高效液相色谱法同时测定中药材虎掌南星的核苷类成分

建立了高效液相色谱同时测定中药材虎掌南星中核苷类活性成分(腺嘌呤、次黄嘌呤、黄嘌呤、尿苷、胸腺嘧啶、腺苷、鸟苷)含量的方法。以Lichrospher C18色谱柱(150 mm×4.6 mm, 5 μm)分离,以乙腈-水(含0.1%甲酸)为流动相,梯度洗脱,在254 nm下检测,腺嘌呤、次黄嘌呤、黄嘌呤、尿苷及鸟苷分别在1.6～50 mg/L范围内、胸腺嘧啶和腺苷分别在1.2～40 mg/L范围内的线性关系良好,相关系数均大于0.9995,加标回收率为98.9%～101.2%,相对标准偏差均小于3%。方法学考察结果显示符合含量测定要求,并应用于不同产地虎掌南星的测定。该方法操作简便、快速,结果可靠,重现性好,可作为虎掌南星质量评价的参考依据。     

毛细管区带电泳法测定冬虫夏草中的腺苷、腺嘌呤和尿嘧啶

建立了毛细管区带电泳法测定天然和人工冬虫夏草中腺苷、腺嘌呤和尿嘧啶含量的分析方法。采用15mmol/L硼砂＋14mmol/L磷酸二氢钠＋5％（V／V）甲醇（pH＝9.5）作为缓冲体系，在电压为18kV和检测波长为254nm的条件下，冬虫夏草提取液中的腺苷、腺嘌呤和尿嘧啶实现了基线分离。定量分析表明，3种成分的校正峰面积与质量浓度呈较好的线性关系(r≥0.9991）。考察了缓冲溶液的pH值、浓度及有机改性剂对腺苷、腺嘌呤和尿嘧啶迁移行为的影响。     

超高效液相色谱-四极杆/线性离子阱质谱法同时测定不同产地何首乌中10种核苷类成分

建立了何首乌药材中10种核苷类成分(尿嘧啶、胞苷、鸟嘌呤、尿苷、腺嘌呤、肌苷、鸟苷、胸苷、腺苷、2'-脱氧胞苷)的超高效液相色谱-串联四极杆/线性离子阱质谱(UPLC-QTRAP-MS/MS)同时测定的分析方法。不同产地何首乌样品用超纯水在室温下超声提取,提取液经高速离心处理,取上清液,经Waters Atlantis T3色谱柱(2.1 mm×150 mm,3μm),以甲醇-5 mmol/L醋酸铵(含0.1%冰醋酸)为流动相,0.4 m L/min梯度洗脱,采用正离子多反应监测(MRM)模式测定。10种核苷在一定浓度范围内具有良好的线性关系,相关系数均大于0.99,检出限为1.05~9.68 ng/m L;平均加标回收率为97.8%~104.8%,相对标准偏差(RSD)在1.8%~5.0%之间。该方法简便、灵敏、准确,为何首乌药材内在质量的评价和控制提供了可靠的检测方法。     

反相高效液相色谱法同时测定罗氏海盘车中的7种核苷化合物

建立了罗氏海盘车中7种核苷化合物的反相高效液相色谱分析测定方法。采用超声波辅助提取,选用两根不同的C18色谱柱串联,以甲醇和0.2%(体积分数)乙酸/水溶液为流动相梯度洗脱分离。优化的色谱条件为: 柱温为室温,检测波长为260 nm,流速为0.8 mL/min,进样量为20 μL。结果表明,7种核苷化合物在一定的浓度范围内线性关系良好,次黄嘌呤和胸苷的线性范围为0.65～40 mg/L,尿苷、黄嘌呤和肌苷的线性范围为0.80～40 mg/L,胸腺嘧啶的线性范围为1.15～40 mg/L,鸟苷的线性范围为0.50～40 mg/L。样品中7种核苷化合物的加标回收率为90.00%～105.00%,相对标准偏差为0.72%～3.23%。该方法操作简便、灵敏度高、重复性好,回收率高,适用于罗氏海盘车中7种核苷类成分的同时分析,也可用于罗氏海盘车的质量控制和综合评价。     

