N-desmethyl Rosiglitazone
(Synonyms: N-去甲罗格列酮) 目录号 : GC41380A major metabolite of rosiglitazone
Cas No.:257892-31-2
Sample solution is provided at 25 µL, 10mM.
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Quality Control & SDS
- View current batch:
- Purity: >98.00%
- COA (Certificate Of Analysis)
- SDS (Safety Data Sheet)
- Datasheet
N-desmethyl Rosiglitazone is a major metabolite of rosiglitazone , a potent and selective PPARγ ligand present in formulations that have been used to treat type 2 diabetes. Rosiglitazone is metabolized by the cytochrome P450 (CYP) isoform CYP2C8 to form N-desmethyl rosiglitazone.
| Cas No. | 257892-31-2 | SDF | |
| 别名 | N-去甲罗格列酮 | ||
| Canonical SMILES | O=C(C(S1)CC(C=C2)=CC=C2OCCNC3=NC=CC=C3)NC1=O | ||
| 分子式 | C17H17N3O3S | 分子量 | 343.4 |
| 溶解度 | DMF: 25 mg/ml,DMSO: 34 mg/ml,DMSO:PBS(pH 7.2) (1:3): 0.5 mg/ml,Ethanol: 1 mg/ml | 储存条件 | Store at -20°C |
| General tips | 请根据产品在不同溶剂中的溶解度选择合适的溶剂配制储备液;一旦配成溶液,请分装保存,避免反复冻融造成的产品失效。 储备液的保存方式和期限:-80°C 储存时,请在 6 个月内使用,-20°C 储存时,请在 1 个月内使用。 为了提高溶解度,请将管子加热至37℃,然后在超声波浴中震荡一段时间。 |
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| Shipping Condition | 评估样品解决方案:配备蓝冰进行发货。所有其他可用尺寸:配备RT,或根据请求配备蓝冰。 | ||
| 制备储备液 | |||
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1 mg | 5 mg | 10 mg |
| 1 mM | 2.9121 mL | 14.5603 mL | 29.1206 mL |
| 5 mM | 0.5824 mL | 2.9121 mL | 5.8241 mL |
| 10 mM | 0.2912 mL | 1.456 mL | 2.9121 mL |
| 第一步:请输入基本实验信息(考虑到实验过程中的损耗,建议多配一只动物的药量) | ||||||||||
| 给药剂量 | mg/kg |  |
动物平均体重 | g | |
每只动物给药体积 | ul | |
动物数量 | 只 |
| 第二步:请输入动物体内配方组成(配方适用于不溶于水的药物;不同批次药物配方比例不同,请联系GLPBIO为您提供正确的澄清溶液配方) | ||||||||||
| % DMSO % % Tween 80 % saline | ||||||||||
| 计算重置 | ||||||||||
计算结果:
工作液浓度: mg/ml;
DMSO母液配制方法: mg 药物溶于 μL DMSO溶液(母液浓度 mg/mL,
体内配方配制方法:取 μL DMSO母液,加入 μL PEG300,混匀澄清后加入μL Tween 80,混匀澄清后加入 μL saline,混匀澄清。
1. 首先保证母液是澄清的;
2.
一定要按照顺序依次将溶剂加入,进行下一步操作之前必须保证上一步操作得到的是澄清的溶液,可采用涡旋、超声或水浴加热等物理方法助溶。
3. 以上所有助溶剂都可在 GlpBio 网站选购。
An improved LC-ESI-MS-MS method for simultaneous quantitation of rosiglitazone and N-desmethyl Rosiglitazone in human plasma
J Pharm Biomed Anal 2008 Nov 4;48(3):934-9.PMID:18818043DOI:10.1016/j.jpba.2008.08.001.
