栀子苷在乙腈水体系中诱导相分离分配行为

研究了栀子乙腈水提取液中的栀子苷在诱导相分离后在两相中的分配行为,建立了乙腈/水分相体系分离纯化栀子苷的新方法。重点考察了能使乙腈/水体系分相的诱导剂的种类,分析了诱导剂的组成比例以及用量、乙腈的体积分数、样品加入量和温度对栀子苷分配行为的影响。当温度为25℃时,栀子的乙腈/水(体积比1∶1)提取液中加入KCl与MgSO4组成的混盐(质量比2∶1)分相诱导剂后,栀子苷的萃取率达到81.63%,含量由分相前的3.05%提高至13.54%。     

高效液相色谱法测定新雪颗粒中栀子苷的含量

建立了新雪颗粒中栀子苷含量的高效液相色谱测定方法。色谱柱为Diamonsil C18(200 mm×4.6 mm i.d., 5 μm), 流动相为乙腈-水(体积比为15∶85),流速1.0 mL/min,检测波长238 nm,进样量20 μL。栀子苷在25~400 mg/L时其浓度与峰面积呈良好的线性关系,方法平均回收率为101.2%,相对标准偏差(RSD)为1.6％。     

低速逆流色谱分离制备栀子黄色素中的藏花素

建立了低速逆流色谱技术(SRCCC)从栀子黄色素中快速分离制备藏花素的方法。两相溶剂系统由叔丁基甲基醚-正丁醇-乙腈-水(2:2.5:1:5, v/v/v/v)组成,以上相为固定相,下相为流动相。在转速为50 r/min和流速为5 mL/min的条件下,从5 g栀子黄色素粗样中分离得到2.47 g藏花素,纯度为96.8%。该方法制备量大、安全、高效,有可能成为工业级分离制备藏花素的一种有效手段。     

加压毛细管电色谱在芎菊上清片中栀子苷及黄芩苷分离检测中的应用

采用加压毛细管反相电色谱技术,建立了一种用于分离检测芎菊上清片中栀子苷和黄芩苷的高效简便新方法。色谱柱为EP-100-20/45-3 C18毛细管柱(总长度45 cm,有效长度20 cm,直径为100μm,ODS填料内径3μm),柱温为25℃,流动相采用20 mmol/L Na H2PO4-乙腈(71∶29),流动相的总流速为0.035m L/min,分离电压为+2.0 k V,检测波长为240 nm。经等度洗脱,栀子苷和黄芩苷可实现快速分离,峰面积的相对标准偏差(RSD)不大于2.8%,回收率为91.9%~101.2%,测得该芎菊上清片中栀子苷的含量为2.616 mg/g,黄芩苷的含量为11.220 mg/g。该方法的选择性好、柱效高、试剂用量少,用于芎菊上清片中黄芩苷和栀子苷的分离检测,结果满意。     

Bond Elut PBA固相萃取柱净化-高效液相色谱-串联质谱法同时测定鸡肉中金刚烷胺和利巴韦林的残留量

取鸡肉样品约2.0 g,加入100μg·L^-1金刚烷胺-d₆和利巴韦林-¹³C₅的混合内标溶液100μL和体积比为7∶3的20 g·L^-1三氯乙酸溶液-乙腈的混合溶液15 mL,涡旋30 s,振荡15 min,离心5 min,上层有机相转移至50 mL离心管中。重复上述操作一次,合并上层有机相,过普通滤纸,滤液用约100μL氨水调节酸度至pH 8.5,过活化好的Bond Elut PBA固相萃取柱。固相萃取柱先以体积比1∶9的乙腈-0.25 mol·L^-1乙酸铵混合溶液3 mL和含5%(体积分数)氨水的甲醇溶液3 mL淋洗,然后以含2%(体积分数)甲酸的甲醇溶液4 mL洗脱。收集洗脱液,氮吹至干,残渣用体积比1∶9乙腈-水混合溶液1 mL复溶后,过0.22μm滤膜。滤液进入高效液相色谱-串联质谱仪,在Eclipse XDB-C₈色谱柱上用不同体积比的含5 mmol·L^-1乙酸铵的1%(体积分数)甲酸溶液-甲醇-水...     

