大鼠肠内菌转化间尼索地平的代谢产物

应用LC-MS/MS法研究肠内菌转化间尼索地平的代谢产物.将间尼索地平与大鼠肠内菌于体外厌氧温孵培养,放大制备转化产率最高的代谢物.依据1H NMR和ESI-MS/MS数据确认代谢物结构,推断可能的代谢途径.结果在温孵液中发现了间尼索地平及其2种代谢产物.     

抗焦虑新药AF-5及其代谢物在人肝微粒体体外温孵体系中代谢研究

目的研究一类抗焦虑新药AF-5及其代谢物(I,II)在人肝微粒体体外温孵体系中代谢情况.方法自制人肝微粒体,用Lowry法测定酶活性为8.79mg·mL^-1.以此配制人肝微粒体体外温孵体系,加入药物,温孵后,提取分离,GC-MS测定.结果鉴定了AF-5在人肝微粒体体外温孵体系中的两个主要代谢物,并阐明了其体外代谢途径为AF-5的4位首先氧化为羟基,然后氧化成羰基.结论AF-5在体外人肝微粒体温孵体系中,100min后完全代谢成羟基代谢物I及羰基代谢物II,以羟基代谢物为主要代谢产物.AF-5代谢物I在人肝微粒体温孵体系中,可转化为代谢物II,而代谢物II在人肝中则不再代谢.     

柚皮苷的人肠内菌生物转化(英文)

柚皮苷(1)是酸橙中含量最高的二氢黄酮苷类化合物, 将其与人肠内菌丛共温孵, 从温孵物中通过色谱方法得到原形化合物1和四个转化产物 (2-5), 根据谱学数据确定它们分别为柚皮苷-6"-乙酰物(2)、柚皮素(3)、根皮酸(4)和间苯三酚(5)。在1的糖苷链葡萄糖基6位能够特异性地发生乙酰化作用。1口服难以吸收。本文结果为阐明其生物利用度低提供了实验依据, 推测表现其生物活性的物质基础主要是其肠内菌生物转化产物3。肠内菌丛所致1的生物转化的继发结果,是它的转化产物吸收进入体循环发挥生物学作用, 此结果为进一步或再评价其体内过程、作用或毒性及其生物利用度提供了有用的信息。     

左旋黄皮酰胺在大鼠肝微粒体中的代谢转化研究

用大鼠肝微粒体体外温孵法进行了左旋黄皮酰胺[(-)-clausenamide]代谢转化研究,优化了温孵体系,建立了反相HPLC-DAD同时分离检测左旋黄皮酰胺及其体外代谢产物的分析方法。用硅胶低压柱色谱、制备TLC及制备HPLC分离纯化了两个代谢产物并进行了光谱鉴定。结果表明,两个代谢物分别确定为6-和5-位羟基取代的黄皮酰胺。     

左旋一叶萩碱的代谢转化

目的　研究一叶碱 [securinine ,( - )SE]在大鼠体内外的代谢转化。方法　采用大鼠肝微粒体体外温孵法对 ( - )SE的代谢转化进行了研究 ,优化了代谢体系 ,建立了反相HPLC法同时分离检测 ( - )SE及其体外代谢产物的分析方法。用液液萃取 ,制备TLC及半制备HPLC分离纯化了 4个代谢产物并进行了光谱鉴定。在此基础上 ,建立了生物体液中 ( - )SE及其代谢物的反相HPLC分析方法 ,并用该法检测了ip给药后大鼠的胆汁、尿样及其经 β 葡糖醛酸苷酶水解后的样品。结果　代谢物分别鉴定为 6 位羟基 ,6 位羰基及 5 位α及 β羟基取代的 ( - )SE ,还证实了体内 6 位羟基代谢物进一步形成了二相结合型产物。结论　基本阐明 ( - )SE在大鼠体内外代谢转化的途径     