A fast, sensitive, and selective method for the simultaneous quantitation of rosiglitazone and N-desmethyl Rosiglitazone in human plasma, using rosiglitazone-d(4) and N-desmethyl rosiglitazone-d(4) as the respective internal standards, has been developed and validated. The analytes in human plasma (50 microL sample aliquot) were isolated through supported liquid/liquid extraction (SLE) and separated by isocratic HPLC over a 3-min period. The precursor and product ions were detected by ESI-MS-MS with multiple reaction monitoring (MRM) in a triple quadrupole mass spectrometer. For both rosiglitazone and N-desmethyl Rosiglitazone, the lower limit of quantitation (LLOQ) was 1.00 ng/mL, and the quantitation range was 1.00-500 ng/mL (with an average correlation coefficient >0.9990). The intra-assay and inter-assay precision had a maximum %CV of 9.37%, and the accuracy had a maximum %difference from theoretical of 12.7%. This method was applied to a clinical study where 16 healthy volunteers were administered a single dose of 4.0mg rosiglitazone. The pharmacokinetic parameters of rosiglitazone and N-desmethyl Rosiglitazone were consistent with the results reported in the literature.
Simultaneous quantification of rosiglitazone and its two major metabolites, N-desmethyl and p-hydroxy rosiglitazone in human plasma by liquid chromatography/tandem mass spectrometry: application to a pharmacokinetic study
J Chromatogr B Analyt Technol Biomed Life Sci 2009 Jul 1;877(20-21):1951-6.PMID:19477697DOI:10.1016/j.jchromb.2009.05.001.
We present a simple, rapid, and sensitive liquid chromatography (LC)-tandem mass spectrometry (MS/MS) method for the simultaneous quantification of rosiglitazone and its two major metabolites via CYP2C8/9, N-desmethyl and p-hydroxy rosiglitazone, in human plasma. The procedure was developed and validated using rosiglitazone-d(3) as the internal standard. Plasma samples (0.1 ml) were prepared using a simple deproteinization procedure with 0.2 ml of acetonitrile containing 40 ng/ml of rosiglitazone-d(3). Chromatographic separation was carried out on a Luna C18 column (100 mm x 2.0 mm, 3-microm particle size) using an isocratic mobile phase consisting of a 60:40 (v/v) mixture of acetonitrile and 0.1% formic acid((aq)). Each sample was run at 0.2 ml/min for a total run time of 2.5 min per sample. Detection and quantification were performed using a mass spectrometer in selected reaction-monitoring mode with positive electrospray ionization at m/z 358.1-->135.1 for rosiglitazone, m/z 344.2-->121.1 for N-desmethyl Rosiglitazone, m/z 374.1-->151.1 for p-hydroxy rosiglitazone, and m/z 361.1-->138.1 for rosiglitazone-d(3). The linear ranges of concentration for rosiglitazone, N-desmethyl Rosiglitazone, and p-hydroxy rosiglitazone were 1-500, 1-150, and 1-25 ng/ml, respectively, with a lower limit of quantification of 1 ng/ml for all analytes. The coefficient of variation for assay precision was less than 14.4%, and the accuracy was 93.3-112.3%. No relevant cross-talk and matrix effect were observed. This method was successfully applied to a pharmacokinetic study after oral administration of a 4-mg rosiglitazone tablet to healthy male Korean volunteers.
In vitro characterization of rosiglitazone metabolites and determination of the kinetic parameters employing rat liver microsomal fraction
Eur J Drug Metab Pharmacokinet 2011 Sep;36(3):159-66.PMID:21499911DOI:10.1007/s13318-011-0039-8.
Rosiglitazone (RSG), a thiazolidinedione antidiabetic drug, is metabolized by CYP450 enzymes into two main metabolites: N-desmethyl Rosiglitazone (N-Dm-R) and ρ-hydroxy rosiglitazone (ρ-OH-R). In humans, CYP2C8 appears to have a major role in RSG metabolism. On the other hand, the in vitro metabolism of RSG in animals has not been described in literature yet. Based on these concerns, the kinetic metabolism study of RSG using rat liver microsomal fraction is described for the first time. Maximum velocity (V (max)) values of 87.29 and 51.09 nmol/min/mg protein were observed for N-Dm-R and ρ-OH-R, respectively. Michaelis-Menten constant (K(m)) values were of 58.12 and 78.52 μM for N-Dm-R and ρ-OH-R, respectively. Therefore, these results demonstrated that this in vitro metabolism model presents the capacity of forming higher levels of N-Dm-R than of ρ-OH-R, which also happens in humans. Three other metabolites were identified employing mass spectrometry detection under positive electrospray ionization: ortho-hydroxy-rosiglitazone (ο-OH-R) and two isomers of N-desmethyl hydroxy-rosiglitazone. These metabolites have also been observed in humans. The results observed in this study indicate that rats could be a satisfactory model for RSG metabolism.