高效液相色谱-质谱法同时测定清热解毒口服液中的5种有效成分

建立了同时测定清热解毒口服液中的绿原酸、栀子苷、黄芩苷、连翘苷和靛玉红5种有效成分的高效液相色谱-电喷雾电离质谱（HPLC-ESI/MS）分析方法。采用Zorbax SB C18色谱柱,以含0.2%甲酸的0.4 mmol/L醋酸钠(A相)、乙腈(B相)为流动相进行梯度洗脱,在ESI正离子模式下,采用选择离子监测方法进行测定,用峰面积进行定量。结果表明,绿原酸、栀子苷、黄芩苷、连翘苷和靛玉红的线性范围分别为0.050～50 mg/L,0.020～20 mg/L,0.005～30 mg/L,0.010～15 mg/L和0.010～10 mg/L;检出限分别为0.010,0.005,0.001,0.002和0.003 mg/L。5种成分的加样回收率为97.0%～101.7%,相对标准偏差小于2.2%。该法快捷、准确、重复性好,可用于清热解毒口服液中的5种有效成分含量的同时测定。     

高效液相色谱法测定柑橘汁中的柠檬苦素和柚皮苷

柑橘汁的苦味主要是由于柚皮苷和柠檬苦素的存在所致,其含量的测定可用于控制柑橘类果汁的质量。采用高效液相色谱法在KR100-5C18(4.6 mm i.d.×250 mm,5 μm)上,分别以乙腈-四氢呋喃-水(体积比为17.5∶17.5∶65)和甲醇-冰醋酸-水(体积比为40∶1∶59)为流动相（流速均为1 mL/min）,在207 nm和283 nm检测波长下分别测定了柠檬苦素和柚皮苷。实验结果表明,柠檬苦素在1.00～50.00 mg/L时线性关系良好(r=0.9992),检出限为0.07 μg,平均加标回收率为98.69%,相对标准偏差（RSD）为2.5%;柚皮苷在20.00～160.00 mg/L时线性关系良好(r=0.9988),检出限为0.14 μg,平均加标回收率为100.13%,RSD为1.5%。用该法检测柑橘汁样品中的柠檬苦素与柚皮苷,方法简便、快速、准确。     

超高效液相色谱-串联质谱法测定植物源性食品中丁氟螨酯及其代谢物的残留量

建立了超高效液相色谱-串联质谱法（UHPLC-MS/MS）测定水果、蔬菜、茶叶等植物源性食品中丁氟螨酯及其代谢物邻三氟甲基苯甲酸含量的方法。在样品4 g（茶叶1 g）中加入90%（体积分数）乙腈溶液10 mL、1 mol·L^-1盐酸溶液1.0 mL、无水硫酸钠3 g和氯化钠2 g,振荡提取2 min后,离心,取上层乙腈相注入石墨化碳黑固相萃取小柱中净化,再用6 mL体积比为2∶3的丙酮-甲醇的混合液洗脱,收集流出液和洗脱液,于40℃氮吹至近干,加入2 mL 40%（体积分数）乙腈溶液,过滤,取滤液进行UHPLC-MS/MS测定。以Waters ACQUITY UPLC BEH C₁₈柱为固定相,以不同体积比的乙腈-含0.2%（体积分数）甲酸的5 mmol·L^-1乙酸铵溶液的混合液为流动相对其进行梯度洗脱。质谱分析采用电喷雾正、负离子源（ESI⁺、ESI^-）和多反应监测（MRM）模式,以基质匹配的混合标准溶液系列绘制工作曲线。结果显示：在大豆、茄子、甘蓝、西红柿、苹果、绿茶中,丁...     

高效液相色谱-三重四极杆复合线性离子阱质谱法检测水产品中氟喹诺酮类抗生素和镇静剂

为实现水产品中抗生素和镇静剂的同时、快速检测,进行了题示研究。分取2.0 g匀浆后的样品的肌肉组织,加入体积比79∶1∶20的乙腈-乙酸-水混合溶液10 mL,振荡1 min,超声10 min。加入2.0 g氯化钠,振荡1 min,于-20℃保存30 min,用于去除提取液中的脂肪。离心10 min,分取1 mL上清液注入装载有150 mg C₁₈的CAFS clean-up净化柱中,多次推动活塞,将提取液全部转移到2 mL离心管中。分取0.5 mL净化液,加入0.5 mL 0.1%(体积分数,下同)甲酸溶液,混匀后过0.22μm尼龙滤膜。滤液注入高效液相色谱-三重四极杆复合线性离子阱质谱仪,9种目标物在BEH C₁₈色谱柱上用不同体积比的0.1%甲酸溶液和含0.1%甲酸的甲醇溶液的混合溶液进行梯度洗脱分离后,用电喷雾离子源正离子(ESI⁺)模式电离,多反应监测(MRM)模式检测,基质匹配法定量。结果显示,9种目标物的质量分数分别在1.0～50.0μg·kg^-1(丁卡因、布比卡因、恩诺沙星和氧氟沙星...     

