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Fura-10™, potassium salt

In contrast to single-wavelength indicators such as Fluo-4, the absorption (or fluorescence excitation) maximum of Fura indicators shifts from 380 nm (Fura-2), 415 nm (Fura-8™ and Fura-10™) for the Ca2+-free chelator to about 340 nm (Fura-2), 355 nm (Fura-8™ and Fura-10™) for the Ca2+-bound . The wavelength of maximum fluorescence emission is relatively independent of Ca2+ concentration. The largest dynamic range for Ca2+-dependent fluorescence signals is obtained by using excitation at 340 nm and 380 nm (for Fura-2), 355 nm and 415 nm (for Fura-8™ and Fura-10™) and ratioing the fluorescence intensities detected at ~510 nm (Fura-2), 525 nm (Fura-8™ and Fura-10™). From this ratio, the level of intracellular Ca2+ can be estimated, using dissociation constants (Kd) that are derived from calibration curves. By using the ratio of fluorescence intensities produced by excitation at two wave lengths, factors such as uneven dye distribution and photo bleaching are minimized because they should affect both measurements to the same extent. Calibration solutions should be initially free of heavy metal ions such as manganese, which may affect both its fluorescence and its affinity for calcium.

Example protocol

PREPARATION OF STOCK SOLUTIONS

Unless otherwise noted, all unused stock solutions should be divided into single-use aliquots and stored at -20 °C after preparation. Avoid repeated freeze-thaw cycles.

Fura-10™ stock solution
Prepare a 2 to 5 mM Fura-10™ stock solution in ddH2O.

PREPARATION OF WORKING SOLUTION

Fura-10™ working solution
Prepare a 10 to 50 µM Fura-10™ working solution in ddH2O or buffer of your choice.

SAMPLE EXPERIMENTAL PROTOCOL

In contrast to single-wavelength indicators such as Fluo-4, the absorption (or fluorescence excitation) maximum of Fura indicators shifts from 415 nm (Fura-10™) for the Ca2+ -free chelator to about 355 nm (Fura-10™) for the Ca2+ -bound. The wavelength of maximum fluorescence emission is relatively independent of Ca2+ concentration. The largest dynamic range for Ca2+ -dependent fluorescence signals is obtained by using excitation at 355 nm and 415 nm (Fura-10™) and ratioing the fluorescence intensities detected at ~510 nm 525 nm (Fura-10™). From this ratio, the level of intracellular Ca2+ can be estimated, using dissociation constants (Kd) that are derived from calibration curves. By using the ratio of fluorescence intensities produced by excitation at two wave lengths, factors such as uneven dye distribution and photo bleaching are minimized because they should affect both measurements to the same extent. Calibration solutions should be initially free of heavy metal ions such as manganese, which may affect both its fluorescence and its affinity for calcium.
Once the indicator has been calibrated with solutions of known Ca2+ concentrations (see below), the following equation can be used to relate the intensity ratios to Ca2+ levels:
[Ca 2+] = Kd Q (R − Rmin) / (Rmin − R)
Where, R represents the fluorescence intensity ratio Fλ1/Fλ2, in which λ1 (~ 355 nm for Fura-10™) and λ2 (415 nM Fura-10™) are the fluorescence detection wavelengths for the ion-bound and ion-free indicator, respectively. Ratios corresponding to the titration end points are denoted by the subscripts indicating the minimum and maximum Ca2+ concentration. Q is the ratio of Fmin to Fmax at λ2 (~ 415 nM Fura-10™). Kd is the Ca2+ dissociation constant of the indicator. Calibrating fura indicators requires making measurements for the completely ion-free and ion-saturated indicator (to determine the values for Fmin, Fmax, Rmin, and Rmax) and for the indicator in the presence of known Ca2+ concentrations (to determine Kd).

Spectrum

Product family

NameExcitation (nm)Emission (nm)
Fura Red, potassium salt435639

References

View all 50 references: Citation Explorer
Using FluoZin-3 and fura-2 to monitor acute accumulation of free intracellular Cd2+ in a pancreatic beta cell line.
Authors: Malaiyandi, Latha M and Sharthiya, Harsh and Barakat, Ameir N and Edwards, Joshua R and Dineley, Kirk E
Journal: Biometals : an international journal on the role of metal ions in biology, biochemistry, and medicine (2019): 951-964
A Novel Nicotinamide Adenine Dinucleotide Correction Method for Intracellular Ca2+ Measurement with Fura-2-Analog in Live Cells.
Authors: Lee, Jeong Hoon and Ha, Jeong Mi and Ho, Quynh Mai and Leem, Chae Hun
Journal: Journal of visualized experiments : JoVE (2019)
Calcium Imaging of Store-Operated Calcium (Ca2+) Entry (SOCE) in HEK293 Cells Using Fura-2.
Authors: Johnson, Martin
Journal: Methods in molecular biology (Clifton, N.J.) (2019): 163-172
A 340/380 nm light-emitting diode illuminator for Fura-2 AM ratiometric Ca2+ imaging of live cells with better than 5 nM precision.
Authors: Tinning, P W and Franssen, A J P M and Hridi, S U and Bushell, T J and McConnell, G
Journal: Journal of microscopy (2018): 212-220
Tuning the Spectroscopic Properties of Ratiometric Fluorescent Metal Indicators: Experimental and Computational Studies on Mag-fura-2 and Analogues.
Authors: Zhang, Guangqian and Jacquemin, Denis and Buccella, Daniela
Journal: The journal of physical chemistry. B (2017): 696-705
Page updated on December 3, 2024

Ordering information

Price
Unit size
5x50 ug
1 mg
Catalog Number
2111021111
Quantity
Add to cart

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Physical properties

Dissociation constant (Kd, nM)260

Molecular weight

1024.27

Solvent

Water

Spectral properties

Excitation (nm)

354

Emission (nm)

524

Storage, safety and handling

H-phraseH303, H313, H333
Hazard symbolXN
Intended useResearch Use Only (RUO)
R-phraseR20, R21, R22

Storage

Freeze (< -15 °C); Minimize light exposure
UNSPSC12171501
&nbsp;Fluorescence excitation spectra of Fura-10&trade; in the presence of 0 to 39 &micro;M free Ca2+.
&nbsp;Fluorescence excitation spectra of Fura-10&trade; in the presence of 0 to 39 &micro;M free Ca2+.
&nbsp;Fluorescence excitation spectra of Fura-10&trade; in the presence of 0 to 39 &micro;M free Ca2+.