在线固相萃取法结合电雾式检测器测定黄芪及其复方中黄芪甲苷的含量

采用在线固相萃取高效液相色谱法,结合电雾式检测器,建立了快速测定黄芪及其复方中黄芪甲苷的方法。采用Acclaim Polar AdvantageⅡC18(50 mm×4.6 mm,3μm)为在线净化柱,以双三元液相色谱的右泵作为上样净化泵,甲醇-水为流动相,梯度洗脱,进行富集和净化;采用Acclaim C18(150 mm×4.6 mm,5μm)为分析柱,以双三元液相色谱的左泵作为分析泵,乙腈-水作为流动相,等度洗脱,流速为1.0 mL/min,采用中心切割的方式将目标物从在线净化柱转移至分析柱中。电雾式检测器( CAD)的雾化器温度为30℃;氮气压力为241.3 kPa。黄芪甲苷在药材及复方基质中获得较好分离,黄芪甲苷在4.0~80 mg/L范围内,相关系数r=0.9998,平均回收率为97.6％。实验表明,本方法快速、简便,专属性、重现性较好,测定结果可靠,可应用于黄芪及其复方中黄芪甲苷含量的检测。     

高效液相色谱–波长切换法同时测定独一味软胶囊中6种成分

建立高效液相色谱–波长切换法同时测定独一味软胶囊中山栀苷甲酯、绿原酸、8-O-乙酰山栀苷甲酯、连翘酯苷B、毛蕊花糖苷和木犀草苷的方法。以Symmetry Shield RP18柱(250 mm×4.6 mm,5 μm)为色谱柱,乙腈–0.3%磷酸水为流动相,检测波长分别为235 nm(山栀苷甲酯、8-O-乙酰山栀苷甲酯)、330 nm(绿原酸、连翘酯苷B、毛蕊花糖苷)、360 nm(木犀草苷),流量为1 mL/min。山栀苷甲酯、绿原酸、8-O-乙酰山栀苷甲酯、连翘酯苷B、毛蕊花糖苷和木犀草苷的进样量在各自的范围内与色谱峰面积线性关系良好,相关系数不小于0.999 0,测定结果的相对标准偏差为0.21%～0.69%(n=6),平均加标回收率为94.0%～101.1%。该方法简单、准确、重现性好,适用于独一味软胶囊的质量评价。     

金银花不同部位中绿原酸和木犀草苷含量的测定

利用HPLC法测定金银花不同部位中绿原酸和木犀草苷。采用ODS-C18色谱柱(250 mm×4.6 mm,5μm),以甲醇-水(0.03 mol/L磷酸)为流动相进行梯度洗脱,流速:1.0 mL/min,检测波长:350 nm,柱温:室温。绿原酸浓度在0~0.4 mg/mL内与峰面积呈良好线性关系(r2=0.999 6),回收率为101.9%~105.2%,相对标准偏差为3.18%(n=6)。木犀草苷浓度在0~0.1 mg/mL内与峰面积呈良好线性关系(r2=0.999 1),平均回收率为100.5%~104.0%,相对标准偏差为3.42%(n=6)。结果表明:金银花、芽等部位绿原酸和木犀草苷的含量较高。     

HPLC柱切换技术用于同时分析鱼腥草中3种黄酮类成分

利用柱切换技术解决了鱼腥草中难分离组分的分离和低含量组分的定量问题。以Synergi Fusion-RP柱(250 mm×4.6 mm i.d.,4μm)作为预柱,甲醇-0.05%磷酸溶液作流动相,以Acclaim120 C18柱(250mm×4.6 mm i.d.,5μm)作为分析柱,乙腈-0.05%磷酸溶液作流动相,对鱼腥草中的3种黄酮类成分进行分析。该方法在10.0～1 000.0 mg.L-1范围内线性关系良好,相关系数(r)不低于0.998,回收率为95%～99%,RSD值均小于3%。该方法操作简便、快速,可作为分析鱼腥草中黄酮类组分的有效手段。     