固相萃取/超高效液相色谱法测定龙胆泻肝丸中栀子苷、龙胆苦苷与黄芩苷

建立了一种快速测定龙胆泻肝丸中栀子苷、龙胆苦苷和黄芩苷3种有效成分的超高效液相色谱方法。样品经50%甲醇提取,C18固相萃取(SPE)小柱净化后,采用Ultimate XB-C18色谱柱(4.6 mm×50 mm,1.8μm)进行分离,以乙腈-0.1%磷酸溶液为流动相进行梯度洗脱。考察了不同规格色谱柱、流动相梯度比例、进样体积、柱温和流速对分离效果的影响,并对SPE柱流出液的平衡体积进一步考察,在最佳分析条件下进行液相色谱分析,该方法显示了良好的线性关系(r≥0.999 8),其定量下限(LOQ)为0.24～0.44 mg/L,加标回收率为95%～99%。该方法快速、准确,可满足实际检测需要。     

Extraction and Purification of Ipomoea Peroxidase Employing Three-phase Partitioning

Three-phase partitioning (TPP) is a novel separation process used for the extraction and purification of biomolecules. The biomolecules are recovered in a purified form at the interface (precipitate), while the contaminants partition in t-butanol and aqueous phases. Peroxidase from the leaves of Ipomoea palmata was purified by using TPP. The ratio of the crude extract to t-butanol of 1:1 and 30% ammonium sulfate at 37 degrees C resulted in about 160% activity recovery and twofold purification in the aqueous phase of the first cycle of TPP. On subjecting the aqueous phase to the second cycle of TPP, a purification of 18-fold was achieved with about 81% activity recovery. The sodium dodecyl sulfate polyacrylamide gel electrophoresis analysis showed substantial purification, and the molecular weight of peroxidase was found to be 20.1 KDa. The present study shows a higher degree of purification and activity yield as a primary purification process in comparison with existing literature values, thus demonstrating TPP as an attractive downstream process for the purification of peroxidase.     

A simple and low-energy strategy for the separation of water and acetonitrile

As acetonitrile is a widely used solvent for the chemical industry, the recovery of acetonitrile from acetonitrile wastewater is significant for both industrial cost reduction and environmental protection. In this article, a simple, low-energy, and low-cost strategy is proposed for the effective separation of acetonitrile from high-concentration acetonitrile wastewater. The approach is based on a sequential combination of two steps: salt-induced phase separation and hydrophobic filtration. The acetonitrile wastewater was first induced to split into two phases by salt, that is, the acetonitrile-rich phase and the water-rich phase, then the above two phases were poured into the hydrophobic filter paper funnel for the separation. It was shown that NaCl is a suitable salting-out reagent, and that hydrophobic filter papers—obtained from modification by butyltrichlorosilane and octyltrichlorosilane were the optimal choice for hydrophobic filtration. The salt-induced phase separation process is able to increase the volume fraction of acetonitrile in the acetonitrile-rich phase up to 92%. The acetonitrile-rich phase can pass through the hydrophobic filter paper, whereas the water-rich phase was intercepted. The hydrophobic filter paper retained strong hydrophobicity and high acetonitrile-separating capacity after 3 months storage, or upon immersion in acetonitrile-water mixtures for 12 h, or applied for 25 consecutive separations.     

Determinations of geniposide using LC/MS/MS methods via forming ammonium and acetate adducts