发酵虫草菌粉及产品指纹图谱建立及多指标成分分析

《中国药典》收载的发酵虫草菌粉产品的质量标准中,规定以鸟苷、腺苷、尿苷的含量作为评价相关产品质量的标准。但除此之外,还有许多其他的核苷类成分对发酵虫草菌粉质量控制的影响尚未被探讨。为探究发酵虫草菌粉及产品质控指标选择的合理性,采用超高效液相色谱-紫外检测法对19批发酵虫草菌粉及产品中9种核苷成分(尿嘧啶、胞苷、鸟嘌呤、尿苷、腺嘌呤、肌苷、鸟苷、胸苷、腺苷)进行了定量分析,建立了发酵虫草菌粉样品的指纹图谱,并结合统计学提供了一种分析指标性成分的方法。通过优化样品的提取方法,选择超声提取法制备19批发酵虫草菌粉及产品的供试液;采用Agilent Eclipse Plus C18色谱柱(150 mm×4.6 mm, 3.5 μm)进行色谱分析,以甲醇-水为流动相梯度洗脱,对方法的校正曲线、准确度、精密度、重复性和回收率进行了验证。结合对照品指认了指纹图谱中的9个核苷峰,并采用外标一点法测得了各核苷成分的含量。使用化学模式识别对指纹图谱中的共有峰进行分析,聚类分析和主成分分析得到了同样的分类结果:19批样品共分为5类,其中同一发酵虫草菌粉因工艺差异可分为2类,而心肝宝胶囊、百令胶囊、宁心宝胶囊则各单独分为1类。同时,使用主成分分析获得了各样品中的指标性成分,分别为尿苷、鸟苷、腺苷、腺嘌呤、尿嘧啶,并使用聚类分析再次进行确证,验证了指标性成分的合理性。     

微流控芯片测定丁溴东莨菪碱注射液中丁溴东莨菪碱

建立了微流控芯片非接触电导检测法测定丁溴东莨菪碱注射液中丁溴东莨菪碱含量的方法。优化选择3 mmol/LHAc+2 mmol/LNaAc(pH4.5)为缓冲溶液,1.0 mmol/Lβ-CD为添加剂,分离电压为2.00 kV,进样时间为10 s,丁溴东莨菪碱在2 min内可得到较好分离,线性范围为20～250μg/mL(r=0.998),检出限为6.0μg/mL(S/N=3),RSD为2.1%,加标回收率为97.0%～99.6%。     

HP 4851A二极管阵列分光光度计用于混合核苷和碱基的HPLC分析

用离子交换HPLC和二极管阵列分光光度计测定了核糖核苷和游离碱基. 在Nucleosil-scx-sμ柱上以磷酸盐缓冲液(pH5)为移动相, 分析了化学水解酵母核糖核酸产品分离过程的尿嘧啶, 胞嘧啶、腺嘌呤, 尿苷, 腺苷, 胞苷, 乌苷.     

LC/ESI-MS分离和测定冬虫夏草及其代用品的有效成分

本文报道采用电喷雾离子化(ESI),用高效液相色谱质谱联用法同时分离和测定冬虫夏草及其代用品中主要活性成分尿苷和腺苷的方法。本法使用Shimadzu VP ODS色谱柱,以水甲醇甲酸(90∶9.0∶1.0,V/V)为流动相,2 氯腺苷为内标,选择性离子检测(SIM)模式作定量分析。结果表明:尿苷和腺苷线性范围分别为2.0~110.0μg·mL-1和1.0~120.0μg·mL-1,检出限分别为0.3μg·mL-1和0.2μg·mL-1,标准加入回收率为97.0%~103.3%。该法已成功地用于冬虫夏草及其代用品中尿苷和腺苷的分析。     