Characterization of the cytochrome P450 enzymes involved in the in vitro metabolism of rosiglitazone
Br J Clin Pharmacol 1999 Sep;48(3):424-32.PMID:10510156DOI:10.1046/j.1365-2125.1999.00030.x.
To identify the human cytochrome P450 enzyme(s) involved in the in vitro metabolism of rosiglitazone, a potential oral antidiabetic agent for the treatment of type 2 diabetes-mellitus. Method The specific P450 enzymes involved in the metabolism of rosiglitazone were determined by a combination of three approaches; multiple regression analysis of the rates of metabolism of rosiglitazone in human liver microsomes against selective P450 substrates, the effect of selective chemical inhibitors on rosiglitazone metabolism and the capability of expressed P450 enzymes to mediate the major metabolic routes of rosiglitazone metabolism. Result The major products of metabolism following incubation of rosiglitazone with human liver microsomes were para-hydroxy and N-desmethyl Rosiglitazone. The rate of formation varied over 38-fold in the 47 human livers investigated and correlated with paclitaxel 6alpha-hydroxylation (P<0.001). Formation of these metabolites was inhibited significantly (>50%) by 13-cis retinoic acid, a CYP2C8 inhibitor, but not by furafylline, quinidine or ketoconazole. In addition, both metabolites were produced by microsomes derived from a cell line transfected with human CYP2C8 cDNA. There was some evidence for CYP2C9 playing a minor role in the metabolism of rosiglitazone. Sulphaphenazole caused limited inhibition (<30%) of both pathways in human liver microsomes and microsomes from cells transfected with CYP2C9 cDNA were able to mediate the metabolism of rosiglitazone, in particular the N-demethylation pathway, albeit at a much slower rate than CYP2C8. Rosiglitazone caused moderate inhibition of paclitaxel 6alpha-hydroxylase activity (CYP2C8; IC50=18 microm ), weak inhibition of tolbutamide hydroxylase activity (CYP2C9; IC50=50 microm ), but caused no marked inhibition of the other cytochrome P450 activities investigated (CYP1A2, 2A6, 2C9, 2C19, 2D6, 2E1, 3A and 4A). Conclusion CYP2C8 is primarily responsible for the hydroxylation and N-demethylation of rosiglitazone in human liver; with minor contributions from CYP2C9.
Simultaneous determination of rosiglitazone and its metabolites in rat liver microsomal fraction using hollow-fiber liquid-phase microextraction for sample preparation
J Sep Sci 2010 Sep;33(17-18):2872-80.PMID:20715144DOI:10.1002/jssc.201000380.
A three-phase hollow-fiber liquid-phase microextraction method for the analysis of rosiglitazone and its metabolites N-desmethyl Rosiglitazone and ρ-hydroxy rosiglitazone in microsomal preparations is described for the first time. The drug and metabolites HPLC determination was carried out using an X-Terra RP-18 column, at 22°C. The mobile phase was composed of water, acetonitrile and acetic acid (85:15:0.5, v/v/v) and the detection was performed at 245 nm. The hollow-fiber liquid-phase microextraction procedure was optimized using multifactorial experiments and the following optimal condition was established: sample agitation at 1750 rpm, extraction for 30 min, hydrochloric acid 0.01 mol/L as acceptor phase, 1-octanol as organic phase, and donor phase pH adjustment to 8.0. The recovery rates, obtained by using 1 mL of microsomal preparation, were 47-70%. The method presented LOQs of 50 ng/mL and it was linear over the concentration range of 50-6000 ng/mL, with correlation coefficients (r) higher than 0.9960, for all analytes. The validated method was employed to study the in vitro biotransformation of rosiglitazone using rat liver microsomal fraction.