左旋一叶碱的代谢转化

目的研究一叶碱［securinine,(-)SE］在大鼠体内外的代谢转化。方法采用大鼠肝微粒体体外温孵法对(-)SE的代谢转化进行了研究,优化了代谢体系,建立了反相HPLC法同时分离检测(-)SE及其体外代谢产物的分析方法。用液液萃取,制备TLC及半制备HPLC分离纯化了4个代谢产物并进行了光谱鉴定。在此基础上,建立了生物体液中(-)SE及其代谢物的反相HPLC分析方法,并用该法检测了ip给药后大鼠的胆汁、尿样及其经β-葡糖醛酸苷酶水解后的样品。结果代谢物分别鉴定为6-位羟基,6-位羰基及5-位α及β羟基取代的(-)SE,还证实了体内6-位羟基代谢物进一步形成了二相结合型产物。结论基本阐明(-)SE在大鼠体内外代谢转化的途径。     

大鼠和人肠道菌群对苯环喹溴铵代谢转化作用的研究

目的:研究大鼠和人肠道菌群对苯环喹溴铵(BCQB)代谢的影响。方法:采用体外肠道菌群代谢方法,将大鼠或人的粪便溶解于人工肠液中,搅拌混合后过滤,滤液加入1mg·mL-1的苯环喹溴铵溶液0.5mL,于37℃厌氧培养48h,采用高效液相色谱串联质谱法对大鼠或人肠内菌温孵液样品进行分离和定性分析,并设不加BCQB溶液的大鼠或人肠内菌温孵液为空白样品。结果:与空白样品比较,大鼠或人肠内菌温孵液样品中总离子流色谱中除BCQB峰外未见新增色谱峰,其质谱碎片信息显示只有BCQB的特征碎片离子,未检测到BCQB的代谢产物。结论:在离体条件下,BCQB不被大鼠和人的肠道菌群代谢。     

二苯乙烯苷在大鼠体内外的代谢研究

采用肝微粒体温孵和大肠杆菌培养等方法对二苯乙烯苷进行体外代谢研究.灌胃给予二苯乙烯苷后,对大鼠血液、胆汁、尿液、粪便、胃和小肠内容物进行体内代谢产物分析,并通过制备液相色谱从胆汁中获得主要代谢物的纯品,采用1HNMR、13CNMR及MS方法进行结构确证.结果表明,二苯乙烯苷在大鼠肝脏代谢为葡萄糖醛酸结合物,并经胆汁排泄,在肠道内菌或酶的作用下水解为二苯乙烯苷随粪便排出.     

山柰苷的人肠内细菌生物转化研究

目的探讨人肠内细菌对中药罗汉果中山柰苷的生物转化。方法采用人肠内细菌与山柰苷共温孵培养的方法，通过色谱技术分离、纯化转化产物，应用谱学技术确定转化产物的结构。结果人肠内细菌转化山柰苷产生山柰酚3-O-α-L-吡喃鼠李糖苷(阿福豆苷)、山柰酚7-O-α-L-吡喃鼠李糖苷、山柰酚和对-羟基苯甲酸。结论山柰苷可被人肠内细菌进行生物转化。     

蓝萼甲素在大鼠体内外的代谢转化

目的研究蓝萼甲素在大鼠体内外的代谢转化。方法采用大鼠肝微粒体体外温孵法,研究对蓝萼甲素的代谢转化。采用RP-HPLC法同时分离检测蓝萼甲素及其体外代谢产物。结果用液-液萃取、制备HPLC法,从大鼠胆汁中分离了一个代谢产物,经质谱分析推测结构为羟基化蓝萼甲素,并采用HPLC-MS连用,分析了肝微粒体体外温孵样品中的代谢产物,推测了蓝萼甲素的可能代谢转化途径。结论蓝萼甲素在大鼠肝微粒体和胆汁中可被代谢转化,主要代谢产物为羟基化蓝萼甲素。     

