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Na 1.15 water immersion objective

Manufactured by Nikon
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The Nikon 40x NA 1.15 water immersion objective is a high-magnification, high-numerical aperture lens designed for advanced microscopy applications. It provides a large field of view and excellent optical performance, making it suitable for a variety of scientific and research applications that require detailed, high-resolution imaging.

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Lab products found in correlation

470 nm led, by Thorlabs (2 mentions) Zyla 5.5 camera, by Oxford Instruments (2 mentions) Spectra x light engine, by Lumencor (2 mentions)

Spelling variants of this product

16x water immersion objective (32 citations) 16×/0.8-NA water-immersion objective (15 citations)

2 protocols using na 1.15 water immersion objective

1

Fluorescent Imaging of Voltage Sensors

Check if the same lab product or an alternative is used in the 5 most similar protocols
Fluorescent imaging of voltage sensors expressed in cultured hippocampal neurons for Fig. 2, Supplementary Fig. 12–16 and Supplementary Fig. 18, 19 was performed using a Nikon Eclipse Ti inverted microscope equipped with a 40x NA 1.15 water immersion objective (Nikon), a 637 nm Laser (637 LX, OBIS) focused on the back focal plane of the objective, a SPECTRA X light engine (Lumencor) with 475/28 nm, 585/29 nm, and 631/28 nm exciters (Semrock), a 470 nm LED (ThorLabs) and a 5.5 Zyla camera (Andor), controlled by NIS-Elements AR software.
Piatkevich K.D., Jung E.E., Straub C., Linghu C., Park D., Suk H.J., Hochbaum D.R., Goodwin D., Pnevmatikakis E., Pak N., Kawashima T., Yang C.T., Rhoades J.L., Shemesh O., Asano S., Yoon Y.G., Freifeld L., Saulnier J.L., Riegler C., Engert F., Hughes T., Drobizhev M., Szabo B., Ahrens M.B., Flavell S.W., Sabatini B.L, & Boyden E.S. (2018). A robotic multidimensional directed evolution approach applied to fluorescent voltage reporters. Nature chemical biology, 14(4), 352-360.
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2

Fluorescent Imaging of Voltage Sensors

Check if the same lab product or an alternative is used in the 5 most similar protocols
Fluorescent imaging of voltage sensors expressed in cultured hippocampal neurons for Fig. 2, Supplementary Fig. 12–16 and Supplementary Fig. 18, 19 was performed using a Nikon Eclipse Ti inverted microscope equipped with a 40x NA 1.15 water immersion objective (Nikon), a 637 nm Laser (637 LX, OBIS) focused on the back focal plane of the objective, a SPECTRA X light engine (Lumencor) with 475/28 nm, 585/29 nm, and 631/28 nm exciters (Semrock), a 470 nm LED (ThorLabs) and a 5.5 Zyla camera (Andor), controlled by NIS-Elements AR software.
Piatkevich K.D., Jung E.E., Straub C., Linghu C., Park D., Suk H.J., Hochbaum D.R., Goodwin D., Pnevmatikakis E., Pak N., Kawashima T., Yang C.T., Rhoades J.L., Shemesh O., Asano S., Yoon Y.G., Freifeld L., Saulnier J.L., Riegler C., Engert F., Hughes T., Drobizhev M., Szabo B., Ahrens M.B., Flavell S.W., Sabatini B.L, & Boyden E.S. (2018). A robotic multidimensional directed evolution approach applied to fluorescent voltage reporters. Nature chemical biology, 14(4), 352-360.
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