二维液相色谱法在线检测哈茨木霉发酵液中2460A含量

建立了在线检测哈茨木霉发酵液中微量2460A的二维液相色谱方法。利用Ultimate 3000双三元液相色谱仪,采用阀切换二维色谱技术,组合3根色谱柱实现2460A的在线净化、富集和含量检测。净化柱采用资生堂MF C8柱(10 mm×4.6 mm,5.0μm),富集柱采用资生堂MGC18柱(20 mm×4.6 mm,5.0μm),以水-甲醇为流动相,梯度洗脱,流速2.0 m L/min;二维分析柱采用Thermo Hypersil GOLD C18柱(250 mm×4.6 mm,5.0μm),以水-甲醇为流动相,梯度洗脱,流速1.0 m L/min;进样量1.0 m L;柱温40℃;检测波长424 nm。方法验证结果显示,2460A的线性范围为0.0025~10.0 mg/L(r=0.9981,n=8),检出限为1.2μg/L;定量限为2.5μg/L;方法回收率为88.0%~104.4%。     

全自动在线固相萃取-二维高效液相色谱与质谱联用测定辣椒油中苏丹红

建立了全自动在线固相萃取-二维高效液相色谱与质谱联用快速测定辣椒油中的苏丹红Ⅰ,Ⅱ,Ⅲ,Ⅳ的方法。样品经乙腈和二氯甲烷萃取后,在一维色谱柱(Acclaim PAⅡ,150 mm×3.0 mm×3μm)上分离出苏丹红,通过阀的分段切换,依次富集在SPE柱(Acclaim 120 C18,10 mm×4.6 mm×5μm)上,在线完成净化和萃取富集;再通过阀切换将它们转移至二维色谱流路,在Acclaim 120 C18色谱柱(100 mm×2.1 mm×2.2μm)上分离检测。一维色谱以水-乙腈-甲醇/四氢呋喃(1∶1,V/V)为流动相,进样体积20μL,0.6 mL/min流速梯度洗脱和紫外-可见检测器(λ=254 nm)监测分离状况;二维色谱以水-乙腈-甲酸/乙腈(1∶1000,V/V)为流动相,0.3 mL/min流速梯度洗脱,采用单四极质谱仪,选择离子方式检测。整个分析流程27 min即可完成。4种苏丹红的保留时间的相对标准偏差均小于0.1%,色谱峰面积的相对标准偏差均小于2%(n=7);在0.6～60μg/L范围内峰面积与进样质量浓度的线性相关系数均大于0.9958;加标回收率为50%～97%;方法检出限均小于0.2μg/L(S/N=3)。测定结果令人满意。     

高效液相色谱法测定贯叶连翘中的4种成分

本文利用高效液相色谱法同时测定中药贯叶连翘中绿原酸、芦丁、金丝桃苷和槲皮素四种成分的含量。采用Tiahhe Kromasil C18 100 A(5μm,250mm×4.6 mm)反相色谱柱;流动相为V(乙腈)∶V(水)=20∶80(含0.02%三氟乙酸);紫外检测波长270nm;流速1.0 ml/min;柱温40℃。绿原酸、芦丁、金丝桃苷和槲皮素线性范围分别为3.4~34μg.mL-1(r=0.9993),1.8~18μg.mL-1(r=0.9998),2.3~23μg.mL-1(r=0.9999),3.5~35μg.mL-1(r=0.9991),平均回收率(n=5)分别为98.4%(RSD=1.48%),101.8%(RSD=0.74%),103.7%(RSD=0.77%),103.5%(RSD=1.28%)。方法线性范围宽、相对标准偏差低、精密度高、重现性好,应用于贯叶连翘及制剂样品的测定,结果令人满意。     

