ReadiLink™ Rapid iFluor® 750 Antibody Labeling Kit Production Scale

Ordering information

Price
Catalog Number
Unit Size
Quantity

Add to cart

Additional ordering information

Telephone	1-800-990-8053
Fax	1-800-609-2943
Email	sales@aatbio.com
International	See distributors
Bulk request	Inquire
Custom size	Inquire
Shipping	Standard overnight for United States, inquire for international

Spectral properties

Correction Factor (260 nm)	0.044
Correction Factor (280 nm)	0.039
Correction Factor (565 nm)	0.0250
Correction Factor (650 nm)	0.1413
Extinction coefficient (cm ^-1 M ^-1)	275000¹
Excitation (nm)	757
Emission (nm)	779
Quantum yield	0.12¹

Storage, safety and handling

H-phrase	H303, H313, H333
Hazard symbol	XN
Intended use	Research Use Only (RUO)
R-phrase	R20, R21, R22
UNSPSC	12171501

Alternative formats

ReadiLink™ Rapid iFluor® 750 Antibody Labeling Kit *Microscale Optimized for Labeling 50 μg Antibody Per Reaction*

Overview SDS Protocol

Components

Example protocol

AT A GLANCE

Key Parameters for Optimal Results

1.0 mg Antibody (MW ~150 kDa)
Antibody concentration: 2.0 mg/mL
Antibody volume: 500 µL

SAMPLE EXPERIMENTAL PROTOCOL

Important

Before opening the vials, warm all components and briefly centrifuge. Immediately prepare necessary solutions before starting conjugation. This protocol is a recommendation.

Antibody Labeling Reaction

Warm up a vial of reactive dye (Component A) to room temperature.

Note: Each vial of reactive dye contains an optimized amount of dye to label 1 mg of IgG (MW ~150 kDa) at 2 mg/mL in PBS, the kit can also be used to label other proteins (>10 kDa).
Add 10 µL of DMSO (Component D) to the vial of reactive dye (Component A), mix well.
Prepare a 500 µL antibody solution in PBS with a concentration of 2 mg/mL.

Note: The protein should be dissolved in 1X phosphate buffered saline (PBS), pH 7.2 - 7.4. If the protein is dissolved in buffers containing primary amines, like Tris and/or glycine, it must be dialyzed against 1X PBS, pH 7.2 - 7.4, or use Amicon Ultra0.5, Ultracel-10 Membrane, 10 kDa (Cat No. UFC501008 from Millipore) to remove free amines or ammonium salts (such as ammonium sulfate and ammonium acetate) that are widely used for protein precipitation.

Note: Impure antibodies or antibodies stabilized with bovine serum albumin (BSA) or gelatin will not be labeled well.
Add 25 µL of Reaction Buffer (Component B) to the antibody solution.
Transfer the reconstituted dye solution into the vial of antibody solution, and pipette several times to mix well.
Rotate the reaction mixture for 1 hour at room temperature.

Purification with Desalting Column

Twist off the bottom closure of the desalting column (Component D), and loosen the cap. Place the column in a collection tube.
Centrifuge the column at 1,000 g for 2 minutes to remove the storage solution.
Remove the cap and slowly add 1 mL of PBS to the column. Centrifuge at 1,000 g for 2 minutes and remove the buffer. Repeat this step 3 additional times, discarding the buffer from the collection tube each time.
Place the column in a new collection tube, and gently apply the sample into the center of the compact resin bed.
Centrifuge the column at 1,000 g for 2 minutes to collect the sample.

Determine the Antibody Concentration & Degree of Labeling (Optional)

The following formula can be used to calculate the antibody concentration:

(A₂₈₀- CF₂₈₀ x A_dye) / 1.4

The following formula can be used to calculate the degree of labeling:

DOL = (A_dye / Ec_dye) / (A₂₈₀ - CF₂₈₀ x A_dye) / 210,000)

Where:

210,000 is the molar extinction coefficient (Ec) in cm^-1M^-1 of IgG at 280 nm.
CF₂₈₀ is the correction factor for the effect of the fluorophore on absorbance at 280 nm.
A_dye is the absorbance at maximum (λ_max) for the respective dye.

Table 1. Properties of Labeling Dyes found in the ReadiLink™ Rapid Antibody Labeling Kits.