In this paper, we report method development work to determine geniposide using LC/MS/MS via the formation of positive and negative ion adducts. Geniposide, which has been recognized to have choleretic effects, is the major iridoid glycoside component of Gardenia herbs. To enhance the sensitivity of LC/MS detection of geniposide, a small amount of volatile additives such as ammonium acetate and acetic acid are added into mobile phase solvents to form positive and negative adducts, which can then ionize via electrospray processes. The formation of positive adducts is due to the complexation between geniposide and ammonium ions ([M + NH₄]⁺). The formation of anionic adducts [M + CH₃COO]⁻ is believed to occur via hydrogen bonds bridging acetate ions and glucose groups on the geniposide molecule. Mobile phase solvents containing acetonitrile and aqueous solution (0.2 mM ammonium acetate or 0.1% acetic acid) at the ratio 15: 85 are employed to elute geniposide using C8 reverse phase liquid chromatography columns with electrospray tandem mass spectrometry determinations. Using geniposide standards, the methods are validated at the concentration ranges of 5 to 1000 ng/mL and 20 to 5000 ng/mL using ammonium and acetate adducts respectively. The correlation coefficients of the standard curves are 0.9999 using both ammonium and acetate adducts. The detection limits of using ammonium and acetate adducts are 1 and 5 ng/mL respectively. The measurement accuracy and precision of using ammonium adducts are within 12% and 3% respectively, whereas the accuracy and precision are within 6 and 11% respectively using acetate adducts. When the validated calibration curves of the ammonium adduct of geniposide are used to determine spiked control samples in rat blood dialysates, the determination errors of accuracy and precision are within 12% and 10% respectively.     

Separation/Extraction/Detection of Chloramphenicol Using Binary Small Molecule Alcohol-Salt Aqueous Two-phase System Coupled with High-performance Liquid Chromatography

A green and sensitive sample separation and purification method coupled with high-perfomiance liquid chromatography(HPLC)was developed for the analysis of chioramphenicol(CAP).One element small molecule alcohol-salt aqueous two-phase system(ATPS)can't effectively adjust the polarity of the system,but binary small molecule alcohol-salt ATPS can adjust the polarity and improve the extraction efficiency of antibiotics.A binary aqueous two-phase system based on 1-propanol+2-propanol and NaH2PO4 system was formed and applied to the separation and purification of trace CAP in real samples.The influence factors on partition behaviors of CAP were discussed,including the types and mass of salts,the volume ratio of alcohol,the pH,temperature and the standing time.The optimal condition was found at pH=5.0,2.5 g of NaH2PO4,3.0 mL of 1-propanol and 2-propanol(volume ratio 1:1)and 30℃by using response surface methodology.Under this optimal condition,the extraction efficiency of CAP reached 98.91%,and partition coefficient of CAP was 17.31.     

Effect of inorganic salt on partition of high‐polarity parishins in two‐phase solvent systems and separation by high‐speed counter‐current chromatography from Gastrodia elata Blume

Parishins are high‐polarity and major bioactive constituents in Gastrodia elata Blume. In this study, the effect of several inorganic salts on the partition of parishins in two‐phase solvent systems was investigated. Adding ammonium sulfate, which has a higher solubility in water, was found to significantly promote the partition of parishins in the upper organic polar solvents. Based on the results, a two‐phase solvent system composed of butyl alcohol/acetonitrile/near‐saturated ammonium sulfate solution/water (1.5:0.5:1.2:1, v/v/v/v) was used for the purification of parishins by high‐speed counter‐current chromatography. Fractions obtained from high‐speed counter‐current chromatography were subjected to semi‐preparative high‐performance liquid chromatography to remove salt and impurities. As a result, parishin E (6.0 mg), parishin B (7.8 mg), parishin C (3.2 mg), gastrodin (15.3 mg), and parishin A (7.3 mg) were isolated from water extract of Gastrodia elata Blume (400 mg). These results demonstrated that adding inorganic salt that has high solubility in water to the two‐phase solvent system in high‐speed counter‐current chromatography was a suitable approach for the purification of high‐polarity compounds.     

Purification of salvianolic acid B from the crude extract of Salvia miltiorrhiza with hydrophilic organic/salt-containing aqueous two-phase system by counter-current chromatography

Establishment of hydrophilic organic/salt-containing aqueous two-phase system and purification of salvianolic acid B from crude extract of S. miltiorrhiza by counter-current chromatography with said system were studied. Ethanol and n-propanol were selected to constitute biphasic systems with ammonia sulphate, sodium chloride and phosphate separately, and related system characteristics including phase diagrams, phase ratio, separation time were tested. The partition coefficient of crude salvianolic acid B was also tested in above systems and further finely adjusted by altering the constitution of phosphate in n-propanol/phosphate system. Salvianolic acid B was purified to 95.5% purity by counter-current chromatography in 36% (w/w) n-propanol/8% (w/w) phosphate system with the ratio between dipotassium hydrogen phosphate and sodium dihydrogen phosphate of 94:6. One hundred and eight milligrams of salvianolic acid B was purified from 285 mg crude extract with the recovery of 89%.     

