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Luteolin-3'-D-glucuronide is a naturally occurring flavonoid compound, characterized by its antioxidant and anti-inflammatory properties. It is derived from various plant sources and has been recognized for its potential health benefits and applications in different industries.

53527-42-7

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53527-42-7 Usage

Uses

Used in Pharmaceutical Industry:
Luteolin-3'-D-glucuronide is used as a therapeutic agent for its potential acetylcholinesterase activity, which may contribute to the treatment of neurological disorders and cognitive impairments.
Used in Food Industry:
Luteolin-3'-D-glucuronide is used as a strong antioxidant in the food industry, where it helps to extend the shelf life of products, protect them from oxidative damage, and enhance their nutritional value.
Used in Cosmetic Industry:
Luteolin-3'-D-glucuronide is used as an active ingredient in cosmetic products due to its antioxidant and anti-inflammatory properties, which can help protect the skin from environmental stressors and promote a healthy complexion.

Check Digit Verification of cas no

The CAS Registry Mumber 53527-42-7 includes 8 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 5 digits, 5,3,5,2 and 7 respectively; the second part has 2 digits, 4 and 2 respectively.
Calculate Digit Verification of CAS Registry Number 53527-42:
(7*5)+(6*3)+(5*5)+(4*2)+(3*7)+(2*4)+(1*2)=117
117 % 10 = 7
So 53527-42-7 is a valid CAS Registry Number.

53527-42-7Downstream Products

53527-42-7Relevant academic research and scientific papers

Identification of flavone glucuronide isomers by metal complexation and tandem mass spectrometry: Regioselectivity of uridine 5′-diphosphate- glucuronosyltransferase isozymes in the biotransformation of flavones

Robotham, Scott A.,Brodbelt, Jennifer S.

, p. 1457 - 1463 (2013/04/23)

Flavone glucuronide isomers of five flavones (chrysin, apigenin, luteolin, baicalein, and scutellarein) were differentiated by collision-induced dissociation of [Co(II) (flavone-H) (4,7-diphenyl-1,10-phenanthroline) 2]+ complexes. The complexes were generated via postcolumn addition of a metal-ligand solution after separation of the glucuronide products generated upon incubation of each flavone with an array of uridine 5′-diphosphate (UDP)-glucuronosyltransferase (UGT) isozymes. Elucidation of the glucuronide isomers allowed a systematic investigation of the regioselectivity of 12 human UGT isozymes, including 8 UGT1A and 4 UGT2B isozymes. Glucuronidation of the 7-OH position was the preferred site for all the flavones except for luteolin, which possessed adjacent hydroxyl groups on the B ring. For all flavones and UGT isozymes, glucuronidation of the 5-OH position was never observed. As confirmed by the metal complexation/MS/MS strategy, glucuronidation of the 6-OH position only occurred for baicalein and scutellarein when incubated with three of the UGT isozymes.

Accurate prediction of glucuronidation of structurally diverse phenolics by human UGT1A9 using combined experimental and in silico approaches

Wu, Baojian,Wang, Xiaoqiang,Zhang, Shuxing,Hu, Ming

experimental part, p. 1544 - 1561 (2012/07/27)

Purpose: Catalytic selectivity of human UGT1A9, an important membrane-bound enzyme catalyzing glucuronidation of xenobiotics, was determined experimentally using 145 phenolics and analyzed by 3D-QSAR methods. Methods: Catalytic efficiency of UGT1A9 was determined by kinetic profiling. Quantitative structure activity relationships were analyzed using CoMFA and CoMSIA techniques. Molecular alignment of substrate structures was made by superimposing the glucuronidation site and its adjacent aromatic ring to achieve maximal steric overlap. For a substrate with multiple active glucuronidation sites, each site was considered a separate substrate. Results: 3D-QSAR analyses produced statistically reliable models with good predictive power (CoMFA: q 2=0.548, r2=0.949, r pred 2 =0.775; CoMSIA: q2=0.579, r2=0.876, rpred2 =0.700). Contour coefficient maps were applied to elucidate structural features among substrates that are responsible for selectivity differences. Contour coefficient maps were overlaid in the catalytic pocket of a homology model of UGT1A9, enabling identification of the UGT1A9 catalytic pocket with a high degree of confidence. Conclusion: CoMFA/CoMSIA models can predict substrate selectivity and in vitro clearance of UGT1A9. Our findings also provide a possible molecular basis for understanding UGT1A9 functions and substrate selectivity.

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