HPLC法测定地胆草中绿原酸的含量

建立了用高效液相色谱法测定地胆草中绿原酸含量。选择Agilent TC-C18色谱柱(250 mm×4.6 mm,5μm),甲醇-0.1%磷酸溶液(20∶80)为流动相,流速1.0 mL/min,检测波长328 nm,进样量10μL。结果表明,绿原酸0.044 9~4.488 0μg范围内线性关系良好(r=0.999 9),平均加样回收率为99.63%,RSD为0.61%(n=9)。所用方法专属性强、快速准确,可作为地胆草中绿原酸含量的测定方法。     

高效液相色谱-串联质谱法分离鉴定绿原酸及其相关杂质

建立了高效液相色谱-串联质谱法（HPLC-MS/MS)分离和鉴定绿原酸及其相关杂质的方法。采用C18色谱柱(5 μm,4.6 mm×150 mm),乙腈-水（含0.1%甲酸）(体积比为8∶92)为流动相,经HPLC-MS/MS和HPLC-二极管阵列检测器在线检测,对工业绿原酸中的奎尼酸、咖啡酸、绿原酸同分异构体等8个相关杂质的结构进行了鉴定。     

柱切换-高效液相色谱法测定抗病毒口服液中非法添加利巴韦林

提出了由双泵单阀的驱动系统和双柱(预处理柱和分析柱)切换的分析系统所组成的色谱分析流程并应用于测定抗病毒口服液中非法添加物利巴韦林.样品离心后取上清液直接进样于C18预处理柱,水作为预处理流动相;用0.3 g·L-1磷酸二氢钠溶液(分析流动相)将保留在预处理柱上的药物冲入Kromasil C18分析柱(250 mm×4.6 mm,5μm)进行测定.方法集样品净化和色谱分析一次连续进行,测定条件下无干扰.检测波长205.6 am,药物的质量浓度在0.4～40.0 mg·L-1范围内呈线性(r=0.999 2),检出限(S/N=3)为0.08 mg·L-1,加标回收率分别为98.32%,98.45%,99.45%.     

Furyl- and thienyl-silatranes and germatranes

We review our research on the synthesis and study of the physical and biological properties of furyl- and thienylgermatranes and -silatranes.Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 6, pp. 725–732, June, 1992.     

Review and patents and literature

The use of the insect cell/baculovirus expression system for producing recombinant proteins of bacterial, plant, insect, and mammalian origin has become widespread. The popularity of this eukaryotic expression system is due to many factors, including (1) potentially high protein expression levels, (2) ease and speed of genetic engineering, (3) ability to accommodate large DNA inserts, (4) protein processing similar to higher eukaryotic cells (e.g., mammalian cells), and (5) ease of insect cell growth (e.g., suspension growth). The following review of the literature discusses two engineering aspects of recombinant protein synthesis by insect cell cultures: bioreactor scale-up and insect cell line selection. Following this review patent abstracts and additional literature pertaining to expression of recombinant proteins in insect cell culture are listed.     

Ground- and excited-state aromaticity and antiaromaticity in benzene and cyclobutadiene

The aromaticity and antiaromaticity of the ground state (S 0), lowest triplet state (T 1), and first singlet excited state (S 1) of benzene, and the ground states (S 0), lowest triplet states (T 1), and the first and second singlet excited states (S 1 and S 2) of square and rectangular cyclobutadiene are assessed using various magnetic criteria including nucleus-independent chemical shifts (NICS), proton shieldings, and magnetic susceptibilities calculated using complete-active-space self-consistent field (CASSCF) wave functions constructed from gauge-including atomic orbitals (GIAOs). These magnetic criteria strongly suggest that, in contrast to the well-known aromaticity of the S 0 state of benzene, the T 1 and S 1 states of this molecule are antiaromatic. In square cyclobutadiene, which is shown to be considerably more antiaromatic than rectangular cyclobutadiene, the magnetic properties of the T 1 and S 1 states allow these to be classified as aromatic. According to the computed magnetic criteria, the T 1 state of rectangular cyclobutadiene is still aromatic, but the S 1 state is antiaromatic, just as the S 2 state of square cyclobutadiene; the S 2 state of rectangular cyclobutadiene is nonaromatic. The results demonstrate that the well-known "triplet aromaticity" of cyclic conjugated hydrocarbons represents a particular case of a broader concept of excited-state aromaticity and antiaromaticity. It is shown that while electronic excitation may lead to increased nuclear shieldings in certain low-lying electronic states, in general its main effect can be expected to be nuclear deshielding, which can be substantial for heavier nuclei.     

