos were stained overnight at 4°C. After eight 10-min washes with PTwTx, the embryos were gradually embedded in Vectashield (Vector labs) and imaged with the Leica SP8 CLSM.

Niedermoser I., Lebedeva T, & Genikhovich G. (2022). Sea anemone Frizzled receptors play partially redundant roles in oral-aboral axis patterning. Development (Cambridge, England), 149(19), dev200785.

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Zebrafish Whole-Body Imaging at 72 hpf

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All images were obtained at 72 hpf when the live embryos were washed with 1×E3 and mounted in 3% methylcellulose. Whole body images were obtained at 10× on Nikon 80i compound microscope (Nikon Instruments). High magnification images of somites 11-13 were obtained at 20× using confocal microscope (Nikon A1R Si Confocal Eclipse Ti series). All confocal and software settings were kept unchanged during image acquisition. Images were processed with an NIS-Elements advanced research image acquisition and analysis system (Nikon Instruments), using the maximum intensity projection feature applied to z-stacks for greater depth of clarity. Image files were exported as TIFF files. Figures were composed with Adobe Photoshop CS6 (Adobe, USA).

Mukherjee K, & Liao E.C. (2018). Generation and characterization of a zebrafish muscle specific inducible Cre line. Transgenic research, 27(6), 559-569.

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Quantifying Scar Area in Regenerated Hearts

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Quantification of scar area in regenerated hearts at 30 dpa was performed as described previously (Chablais et al., 2011 (link); González-Rosa et al., 2018 (link); Schnabel et al., 2011 (link)). Serial sections of AFOG-stained hearts were imaged using a Nikon 80i compound microscope (Nikon) with a 4x objective and Excelis AU600HDS HD Camera & Monitor System (Accu-Scope Inc. Commack, NY). Whole ventricular area and scar area [fibrin (red) + collagen (blue)] were measured using Fiji software. The scar area was normalized to the whole ventricular area to calculate the percentage of the scar size for each heart. Scar percentage data were collected for 6–10 sections per heart and averaged to generate each data point.

Zhao L., Ben-Yair R., Burns C.E, & Burns C.G. (2019). Endocardial Notch Signaling Promotes Cardiomyocyte Proliferation in the Regenerating Zebrafish Heart through Wnt Pathway Antagonism. Cell reports, 26(3), 546-554.e5.

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Quantifying Cardiac Fibrosis in Regenerated Hearts

Cited 2 times

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To quantify the fibrotic area in regenerated hearts at 45 dpr, images of evenly-spaced AFOG-stained serial sections of the whole heart were captured using a Nikon 80i compound microscope (Nikon Instruments) with a 4x lens and a mounted Excelis AU600HDS HD Camera (Accu-Scope Inc. Commack, NY). On average, ~21 sections were analyzed per heart (min=13, max=30; 1427 total sections analyzed). Masks containing the entire ventricular area and the scar area were manually generated using Adobe Photoshop based on differential staining (uninjured/regenerated muscle=brown/orange; fibrotic area=(fibrin (red) + collagen (blue)). Selected areas were measured using ImageJ software. As described previously (Chablais et al., 2011 (link); Schnabel et al., 2011 (link)), the fibrotic area was normalized to the total ventricular area to calculate the percentage of the scar size for each heart.

González-Rosa J.M., Sharpe M., Field D., Soonpaa M.H., Field L.J., Burns C.E, & Burns C.G. (2018). Myocardial polyploidization creates a barrier to heart regeneration in zebrafish. Developmental cell, 44(4), 433-446.e7.

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Quantifying Scar Area in Regenerated Hearts

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Imaging Embryonic Tissue Development

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Embryos were mounted in 95% glycerol in 1× PBS with Tween 20 and imaged at 10× on Nikon 80i compound microscope (Nikon Instruments, Melville, NY) for WISH and cartilage staining experiments. The palate and mandible were dissected and flat mounted before imaging them at 40×. Embryos were mounted in 3% methylcellulose and imaged at 20× on the confocal microscope (Nikon A1R Si Confocal Eclipse Ti series) for cell proliferation, migration, and apoptosis assays. All images were processed with NIS-Elements advanced image acquisition and analysis system (Nikon Instruments). Figures were composed with Adobe Photoshop CS6 and Adobe Illustrator CS6 (Adobe, San Jose, CA). All measurements were performed using ImageJ (NIH).

Ishii K., Mukherjee K., Okada T, & Liao E.C. (2018). Genetic Requirement of talin1 for Proliferation of Cranial Neural Crest Cells during Palate Development. Plastic and Reconstructive Surgery Global Open, 6(3), e1633.

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Craniofacial Skeletal Analysis in Embryos

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To analyze the craniofacial skeleton, Alcian blue staining was performed on five WT and five β3^−/− embryos euthanized at 4.5 dpf, as described previously.³¹ Embryos were mounted in 95% glycerol in 1x phosphate buffered saline with tween 20 (PBST) and images were obtained at 10x and 40x on a Nikon 80i compound microscope (Nikon Instruments Inc., Melville, NY, USA). Images were processed with an NIS-Elements advanced research image acquisition and analysis system (Nikon Instruments), using the maximum intensity projection feature applied to z-stacks. Images for each animal were examined for abnormalities and measurements recorded for palate length and width as well as lower jaw length and width.

Yang X., Jounaidi Y., Mukherjee K., Fantasia R.J., Liao E.C., Yu B, & Forman S.A. (2019). Drug-Selective Anesthetic Insensitivity of Zebrafish Lacking γ-Aminobutyric Acid Type A Receptor β3 Subunits. Anesthesiology, 131(6), 1276-1291.

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