刺五加苷B、苷E在体外大鼠肠道菌群中的代谢

目的：观察体外大鼠肠道菌群对刺五加苷B、苷E的代谢。方法：收集大鼠新鲜粪便在厌氧培养基37℃培养24h,分别加入刺五加苷B、刺五加苷E,培养后加甲醇提取离心,取上清液采用HPLC及UPLC/MS方法对代谢成分进行分离和定性分析。结果：刺五加苷B、苷E在大鼠粪便孵育液中代谢,24h后样本中能检测出较高浓度代谢物。在离体条件下,刺五加苷B、苷E可以被大鼠的肠道菌群代谢,经过UPLC/MS的检测,刺五加苷B代谢物的分子离子峰[M＋H]~＋为193.08,推测为刺五加苷B的苷元再脱一分子水;刺五加苷E代谢物的分子离子峰[M＋H]~＋为417.17,推测为刺五加苷B的苷元。结论：刺五加苷B、苷E可以被大鼠肠道菌群代谢。     

Structural elucidation of in vivo and in vitro metabolites of anisodine by liquid chromatography-tandem mass spectrometry

Liquid chromatography-electrospray ionization tandem mass spectrometry (LC-ESIMSn) was employed to investigate the in vivo and in vitro metabolism of anisodine. Feces, urine and plasma samples were collected after ingestion of 20 mg anisodine to healthy rats. Feces and urine samples were cleaned up by liquid-liquid extraction and solid-phase extraction procedures (C18 cartridges), respectively. Methanol was added to plasma samples to precipitate plasma proteins. Anisodine was incubated with homogenized liver and intestinal flora of rats in vitro, respectively, followed by extraction with ethyl acetate. LC-MSn was used for the separation and identification of the metabolites using C18 column with mobile phase of methanol/0.01% triethylamine solution (2 mM, adjusted to pH 3.5 with formic acid) (60:40, v/v). The results revealed that five metabolites (norscopine, scopine, alpha-hydroxytropic acid, noranisodine and hydroxyanisodine) and the parent drug existed in feces. Three new metabolites (dimethoxyanisodine, tetrahydroxyanisodine and trihydroxy-methoxyanisodine) were identified in urine. Four metabolites (norscopine, scopine, hydroxyanisodine and anisodine N-oxide) and the parent drug were detected in plasma. Two hydrolyzed metabolites (scopine and alpha-hydroxytropic acid) were found in rat intestinal flora incubation mixture, and two metabolites (aponoranisodine and anisodine N-oxide) were identified in homogenized liver incubation mixture.     

基于肠心轴学说探讨肠道菌群在心血管疾病中的作用

肠道内庞大的菌群之间相互依存、相互制约,协同参与机体生理代谢和营养物质的消化。肠道菌群与心血管健康相关研究已成为十分重要的研究领域,肠道菌群组成的改变、肠道菌群产生的代谢产物和毒素都能引发心血管系统的病变。心血管疾病(cardiovascular disease,CVD)因高发病率和死亡率已成为一个主要的健康问题,CVD的发生、发展中肠道特定菌群的改变已被确定为疾病发生的关键因素。然而,肠道菌群及其代谢产物如何产生及影响CVD的潜在机制仍不清楚。本文就肠道菌群通过肠心轴调节CVD的最新研究进展进行综述,重点总结肠道微生物及其代谢产物与CVD发生发展之间复杂的相互作用,以及肠道菌群失调的改变对心血管事件发生的影响,探讨肠道菌群与CVD发病机制之间的因果联系。     

Characterization of metabolites of worenine in rat biological samples using liquid chromatography–tandem mass spectrometry