Cat#	Dye	Mol. Wt.	Ec (cm^-1M^-1)	CF₂₈₀	Target DOL
5700	iFluor® 350	749.85	20,000	0.23	5-10
5702	iFluor® 488	945.07	75,000	0.21	4-8
5705	iFluor® 555	914.06	90,000	0.16	4-7
5710	iFluor® 594	1160.42	18,000	0.04	3-6
5713	iFluor® 647	1274.66	250,000	0.03	3-7
5718	iFluor® 750	1416.83	250,000	0.039	2-6
5720	FITC	620.52	75,000	0.183	3-6
5722	Cy3	829.03	150,000	0.073	1-3
5725	Cy5	855.07	250,000	0.03	2-4
5727	Cy7	881.11	250,000	0.036	2-4
5730	XFD488	643.4	71,000	0.11	4-8
5733	XFD555	1250	150,000	0.08	4-7
5736	XFD594	819.85	90,000	0.56	3-6
5740	XFD647	1259.66	240,000	0.03	3-7
5745	XFD750	1300	240,000	0.04	2-5

Spectrum

Open in Advanced Spectrum Viewer

Spectral properties

Correction Factor (260 nm)	0.044
Correction Factor (280 nm)	0.039
Correction Factor (565 nm)	0.0250
Correction Factor (650 nm)	0.1413
Extinction coefficient (cm ^-1 M ^-1)	275000¹
Excitation (nm)	757
Emission (nm)	779
Quantum yield	0.12¹

Product Family

Name	Excitation (nm)	Emission (nm)	Extinction coefficient (cm ^-1 M ^-1)	Quantum yield	Correction Factor (260 nm)	Correction Factor (280 nm)
ReadiLink™ Rapid iFluor® 350 Antibody Labeling Kit Microscale Optimized for Labeling 50 μg Antibody Per Reaction	345	450	20000¹	0.95¹	0.83	0.23
ReadiLink™ Rapid iFluor® 555 Antibody Labeling Kit Microscale Optimized for Labeling 50 μg Antibody Per Reaction	557	570	100000¹	0.64¹	0.23	0.14
ReadiLink™ Rapid iFluor® 594 Antibody Labeling Kit Microscale Optimized for Labeling 50 μg Antibody Per Reaction	588	604	180000¹	0.53¹	0.05	0.04
ReadiLink™ Rapid iFluor® 647 Antibody Labeling Kit Microscale Optimized for Labeling 50 μg Antibody Per Reaction	656	670	250000¹	0.25¹	0.03	0.03
ReadiLink™ Rapid iFluor® 680 Antibody Labeling Kit Microscale Optimized for Labeling 50 μg Antibody Per Reaction	684	701	220000¹	0.23¹	0.097	0.094
ReadiLink™ Rapid iFluor® 700 Antibody Labeling Kit Microscale Optimized for Labeling 50 μg Antibody Per Reaction	690	713	220000¹	0.23¹	0.09	0.04
ReadiLink™ Rapid iFluor® 488 Antibody Labeling Kit Microscale Optimized for Labeling 50 μg Antibody Per Reaction	491	516	75000¹	0.9¹	0.21	0.11
ReadiLink™ Rapid iFluor® 633 Antibody Labeling Kit Microscale Optimized for Labeling 50 μg Antibody Per Reaction	640	654	250000¹	0.29¹	0.062	0.044
ReadiLink™ Rapid iFluor® 790 Antibody Labeling Kit Microscale Optimized for Labeling 50 μg Antibody Per Reaction	787	812	250000¹	0.13¹	0.1	0.09
ReadiLink™ Rapid iFluor® 350 Antibody Labeling Kit Production Scale	345	450	20000¹	0.95¹	0.83	0.23
ReadiLink™ Rapid iFluor® 488 Antibody Labeling Kit Production Scale	491	516	75000¹	0.9¹	0.21	0.11
ReadiLink™ Rapid iFluor® 555 Antibody Labeling Kit Production Scale	557	570	100000¹	0.64¹	0.23	0.14
ReadiLink™ Rapid iFluor® 594 Antibody Labeling Kit Production Scale	588	604	180000¹	0.53¹	0.05	0.04
ReadiLink™ Rapid iFluor® 647 Antibody Labeling Kit Production Scale	656	670	250000¹	0.25¹	0.03	0.03
Show More (5)

Images

Figure 1. HeLa cells were labeled with mouse anti-tubulin followed by a goat anti-mouse IgG conjugated to iFluor® 750 using the ReadiLink™ Rapid iFluor® 750 Antibody Labeling Kit (Cat No. 5718).