Hard and soft acids and bases: structure and process

Under investigation is the structure and process that gives rise to hard-soft behavior in simple anionic atomic bases. That for simple atomic bases the chemical hardness is expected to be the only extrinsic component of acid-base strength, has been substantiated in the current study. A thermochemically based operational scale of chemical hardness was used to identify the structure within anionic atomic bases that is responsible for chemical hardness. The base's responding electrons have been identified as the structure, and the relaxation that occurs during charge transfer has been identified as the process giving rise to hard-soft behavior. This is in contrast the commonly accepted explanations that attribute hard-soft behavior to varying degrees of electrostatic and covalent contributions to the acid-base interaction. The ability of the atomic ion's responding electrons to cause hard-soft behavior has been assessed by examining the correlation of the estimated relaxation energies of the responding electrons with the operational chemical hardness. It has been demonstrated that the responding electrons are able to give rise to hard-soft behavior in simple anionic bases.     

Determination and study on residue and dissipation of benazolin-ethyl and quizalofop-p-ethyl in rape and soil

A QuEChERS (quick, easy, cheap, effective, rugged, and safe) method for the determination of benazolin-ethyl and quizalofop-p-ethyl in rape and soil by high-performance liquid chromatography-tandem mass spectrometry has been developed in this study. The residue and dissipation of benazolin-ethyl and quizalofop-p-ethyl in rape and soil were determined with the developed method. The half-lives of benazolin-ethyl in rape straw and soil were 3.7–5.1 days and 14.3–26.3 days, respectively. The half-lives of quizalofop-p-ethyl in rape straw and soil were 5.0-6.1 days and 0.3–9.7 days, respectively. The residue of benazolin-ethyl and quizalofop-p-ethyl in rapeseed and soil were below the detection limit (i.e., 0.5?mg?kg^?1, the maximum residue level of European Union for quizalofop-p-ethyl).     

Syntheses and structures of P-anilino-P-chalcogeno- and P-anilino-P-iminodiazasilaphosphetidines and their group 12 and 13 metal compounds

The P-anilino-P-chalcogeno(imino)diazasilaphosphetidines [Me(2)Si(mu-N(t)Bu)(2)P=E(NHPh)] (E = O (3), S (4), Se (5), N-p-tolyl (6)) were synthesized by oxidizing the P-anilinodiazasilaphosphetidine [Me(2)Si(N(t)Bu)(2)P(NHPh)] (2) with cumene hydroperoxide, sulfur, selenium, and p-tolyl azide, respectively. The lithium salt of 4 reacted with thallium monochloride to produce ([Me(2)Si(mu-N(t)Bu)(2)P=S(NPh)-kappaN-kappaS]Tl)(7), which features a two-coordinate thallium atom. Treatment of 4-6 with AlMe(3) gave the monoligand dimethylaluminum complexes ([Me(2)Si(mu-N(t)Bu)(2)P=E(NPh)-kappaN-kappaE]AlMe(2)) (E = S (8), Se (9), N-p-tolyl (10)), respectively. In these complexes the aluminum atom is tetrahedrally coordinated by one chelating ligand and two methyl groups, as a single-crystal X-ray analysis of 8 showed. A 2 equiv amount of 4-6 reacted with diethylzinc to produce the homoleptic diligand complexes ([Me(2)Si(mu-N(t)Bu)(2)P=E(NPh)-kappaN-kappaE](2)Zn)(E = S (11), Se (12), N-p-tolyl (13)). A crystal-structure analysis of 11 revealed a linear tetraspirocycle with a tetrahedrally coordinated, central zinc atom.