fied by UPLC ESI Afatinib Q TOF MS and 1H NMR. The mass spectrometer parameters were set as follows: capillary voltage, 4.5KV; ion source temperature, 350 C, desolvation temperature, 108 C; nebulizer gas , nitrogen, 40 psi; turbo gas , argon gas, 20 psi. The UPLC method developed for emodin had a run time of 4 min along with a linear calibration curve over the concentration selection of 0.6125 40 M . The intra and inter day variabilities at 1.25, 10, and 40 M of emodin were much less than 4.2 and 3.8 , respectively. In microsomal incubation samples, a single new peak eluted at 1.92 min . A UPLC ESI Q TOF MS running at a negative ion mode was applied to establish the MS spectrum of the metabolite. The mass spectra of this metabolite exhibited a molecular ion at m z 445.0780, calculated as C21H17O11: 445.
0776, Afatinib which corresponded to the molecular weight of emodin glucuronide, as well as the significant fragment ion at m z 269.0462, which corresponded to the molecular weight of emodin . LC MS MS study also indicated that all metabolites generated from a variety of microsomes of distinct species showed identical mono glucuronide of emodin . The UV spectra of emodin glucuronide and emodin were similar, which were supportive of the notion that the new eluted peak is closely related to emodin. 1H NMR spectra of the metabolite displayed really similar signals with those of emodin except for the signals derived from an added sugar moiety which was determined to be glucuronide group from its H 1 signal at 5.14 and H 5 signal at 4.21 . The location of glucuronide group was confirmed to be at 3 OH by the observation of NOE correlations between the anomeric proton with both H 4 and H 2 in the NOESY spectrum shown in Fig.
1d. According to the above evidences, the metabolite was identified as emodin 3 O D glucuronide . Due to the fact the same glucuronide was identified in all glucuronidation reactions using liver microsomes of any species or gender, emodin Everolimus 3 O D glucuronide was the only glucuronide formed in the present study. Glucuronidation of Emodin by Rat Liver Microsomes Emodin was quickly glucuronidated by rat liver microsomes . Soon after 15 min, only 20 of emodin was left . Soon after incubation times of 30 min, 1 h, and 2 h, percent remaining were 9.73 , 5.73 , and 1.87 , respectively. Phase I Metabolism of Emodin by Rat Liver Microsomes For phase I oxidation reaction conducted using identical concentration of rat liver microsomes, the percent emodin remaining was 84.
81 soon after 15 min of reaction time. Soon after reaction times of 0.5, 1, and 2 h, the percent remaining were 65.53 , 42.53 , and 28.35 , respectively . For that reason, it was clear that oxidative metabolism was a minimum of five times slower VEGF than glucuronidation. In oxidative metabolism, a single major metabolite was identified, which was eluted at the retention time of 2.07 min along with a molecular ion at 285.16 Da, 16 more than that of emodin , indicating that the compound is really a hydroxylated metabolite of emodin . The MS MS spectrum of item ion at m z 255 and m z 268 suggested that the metabolite must be hydroxyemodin, as reported previously . The MS2 profile of the hydroxyemodin is noticed in Fig. 2a, but we were unable to assign the position of the hydroxylation.
Metabolism of Emodin in a Mixed Oxidation and Glucuronidation Reaction System The mixed program of oxidation and glucuronidation reaction was applied to establish Everolimus the primary pathway of metabolism of emodin by using male rat liver Afatinib microsomes at 1.67 mg mL with both oxidation and glucuronidation reaction cofactors. Detectable amount of emodin glucuronide was observed within 6 min of incubation, and emodin was metabolized nearly totally within 1 h. The metabolite was confirmed to be emodin 3 O D glucuronide by LCMS MS, which was the only metabolite identified in the mixed reaction program. There were no detectable amounts of hydroxyemodin identified in the mixed reaction program, confirming earlier observation that glucuronidation reaction was substantially a lot more rapid than oxidation reaction.
Intestinal Absorption and Metabolism of Emodin Absorption of emodin displayed regional difference in male but not in female rats . On the other Everolimus hand, excretion of emodin glucuronide displayed region dependence in both male and female rats . The amounts of emodin glucuronide excreted in duodenum were considerable greater than that in jejunum, followed by ileum and colon in male rats . In female rats, the rank order of amounts of metabolite excreted was jejunum≈duodenum ileum colon . The amounts of emodin absorbed in each of the four regions of female rat intestine were greater than that in the male rats , and selection of the improve was 27 44 . In contrast, amounts of emodin glucuronide excreted were greater in each of the four segments of intestine in the male rats than the female rats , as well as the selection of the improve was 40 67 , indicating somewhat larger difference in metabolism than in excretion. Concentration Dependent Glucuronidation of Emodin by Rat Intestinal Microsomes To establish if the above observed pattern of metabolite excr
Wednesday, June 5, 2013
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