Cal-520®-Dextran Conjugate MW 10,000

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Telephone	1-800-990-8053
Fax	1-800-609-2943
Email	sales@aatbio.com
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Shipping	Standard overnight for United States, inquire for international

Physical properties

Molecular weight	~11000
Solvent	Water

Spectral properties

Excitation (nm)	492
Emission (nm)	515
Quantum yield	0.75¹

Storage, safety and handling

H-phrase	H303, H313, H333
Hazard symbol	XN
Intended use	Research Use Only (RUO)
R-phrase	R20, R21, R22
Storage	Freeze (< -15 °C); Minimize light exposure
UNSPSC	12352200

Alternative formats

Overview SDS Protocol

Molecular weight

~11000

Excitation (nm)

492

Emission (nm)

515

Quantum yield

0.75¹

Calcium measurement is critical for numerous biological investigations. Fluorescent probes that show spectral responses upon binding calcium have enabled researchers to investigate changes in intracellular free calcium concentrations by using fluorescence microscopy, flow cytometry, fluorescence spectroscopy and fluorescence microplate readers. Cells may be physically loaded with the cell-impermeant salt forms of these dextran-conjugated calcium indicators using patch pipette or microinjection. The fluorescence signal from these cells is measured using fluorescence microscopy. The dextran forms of our calcium indicators show a dramatic reduction in both leakage and compartmentalization compared to the AM ester forms. Among the fluorescent calcium indicator dextran conjugates, Cal-520 dextran conjugates might be the best choice due to their high fluorescence quantum yield and large fluorescence enhancement by calcium. Compared to Oregon Green BAPTA-1 dextran, Cal-520 dextran exhibits much lower background and much larger calcium-induced fluorescence enhancement.

Spectrum

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Spectral properties

Excitation (nm)	492
Emission (nm)	515
Quantum yield	0.75¹

Product Family

Name	Excitation (nm)	Emission (nm)	Quantum yield
Cal-520®-Biotin Conjugate	492	515	0.75¹
Cal-520®-Biocytin Conjugate	492	515	0.75¹
Cal-590™-Dextran Conjugate MW 3,000	563	584	0.62¹
Cal-590™-Dextran Conjugate MW 10,000	563	584	0.62¹
Cal-630™-Dextran Conjugate MW 3,000	609	626	0.37¹
Cal-630™-Dextran Conjugate MW 10,000	609	626	0.37¹
Cal-670™-Dextran Conjugate MW 3,000	667	680	-
Cal-670™-Dextran Conjugate MW 10,000	667	680	-
Cal-770™-Dextran Conjugate MW 3,000	758	783	-
Cal-770™-Dextran Conjugate MW 10,000	758	783	-
Cal-590L® Dextran Conjugate MW 10,000	569	590	-
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Images

Figure 1. Fluorescence image of live Raw 264.7 cells stained with Cal-520®-Dextran Conjugate MW 10,000 (Cat # 20601, Green) to visualize lysosomal Ca2+ , LysoBrite™ Red (Cat # 22645, Red) to visualize lysosomes and Nuclear Violet™ LCS1 (Cat# 17543, Blue) to visualize nuclei.

Figure 2. Fluorescence intensity increase of Cal-520®-Dextran (Cat# 20600), Cal-520®-Dextran (Cat# 20601) and Calcium-Green™-1-Dextran upon binding saturated amount of calcium.

Citations

View all 104 citations: Citation Explorer

Ca2+-driven cytoplasmic backflow secures spindle position in fertilized mouse eggs
Authors: Totsuka, Takaya and Ohsugi, Miho
Journal: bioRxiv (2024): 2024--02

High-Speed Neural Imaging with Synaptic Resolution: Bessel Focus Scanning Two-Photon Microscopy and Optical-Sectioning Widefield Microscopy
Authors: Meng, Guanghan and Zhang, Qinrong and Ji, Na
Journal: (2023): 293--329

Neurophysiological functions and pharmacological tools of acidic and non-acidic Ca2+ stores
Authors: Martucci, Lora L and Cancela, Jos{\'e}-Manuel
Journal: Cell Calcium (2022): 102582

Network formation and reorganization of the olfactory system of Xenopus laevis
Authors: Hawkins, Sara Joy
Journal: (2022)

Generation and Characterization of a Cell Type-Specific, Inducible Cre-Driver Line to Study Olfactory Processing
Authors: Koldaeva, Anzhelika and Zhang, Cary and Huang, Yu-Pei and Reinert, Janine Kristin and Mizuno, Seiya and Sugiyama, Fumihiro and Takahashi, Satoru and Soliman, Taha and Matsunami, Hiroaki and Fukunaga, Izumi
Journal: Journal of Neuroscience (2021): 6449--6467

Astrocytic glutamate transporters reduce the neuronal and physiological influence of metabotropic glutamate receptors in nucleus tractus solitarii
Authors: Martinez, Diana and Rogers, Richard C and Hermann, Gerlinda E and Hasser, Eileen M and Kline, David D
Journal: American Journal of Physiology-Regulatory, Integrative and Comparative Physiology (2020): R545--R564

Reciprocal regulation of vacuolar calcium transport and V-ATPase activity, and the effects of Phosphatidylinositol 3, 5-bisphosphate
Authors: Miner, Gregory E and Rivera-Kohr, David A and Zhang, Chi and Sullivan, Katherine D and Guo, Annie and Fratti, Rutilio A
Journal: bioRxiv (2020)

Phosphatidylinositol 3, 5-bisphosphate regulates Ca2+ transport during yeast vacuolar fusion through the Ca2+ ATPase Pmc1
Authors: Miner, Gregory E and Sullivan, Katherine D and Zhang, Chi and Rivera-Kohr, David and Guo, Annie and Hurst, Logan R and Ellis, Ez C and Starr, Matthew L and Jones, Brandon C and Fratti, Rutilio A
Journal: Traffic (2020): 503--517

Loss of excitatory amino acid transporter restraint following chronic intermittent hypoxia contributes to synaptic alterations in nucleus tractus solitarii
Authors: Martinez, Diana and Rogers, Richard C and Hasser, Eileen M and Hermann, Gerlinda E and Kline, David D
Journal: Journal of Neurophysiology (2020): 2122--2135

50 Hz volumetric functional imaging with continuously adjustable depth of focus
Authors: Lu, Rongwen and Tanimoto, Masashi and Koyama, Minoru and Ji, Na
Journal: Biomedical Optics Express (2018): 1964--1976