Usage History

A bright, orange to red crystalline powder that reacts with alkalis to form an intense green fluorescence. Fluorescein is used for the detection of soluble hydroxides, carbonates, and ammonia. It is sensitive to the part per billion level. Its UV absorption maxima occur at 493.4 and 460 nm. Fluorescein is used as a pH indicator as well as in industrial coatings, printing inks, lubricants, plastics, and as a cosmetic ingredient. In the late 19th century, fluorescein was used as a yellow dye on wool and silk without a mordant.

Synonyms

C.I. 45350; Fluorescein; Acid Yellow 73; Resorcinolphthalein; Solvent yellow 94; D & C yellow no. 7; Angiofluor; Japan yellow 201; Soap yellow

Molecular Information

• Molecular Formula = C20H12O5
• Molecular Weight = 332.31 g/mol

CI 45350, Fluorescein, Acid Yellow 73

Analytical instrumentation and procedures

Extraction: The extraction was carried out as follows: a small sample of thread was extracted with the TFA 2M in 1.5ml eppendorfs for 30 min, in 60ºC water bath, with constant agitation. After extraction, each extract was dried in a vacuum system, where the resulting dry residues were reconstituted with 50 μl H2O: MeOH (80:20,v/v).

HPLC system: The dye analyses were performed in a Thermofinnigan Surveyor HPLC-DAD system with a Thermofinnigan Surveyor PDA 5 diode array detector (Thermofinnigan, USA), an autosampler and a pump. The samples were injected onto the column via a Rheodyne injector with a 25μl loop.

HPLC Column: The separations were performed in Zorbax Eclipse Plus C18 (Agilent, USA) with 5μm particle size column (2.1 mm x 150 mm). The column was kept at controlled temperature (35ºC).

LC program: A solvent gradient of (A) TEA pH= 6,4 3mM and (B) pure methanolwas used at a flow rate of 0.3 mL/min; 0-0,01min A:B (95:5) isocratic, 5 min A:B (90:10) isocratic, 10 min A:B (70:30) isocratic, 15 min A:B (50:50) isocratic, 30 min A:B (45:55) isocratic, 35 min A:B (30:70) isocratic, 45-55 min A:B (5:95) linear, 60-70 min A:B (95:5) linear.

LC-DAD-MSn: The analyses of dyes were performed on a LC-MS with ProStar 410 autosampler, two 212-LC chromatography pumps, a ProStar 335 diode array detector and a 500-MS ion trap mass spectrometer with an electrospray ionization (ESI) ion source (Varian, Palo Alto, CA, USA). Data acquisition and processing were performed using Varian MS Control 6.9 software.The separations were carried out using a Zorbax Eclipse Plus (Agilent, USA) with 5 μm particle size column (2.1 mm x 150 mm). The column was kept at controlled temperature (35ºC). The samples were injected onto the column via a Rheodyne injector with a 20 μL loop. The gradient adapted from and described in 2.3.1 was used at a flow rate of 0.2 mL/min. The mass spectra were acquired in negative and positive mode depending on the structures. The optimized parameters were as follows: ion spray voltage,  4,8 kV; capillary voltage, 20 V; RF loading 80%. Nitrogen was used as nebulising and drying gas, at a pressure of 35 and 15 psi; drying gas temperature, 300ºC. The multistage MS (MSn) spectra were obtained with an isolation window of 2.0 Da, excitation energy values of 0,9 to 1,5 V and an excitation time of 10 ms.

[1]

Chromatograms

CI 45350, Fluorescein, Acid Yellow 73, Absorbance at 444 nm (mAU) By Cátia Souto, University of Lisbon, Portugal 2010 [1]

Results

compounds identified, By Souto [1]

References

[1] Cátia Susana da Costa Nogueira Souto, "Analysis of Early Synthetic Dyes with HPLC-DAD-MS An important database for analysis of colorants used in cultural heritage", Thesis, Master Degree in Conservation and Restoration of Textiles. UNIVERSIDADE NOVA DE LISBOA, 2010.