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92544

Sigma-Aldrich

Abberior® FLIP 565, maleimide

for single-molecule switching microscopy (e.g. PALM, STORM, GSDIM)

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About This Item

UNSPSC Code:
12352111
NACRES:
NA.32

Quality Level

form

solid

concentration

≥50.0% (degree of coupling)

solubility

DMF: 0.25 mg/mL, clear

fluorescence

λex 565 nm; λem 580 nm±5 nm in PBS, pH 7.4

storage temp.

−20°C

General description

Absorption Maximum (off-state) λmax:314 nm (PBS, pH 7.4)
Extinction Coefficient, ε(λmax): 47,000 M-1cm-1 (MeOH)
Fluorescence Maximum, λfl:580 nm (PBS, pH 7.4)
Photoactication Wavelength: 310-380 (one-photon activation)
650-800 (two-photon activation)
Fluorescence Quantum Yield, η: 0.38 (PBS, pH 7.4)

Application

Abberior® FLIP 565 conjugated with secondary antibody has been used for STORM (stochastic optical reconstruction microscopy) imaging of COS-7 and S180 cells.

Suitability

Designed and tested for fluorescent super-resolution microscopy

Legal Information

abberior is a registered trademark of Abberior GmbH

Storage Class Code

11 - Combustible Solids

WGK

WGK 3

Flash Point(F)

Not applicable

Flash Point(C)

Not applicable


Certificates of Analysis (COA)

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Remi Galland et al.
Nature methods, 12(7), 641-644 (2015-05-12)
Single-objective selective-plane illumination microscopy (soSPIM) is achieved with micromirrored cavities combined with a laser beam-steering unit installed on a standard inverted microscope. The illumination and detection are done through the same objective. soSPIM can be used with standard sample preparations
Marcus Dyba et al.
Nature biotechnology, 21(11), 1303-1304 (2003-10-21)
We report immunofluorescence imaging with a spatial resolution well beyond the diffraction limit. An axial resolution of approximately 50 nm, corresponding to 1/16 of the irradiation wavelength of 793 nm, is achieved by stimulated emission depletion through opposing lenses. We
Nicolas Olivier et al.
Biomedical optics express, 4(6), 885-899 (2013-06-14)
3D STORM is one of the leading methods for super-resolution imaging, with resolution down to 10 nm in the lateral direction, and 30-50 nm in the axial direction. However, there is one important requirement to perform this type of imaging:
T A Klar et al.
Optics letters, 24(14), 954-956 (2007-12-13)
We overcame the resolution limit of scanning far-field fluorescence microscopy by disabling the fluorescence from the outer part of the focal spot. Whereas a near-UV pulse generates a diffraction-limited distribution of excited molecules, a spatially offset pulse quenches the excited
Volker Westphal et al.
Physical review letters, 94(14), 143903-143903 (2005-05-21)
Utilizing single fluorescent molecules as probes, we prove the ability of a far-field microscope to attain spatial resolution down to 16 nm in the focal plane, corresponding to about 1/50 of the employed wavelength. The optical bandwidth expansion by nearly

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