The in vivo and in vitro metabolites of worenine in rat were identified or characterized using a specific and sensitive liquid chromatography–tandem mass spectrometry (LC–MS/MS) method. In vivo samples including rat urine, feces, and plasma samples were collected after ingestion of 25 mg/kg worenine to healthy rats. The in vivo and in vitro samples were cleaned up by a solid-phase extraction procedure (C18 cartridges) and a liquid–liquid extraction procedure, respectively. Then these pretreated samples were injected into a reversed-phase C18 column with mobile phase of methanol–ammonium acetate (2 mM, adjusted to pH 3.5 with formic acid) (60:40, v/v) and detected by an on-line MS/MS system. As a result, at least twenty-seven metabolites and the parent medicine were found in rat urine after ingestion of worenine. Seven metabolites and the parent medicine were identified or characterized in rat feces. Three metabolites and the parent medicine were detected in rat plasma. One metabolite was found in the rat intestinal flora incubation mixture, and three metabolites were characterized in the homogenized liver incubation mixture. The main phase I metabolism of worenine in rat was dehydrogenization, hydrogenation, hydroxylation, and demethylene reactions, and that of phase II was sulfation and glucuronidation.     

离体培养人肠道菌群对黄山药总皂苷的代谢研究

目的通过离体实验观察人肠道内细菌对黄山药总皂苷的代谢。方法离体培养人肠道内细菌，与黄山药总皂苷厌氧温孵，薄层色谱检测黄山药总皂苷的代谢，采用硅胶柱色谱对黄山药总皂苷肠道代谢产物进行分离和代谢转化产物的结构鉴定。结果代谢产物经IR、EI—MS、DEPT和NMR鉴定为，25（R）-螺甾-5-烯-3β，20（S）-二醇，此化合物为新的天然产物。结论体外模拟的人肠道菌群对黄山药总皂苷有代谢作用，其中转化出的新成分是不是起药理活性的真正成分，有待进一步确证。     

Identification of metabolites of tectoridin in-vivo and in-vitro by liquid chromatography-tandem mass spectrometry

In this work, liquid chromatography-electrospray ionization tandem ion-trap mass spectrometry (LC-MS(n)) was used to investigate the in-vivo and in-vitro metabolism of tectoridin. After oral administration of a single dose (100 mg kg(-1)) of tectoridin to healthy rats, faeces and urine samples were collected for 0-48 h and 0-24 h, respectively. Tectoridin was also incubated with rat intestinal flora and rat liver microsomes. Samples from in-vivo and in-vitro metabolism studies were purified using a C(18) solid-phase extraction cartridge, then separated using a reverse-phase C(18) column with methanol/ water (30:70, v/v, adjusted to pH 10.0 with ammonia water) as mobile phase and detected by an on-line MS(n) system. The structure of the metabolites was elucidated by comparing their molecular weights, retention times and full-scan MS(n) spectra with those of the parent drug. The results revealed six metabolites of tectoridin in urine (tectorigenin, hydrogenated tectorigenin, mono-hydroxylated tectorigenin, di-hydroxylated tectorigenin, glucuronide-conjugated tectorigenin and sulfate-conjugated tectorigenin); three metabolites in faeces (tectorigenin, di-hydroxylated tectorigenin and sulfateconjugated tectorigenin); one metabolite in the intestinal flora incubation mixture (tectorigenin), and four in the liver microsomal incubation mixture (tectorigenin, hydrogenated tectorigenin, mono-hydroxylated tectorigenin and di-hydroxylated tectorigenin). Except for tectorigenin, all other metabolites of tectoridin are reported for the first time.     

Identification of in‐vivo and in‐vitro metabolites of palmatine by liquid chromatography–tandem mass spectrometry