基于UPLC-UV-Q-TOF MS的僵蚕嘌呤(核苷)类成分多指标定量指纹图谱研究北大核心CSCD

嘌呤(核苷)是机体细胞生命活动中的主要遗传物质,但目前缺乏对僵蚕中该类成分的整体定量研究。该文采用ACE Excel 2 AQ水性柱(2.1 mm×150 mm,2μm)进行分离,以10 mmol/L磷酸二氢钾水溶液-甲醇为流动相,分别优化了样品提取与色谱条件,建立了中药僵蚕中嘌呤(核苷)类成分的超高效液相色谱-紫外(UPLC-UV)指纹图谱方法。利用四极杆-飞行时间质谱(Q-TOF MS)对9个特征峰物质进行二级鉴定,并对其质谱裂解规律进行总结。其中,2′-甲氧基-鸟苷单磷酸、6-(β-羟基乙基氨基)-嘌呤、2′-甲氧基-腺苷单磷酸和N6-(2-羟乙基)-腺苷首次从僵蚕中鉴定。基于该方法,对其中的鸟嘌呤、尿苷、腺嘌呤、鸟苷、6-(β-羟基乙基氨基)-嘌呤、腺苷、N6-(2-羟乙基)-腺苷7个成分进行绝对定量测定。2′-甲氧基-鸟苷单磷酸和2′-甲氧基-腺苷单磷酸因缺乏对照品,采用相对定量分析。结果表明,各指标成分的精密度、重现性、稳定性、耐用性的相对标准偏差(RSD)均不大于5.0%,7种成分的线性关系良好(r^(2)≥0.9994),检出限(LOD)为0.266~0.474μg/mL,定量下限(LOQ)为0.843~1.58μg/mL,平均加标回收率为94.0%~101%,RSD不大于3.4%。采用该方法对13批不同产地僵蚕药材进行分析,发现各成分含量具有显著差异。该研究可为僵蚕的质量评价提供技术支持和科学依据。     

毛细管电泳高频电导法测定粉防己药材中的生物碱

建立了千金藤属植物粉防己中生物碱测定的毛细管电泳高频电导法,以融硅毛细管(150μm×60cm)为分离柱,1mmol LHAc 2mmol LNH4Ac 10mmol Lβ CD 2mmol LSDS缓冲液为电泳介质,分离电压14.0kV,用高频电导法检测,粉防己药材中粉防己碱和去甲粉防己碱可实现定量分离和检测。探讨了缓冲液的种类、浓度、添加剂、分离电压和进样量对分离和检测的影响;在优化条件下的线性范围分别为:粉防己碱12 5～900μg mL,去甲粉防己碱25 0～900μg mL;检出限分别为:粉防己碱6 25μg mL,去甲粉防己碱12.5μg mL;样品加标回收率分别为92.7%～98.9%和95.9%～101%。     

Simultaneous determination of nucleosides and their bases in Cordyceps sinensis and its substitutes by matrix solid‐phase dispersion extraction and HPLC

Nine nucleosides and nucleobases, including uracil, adenine, thymine, uridine, adenosine, thymidine, cytidine, guanosine, and cordycepin in natural Cordyceps sinensis, cultured Cordyceps mycelia, and Cordyceps fruiting bodies were extracted by matrix solid‐phase dispersion (MSPD) and determined by HPLC. The experimental conditions for the MSPD extraction were optimized. Florisil was used as dispersant, petroleum ether as washing solvent, and methanol as elution solvent. The Florisil‐to‐sample ratio was selected to be 4:1 and no additional clean‐up sorbent was needed. The calibration curves had good linear relationships (r > 0.9997). The LOD and LOQ were in the range of 12 ～ 79 and 41 ～ 265 ng/mL, respectively. The intra‐ and interday precision were lower than 8.3%. The recoveries were between 61.5 and 93.2%. The present method consumed less sample compared with ultrasonic extraction and heating reflux extraction (HRE). The extraction yields obtained by using the present method are much higher than those obtained by UE and comparable to those obtained by HRE.     

Optimization of CEC for simultaneous determination of eleven nucleosides and nucleobases in Cordyceps using central composite design

A CEC method is described for the simultaneous determination of 11 nucleosides and nucleobases including cytosine, uracil, uridine, hypoxanthine, 2'-deoxyuridine, inosine, guanosine, thymidine, adenine, adenosine, and cordycepin in Cordyceps using 5-chlorocytosine arabinoside as internal standard (IS). Chemometric optimization based on central composite design was employed to find the optimum conditions. The factors for optimization were defined as three parameters: voltage, pH, and concentration of ACN as organic modifier. The resolution (R(s)) between inosine and guanosine, as well as the entire run time were employed to evaluate the response function. A running buffer composed of 4 mM ammonium acetate and 2 mM triethylamine (TEA) adjusted to pH 5.3 using acetic acid, and containing 3% ACN as modifier, with gradient voltage (0-4 min: 20 kV, 4-12 min: linear gradient from 20 to 30 kV; 12-16 min: 30 kV) were found to be the optimum conditions for the separation. Separation of the 11 investigated compounds and 5-chlorocytosine arabinoside was achieved within 16 min. The contents of the 11 compounds in natural and cultured Cordyceps sinensis, and cultured Cordyceps militaris were also compared. The result showed that CEC is an efficient method for analysis of nucleosides and nucleobases in Cordyceps, which is helpful to control the quality of this valued traditional Chinese medicine.     