References

View all 31 references: Citation Explorer

pH-responsive graphene oxide loaded with targeted peptide and anticancer drug for OSCC therapy.
Authors: Li, Ran and Gao, Ruifang and Zhao, Yingjiao and Zhang, Fang and Wang, Xiangyu and Li, Bing and Wang, Lu and Ma, Lixin and Du, Jie
Journal: Frontiers in oncology (2022): 930920

Near-Infrared Fluorescence Imaging of Carotid Plaques in an Atherosclerotic Murine Model.
Authors: Wu, Xiaotian and Daniel Ulumben, Amy and Long, Steven and Katagiri, Wataru and Wilks, Moses Q and Yuan, Hushan and Cortese, Brian and Yang, Chengeng and Kashiwagi, Satoshi and Choi, Hak Soo and Normandin, Marc D and El Fakhri, Georges and Zaman, Raiyan T
Journal: Biomolecules (2021)

Challenging a Preconception: Optoacoustic Spectrum Differs from the Optical Absorption Spectrum of Proteins and Dyes for Molecular Imaging.
Authors: Fuenzalida Werner, Juan Pablo and Huang, Yuanhui and Mishra, Kanuj and Janowski, Robert and Vetschera, Paul and Heichler, Christina and Chmyrov, Andriy and Neufert, Clemens and Niessing, Dierk and Ntziachristos, Vasilis and Stiel, Andre C
Journal: Analytical chemistry (2020)

CD24-targeted intraoperative fluorescence image-guided surgery leads to improved cytoreduction of ovarian cancer in a preclinical orthotopic surgical model.
Authors: Kleinmanns, Katrin and Fosse, Vibeke and Davidson, Ben and de Jalón, Elvira García and Tenstad, Olav and Bjørge, Line and McCormack, Emmet
Journal: EBioMedicine (2020): 102783

Mechanistic profiling of the release kinetics of siRNA from lipidoid-polymer hybrid nanoparticles in vitro and in vivo after pulmonary administration.
Authors: Thanki, Kaushik and van Eetvelde, Delphine and Geyer, Antonia and Fraire, Juan and Hendrix, Remi and Van Eygen, Hannelore and Putteman, Emma and Sami, Haider and de Souza Carvalho-Wodarz, Cristiane and Franzyk, Henrik and Nielsen, Hanne Mørck and Braeckmans, Kevin and Lehr, Claus-Michael and Ogris, Manfred and Foged, Camilla
Journal: Journal of controlled release : official journal of the Controlled Release Society (2019): 82-93

Generation and characterization of novel recombinant anti-hERG1 scFv antibodies for cancer molecular imaging.
Authors: Duranti, Claudia and Carraresi, Laura and Sette, Angelica and Stefanini, Matteo and Lottini, Tiziano and Crescioli, Silvia and Crociani, Olivia and Iamele, Luisa and De Jonge, Hugo and Gherardi, Ermanno and Arcangeli, Annarosa
Journal: Oncotarget (2018): 34972-34989

Enhanced Release of Molecules upon Ultraviolet (UV) Light Irradiation from Photoresponsive Hydrogels Prepared from Bifunctional Azobenzene and Four-Arm Poly(ethylene glycol).
Authors: Rastogi, Shiva K and Anderson, Hailee E and Lamas, Joseph and Barret, Scott and Cantu, Travis and Zauscher, Stefan and Brittain, William J and Betancourt, Tania
Journal: ACS applied materials & interfaces (2018): 30071-30080

Phosphorothioate-Modified AP613-1 Specifically Targets GPC3 when Used for Hepatocellular Carcinoma Cell Imaging.
Authors: Dong, Lili and Zhou, Hongxin and Zhao, Menglong and Gao, Xinghui and Liu, Yang and Liu, Dongli and Guo, Wei and Hu, Hongwei and Xie, Qian and Fan, Jia and Lin, Jiang and Wu, Weizhong
Journal: Molecular therapy. Nucleic acids (2018): 376-386

In vivo fluorescence imaging of hepatocellular carcinoma using a novel GPC3-specific aptamer probe.
Authors: Zhao, Menglong and Dong, Lili and Liu, Zhuang and Yang, Shuohui and Wu, Weizhong and Lin, Jiang
Journal: Quantitative imaging in medicine and surgery (2018): 151-160

Performance of optoacoustic and fluorescence imaging in detecting deep-seated fluorescent agents.
Authors: Chen, Zhenyue and Deán-Ben, Xosé Luís and Gottschalk, Sven and Razansky, Daniel
Journal: Biomedical optics express (2018): 2229-2239