Objectives Despite its important therapeutic value, the metabolism of palmatine is not yet clear. Our objective was to investigate its in‐vivo and in‐vitro metabolism. Methods Liquid chromatography–tandem electrospray ionization mass spectrometry (LC‐ESI/MSⁿ) was employed in this work. In‐vivo samples, including faeces, urine and plasma of rats, were collected after oral administration of palmatine (20 mg/kg) to rats. In‐vitro samples were prepared by incubating palmatine with intestinal flora and liver microsome of rats, respectively. All the samples were purified via a C₁₈ solid‐phase extraction procedure, then chromatographically separated by a reverse‐phase C₁₈ column with methanol–formic acid aqueous solution (pH 3.5, 70: 30 v/v) as mobile phase, and detected by an on‐line MSⁿ detector. The structure of each metabolite was elucidated by comparing its molecular weight, retention time and full‐scan MSⁿ spectra with those of the parent drug. Key findings The results revealed that 12 metabolites were present in rat faeces, 13 metabolites in rat urine, 7 metabolites in rat plasma, 10 metabolites in rat intestinal flora and 9 metabolites in rat liver microsomes. Except for six of the metabolites in rat urine, the other in‐vivo and in‐vitro metabolites were reported for the first time. Conclusions Seven new metabolites of palmatine (tri‐hydroxyl palmatine, di‐demethoxyl palmatine, tri‐demethyl palmatine, mono‐demethoxyl dehydrogen palmatine, di‐demethoxyl dehydrogen palmatine, mono‐demethyl dehydrogen palmatine, tri‐demethyl dehydrogen palmatine) were reported in this work.     

Biotransformation of the xanthine oxidase inhibitor BOF-4272 and its metabolites in the liver and by the intestinal flora in rat

1. BOF-4272, (+/-)-8-(3-methoxy-4-phenylsulfinylphenyl) pyrazolo[1,5-a]-1,3,5-triazine-4(1H)-one), is a new drug intended for the treatment of hyperuricaemia. 2. This paper describes the detailed biotransformation of BOF-4272 andits metabolites in the liver and by the intestinal flora in rat. 3. Only the sulphoxide metabolite (M6) was detected in plasma in small amounts after the intravenous administration of M4 (hydroxy-BOF-4272) and in culture medium after the addition of M4. 4. Only M3 (the sulphide metabolite of M4) was detected in faeces, and its amount was ~50% of the administered dose within 1 day after the intravenous administration of M4. 5. These findings suggest that M4, which is excreted in the bile, is metabolized mainly to M3 (the corresponding sulphide of M4) by the intestinal flora in rat, whereas little M4 is metabolized to the sulphoxide (M6) in the rat liver. 6. M2, which is the demethylated form of BOF-4269, was detected in faeces after the oral administration of BOF-4272 to rat in which the common bile duct was cannulated, suggesting that BOF-4272 is metabolized to BOF-4269 and then to M2 by the intestinal flora. 7. These findings suggest that in rat the sulphoxide of BOF-4272 and its metabolites are demethylated and reduced by the intestinal flora, with other types of biotransformation occurring in the liver.     

Biotransformation of the xanthine oxidase inhibitor BOF-4272 and its metabolites in the liver and by the intestinal flora in rat

1. BOF-4272, (+/-)-8-(3-methoxy-4-phenylsulfinylphenyl) pyrazolo[1,5-a]-1,3,5-triazine-4(1H)-one), is a new drug intended for the treatment of hyperuricaemia. 2. This paper describes the detailed biotransformation of BOF-4272 and its metabolites in the liver and by the intestinal flora in rat. 3. Only the sulphoxide metabolite (M6) was detected in plasma in small amounts after the intravenous administration of M4 (hydroxy-BOF-4272) and in culture medium after the addition of M4. 4. Only M3 (the sulphide metabolite of M4) was detected in faeces, and its amount was approximately 50% of the administered dose within 1 day after the intravenous administration of M4. 5. These findings suggest that M4, which is excreted in the bile, is metabolized mainly to M3 (the corresponding sulphide of M4) by the intestinal flora in rat, whereas little M4 is metabolized to the sulphoxide (M6) in the rat liver. 6. M2, which is the demethylated form of BOF-4269, was detected in faeces after the oral administration of BOF-4272 to rat in which the common bile duct was cannulated, suggesting that BOF-4272 is metabolized to BOF-4269 and then to M2 by the intestinal flora. 7. These findings suggest that in rat the sulphoxide of BOF-4272 and its metabolites are demethylated and reduced by the intestinal flora, with other types of biotransformation occurring in the liver.