Determination of nucleotides,nucleosides and their transformation products in Cordyceps by ion-pairing reversed-phase liquid chromatography–mass spectrometry

An ion-pairing reversed-phase liquid chromatography–mass spectrometry (IP-RP-LC–MS) was developed for the determination of nucleotides, nucleosides and their transformation products in Cordyceps. Perfluorinated carboxylic acid, namely pentadecafluorooctanoic acid (PDFOA, 0.25 mM), was used as volatile ion-paring agent and a reversed-phase column (Agilent ZORBAX SB-Aq column) was used for the separation of three nucleotides namely uridine-5′-monophosphate (UMP, 0.638–10.200 μg/mL), adenosine-5′-monophosphate (AMP, 0.24–7.80 μg/mL) and guanosine-5′-monophosphate (GMP, 0.42–13.50 μg/mL), seven nucleosides including adenosine (0.55–8.85 μg/mL), guanosine (0.42–6.75 μg/mL), uridine (0.33–10.50 μg/mL), inosine (0.21–6.60 μg/mL), cytidine (0.48–15.30 μg/mL), thymidine (0.20–6.30 μg/mL) and cordycepin (0.09–1.50 μg/mL), as well as six nucleobases, adenine (0.22–6.90 μg/mL), guanine (0.26–4.20 μg/mL), uracil (0.38–12.15 μg/mL), hypoxanthine (0.13–4.20 μg/mL), cytosine (0.39–12.45 μg/mL) and thymine (0.26–8.25 μg/mL) with 5-chlorocytosine arabinoside as the internal standard. The overall LODs and LOQs were between 0.01–0.16 μg/mL and 0.04–0.41 μg/mL for the 16 analytes, respectively. The contents of 16 investigated compounds in natural and cultured Cordyceps were also determined and compared after validation of the developed IP-RP-LC-MS method. The transformations of nucleotides and nucleosides in Cordyceps were evaluated based on the quantification of the investigated compounds in three extracts, including boiling water extraction (BWE), 24 h ambient temperature water immersion (ATWE) and 56 h ATWE extracts. Two transformation pathways including UMP → uridine → uracil and GMP → guanosine → guanine were proposed in both natural Cordyceps sinensis and cultured Cordyceps militaris. The pathway of AMP → adenosine → inosine → hypoxanthine was proposed in natural C. sinensis, while AMP → adenosine → adenine in cultured C. militaris. However, the transformation of nucleotides and nucleosides was not found in commercial cultured C. sinensis.     

Chemical fingerprint analysis of Fritillaria delavayi Franch. by high-performance liquid chromatography

Bulbus of Fritillaria delavayi Franch. is the most commonly used antitussive and apophlegmatic in China and commonly prepared by water decoction. In this study, a novel and reliable method of high-performance liquid chromatography (HPLC) was developed both for quantitative analysis of 10 bioactive compounds (uracil, cytidine, inosine, uridine, guanosine, thymidine, adenosine, hypoxanthine, adenine and 2-deoxyadenosine) and chemical fingerprint analysis of F. delavayi Franch. In quantitative analysis, 10 compounds showed good regressions (R(2) > 0.9982) within test ranges and the recovery of the method was in the range of 96.33-104.51%. In the fingerprint analysis, 11 characteristic peaks were selected to evaluate the similarities of F. delavayi Franch. samples, and the HPLC chromatograms of 16 samples from different regions of China showed similar patterns. The results from the experiment demonstrated that the combinations of the quantitative and chromatographic fingerprint analysis offer an efficient way to evaluate the quality consistency of F. delavayi Franch.     

胶束扫集毛细管电泳分离测定绿原酸和咖啡酸

采用胶束扫集毛细管电泳分离测定双黄连口服液中的绿原酸和咖啡酸.试验条件为:重力进样时间40 s;以20 mmol/L NaH_2PO_4,100 mmol/L 十二烷基磺酸钠(SDS)为电泳缓冲液(含体积分数15%甲醇,pH 2.20),分离电压-20 kV,检测波长214 nm,讨论了pH、SDS浓度、样品溶剂等对分离效果的影响.在优化条件下,绿原酸和咖啡酸的检出限分别达到1.02和0.168 μg/mL,线性范围分别为5.86～51.5 μg/mL和1.27～14.5 μg/mL.     