溶剂诱导相变萃取法用于高效液相色谱-质谱分析的血浆样品前处理

在匀相的乙腈-水体系中添加一种疏水但与乙腈互溶的有机溶剂(如氯仿), 能诱导乙腈-水体系分相, 基于此现象建立了一种血浆样品处理方法溶剂诱导相变萃取(SIPTE). 与传统的液-液萃取法相比, 该法最大的优势为新形成的有机相为乙腈(仅含少量氯仿), 与常用的反相C₁₈柱兼容, 能直接进行高效液相色谱-质谱分析. 此外, 通过减少乙腈及氯仿的用量还可实现样品的自动浓缩. 本文通过测定血浆中尼群地平, 验证了该方法的有效性. 使用反相C₁₈柱, 以V(乙腈)∶V(水)=70∶30(含20 mmol/L甲酸铵)为流动相, 尼莫地平为内标, ESI正离子模式下选择离子监测(SIM)测定了血浆中尼群地平的浓度. 实验所得的线性、精密度和准确度结果良好, 表明所建立的方法灵敏、准确、简单、快速, 可用于药物代谢动力学研究.     

超声提取正相高效液相色谱法测定大豆及大豆油中的磷酸甘油酯

建立了超声提取-固相萃取纯化/正相高效液相色谱测定大豆及大豆油中磷脂酰胆碱(PC)、磷脂酰乙醇胺(PE)、磷脂酰肌醇(PI)的方法。考察了提取溶剂、超声功率、超声时间、提取温度及净化方式的影响,并研究了不同色谱固定相对磷酸甘油酯分离效果的影响。优化的实验条件为:以氯仿-甲醇(2∶1,体积比)为提取溶剂,1 500 W功率超声提取30 min;氨基固相萃取柱为纯化小柱;正己烷-异丙醇-1%HAc(8∶8∶1,体积比)为流动相。在该条件下,PC、PE、PI的线性范围分别为0.08～8.00、0.15～15.00、0.30～20.00 g.L-1,定量下限分别为0.021、0.050、0.060 g.L-1,检出限在8～23 mg.L-1之间,其在大豆和大豆油中的回收率为85%～108%。日内与日间精密度分别不大于4.7%和8.6%。     

双水相萃取结合液相色谱法分离蛋白质

建立了PEG/( NH4)2SO4双水相体系萃取富集,结合液相色谱分离分析多种蛋白质的方法.考察了无机盐种类和浓度、PEG分子量、pH值和温度等因素对双水相形成以及对细胞色素C、肌红蛋白、牛血清白蛋白、溶菌酶、胰蛋白酶分配行为的影响.结果表明,上述5种蛋白在室温、pH 3.5～9.0范围内,可在15％ PEG-4000/10％ (NH4)2SO4双水相体系中得到富集,且主要集中在下相.同样条件下,血清中的高丰度蛋白在上下相均有分配,下相分配量较大.通过双水相萃取分离蛋白质及对液相色谱一定时间段的色谱峰收集,可初步实现血清中高丰度蛋白质的分离去除.     

Enhanced fluidity liquid chromatography for hydrophilic interaction separation of nucleosides

The application of enhanced fluidity liquid (EFL) mobile phases to improving isocratic chromatographic separation of nucleosides in hydrophilic interaction liquid chromatography (HILIC) mode is described. The EFL mobile phase was created by adding carbon dioxide to a methanol/buffer solution. Previous work has shown that EFL mobile phases typically increase the efficiency and the speed of the separation. Herein, an increase in resolution with the addition of carbon dioxide is also observed. This increase in resolution was achieved through increased selectivity and retention with minimal change in separation efficiency. The addition of CO₂ to the mobile phase effectively decreases its polarity, thereby promoting retention in HILIC. Conventional organic solvents of similar nonpolar nature cannot be used to achieve similar results because they are not miscible with methanol and water. The separation of nucleosides with methanol/aqueous buffer/CO₂ mobile phases was also compared to that using acetonitrile/buffer mobile phases. A marked decrease in the necessary separation time was noted for methanol/aqueous buffer/CO₂ mobile phases compared to acetonitrile/buffer mobile phases. There was also an unusual reversal in the elution order of uridine and adenosine when CO₂ was included in the mobile phase.