Determination of the nucleosides and nucleobases in Tuber samples by dispersive solid-phase extraction combined with liquid chromatography-mass spectrometry

A simple, fast and inexpensive method based on dispersive solid phase extraction (DSPE) combined with LC–MS was developed for simultaneous determination of 7 nucleosides and nucleobases (i.e., adenine, hypoxanthine, uridine, adenosine, guanine, guanosine, and inosine) in Tuber fruiting-bodies and fermentation mycelia. The DSPE procedure was firstly introduced to remove the protein interference from sample solutions, and D3520 macroporous resin was chosen as the DSPE sorbent because of its high removal capability on protein interferences, but low adsorption rate on analytes. Besides, key parameters on DSPE procedure (i.e., macroporous resin type, macroporous resin amount, methanol concentration, and vortex time) were optimized, and the protein removal efficacy could achieve about 95% after the process optimization. Though the method validation test, the DSPE-LC–MS method was confirmed to be precise, accurate and sensitive, and the column blinding problem was solved successfully. By using this established method, the total amount of nucleosides and nucleobases in the fermentation mycelia was determined to range from 4881.5 to 12,592.9 μg g⁻¹, which was about 2–25 times higher than the fruiting-bodies (from 498.1 to 2274.1 μg g⁻¹). The formulation of nucleosides and nucleobases in the fermentation mycelia maintained relatively constant, while the formulation in Tuber fruiting-bodies varied significantly with their species. Hierarchical cluster analysis (HCA) showed the formulation similarity of nucleosides and nucleobases between Tuber fermentation mycelia and the fruiting-bodies of Tuber indicum and Tuber himalayense. From the viewpoint of nucleosides and nucleobases, this work confirms the potentiality of Tuber fermentation mycelia as the alternative resource for its fruiting-bodies.     

Determination of nucleosides in natural Cordyceps sinensis and cultured Cordyceps mycelia by capillary electrophoresis

Cordyceps sinensis is a well-known traditional Chinese medicine, and some of the active components are nucleosides. The analysis of nucleosides in Cordyceps material has been performed by reversed-phase high-performance liquid chromatography (HPLC) with gradient elution or by spectrometry. Here, we have explored the possibility of using capillary electrophoresis to determine the content of three major nucleosides (adenosine, guanosine and uridine) in Cordyceps. Capillary electrophoresis needs no gradients, and it provides a better separation due to its higher efficiency. In order to optimize the resolution, the separation of adenosine, guanosine and uridine was determined in Cordyceps with respect to the variation of buffer concentration, pH, temperature, and voltage. By using the calibrated electrophoresis system, the separation was achieved for the three nucleosides in less than 10 min with a background electrolyte consisting of 0.2 M boric acid-sodium hydroxide buffer, pH 8.5. The nucleoside contents of various types of natural Cordyceps and cultured Cordyceps mycelia were determined and compared. There was a great variation of nucleoside content in different sources of Cordyceps; the cultured Cordyceps mycelia, however, contains a much higher concentration than the natural Cordyceps.     

Simultaneous determination of six main nucleosides and bases in natural and cultured Cordyceps by capillary electrophoresis

A simple method is described for simultaneous determination of six main nucleosides and bases including adenine, uracil, adenosine, guanosine, uridine and inosine in Cordyceps by capillary electrophoresis (CE). Chemometric optimization based on central composite design was employed to find the optimum resolution. The optimum factor space was defined by three parameters: buffer concentration, pH and concentration of acetonitrile as organic modifier. Resolution (Rs) was employed to evaluate the response function. A running buffer composed of 500 mM boric acid, adjusted pH to 8.6 with sodium hydroxide and 12.2% acetonitrile as modifier was found to be the most appropriate for the separation. The contents of the six components were determined by using adenosine monophosphate as an internal standard. Furthermore, hierarchical clustering analysis based on characteristics of 32 peaks in CE profiles from the tested 12 samples showed that natural and cultured Cordyceps were in different clusters. Adenosine and inosine were extracted as markers for discrimination of natural Cordyceps. The result of clustering based on the two peaks characteristics was in excellent agreement with that based on 32 peaks'. Thus, adenosine and inosine could be used as markers for quality control of natural and cultured Cordyceps.