丹磺酰氯柱前衍生-超高效液相色谱-串联质谱法测定人体尿样中的环己胺

建立丹磺酰氯柱前衍生-超高效液相色谱-串联质谱法测定人体尿样中环己胺的方法。冷冻样品经解冻、离心后,用丹磺酰氯衍生,固相萃取小柱净化。目标化合物采用 Waters ACQUITY CSHTM C18色谱柱(50 mm×2.1 mm,1.7μm)分离,以甲醇和0.002 mol/L乙酸铵溶液为流动相梯度洗脱,采用电喷雾离子源电离、正离子多反应监测模式质谱检测。环己胺在2.5~200μg/L浓度范围内有较好的线性关系,相关系数大于0.999,回收率为98.7%~102.3%,精密度为3.1%~5.2%,检出限和定量限分别为1.0和3.0μg/L。结果表明,本方法操作简单、准确可靠,可适用于人体尿液中环己胺的定量分析。应用本方法测定200份学生尿液样品,环己胺检出率为34.5%。     

柱前衍生法测定烟叶中的7种生物胺

建立了丹磺酰氯柱前衍生高效液相色谱法(HPLC)测定烟草基因编辑素材中的7种生物胺的方法。采用0.4 mol/L HClO_4进行样品超声提取,提取液经过pH调整后,利用丹磺酰氯(4 mg/mL)进行柱前衍生;衍生后的样品溶液利用优化的HPLC-DAD色谱方法进行检测;方法在1.0～50μg/mL范围内具有较好的线性(R~2 0.98),检出限在0.01～0.15μg/mL之间,定量限在0.05～0.25μg/mL之间,日间和日内精密度均小于5%,不同加标水平下,平均回收率在86.7%～124.0%之间。     

超高效液相色谱-串联质谱法快速测定蔬菜中7种氨基甲酸酯类农药残留

采用超高效液相色谱-串联质谱联用(UPLC-MS/MS)技术建立了同时检测蔬菜中7种氨基甲酸酯类农药多残留量的快速检测方法。样品经乙腈提取,氨基固相萃取柱净化,WatersC18超高效液相色谱柱分离,进入电喷雾串联四极杆质谱进行检测,采用多反应监测(MRM)分析,对液质分离条件和样品前处理条件进行了优化。结果表明7种氨基甲酸酯类农药在2～500μg/L范围内线性良好(r≥0.9986)。在0.005～0.01mg/kg范围内,平均加标回收率在72.4%～112.1%之间;相对标准偏差小于13%。该方法检出限范围为1.31～3.72μg/L,测定结果满足多残留农残的检测要求。     

液相色谱同位素稀释串联质谱法测定人血清中17β-雌二醇含量

研究建立了以人血清中E2-16,16,17-d3为内标测定17β-雌二醇的液相色谱/串联质谱(ID-LC/MS/MS)方法。血清样品经固相萃取装置(SPE)提取雌二醇,乙酸乙酯萃取净化,吹干复溶后用10-乙基吖啶酮-2-磺酰氯(EASC)进行衍生。以Agilent Eclipse XDB-C18色谱分离柱,乙腈、水梯度洗脱,使用电喷雾三重四极杆串联质谱的多重反应监测模式测定,以校准曲线法进行定量。所建立的液相色谱同位素稀释串联质谱法(ID-LC/MS/MS)对于分析血清17β-雌二醇的批内、批间RSD分别为0.29%～0.73%和0.18%～0.28%,回收率为99.6%～100.2%,采用IFCC RELA比对(JCTLM比对)样品进行了方法比较,测定结果与其他实验室相比偏差在0.8%范围内。方法可作为人血清中17β-雌二醇含量测量参考方法。     

超高效液相色谱-串联质谱筛查确证尿液中磺胺、喹诺酮与四环素抗生素

建立了超高效液相色谱-串联质谱法（UPLC-MS/MS）同时测定尿液中磺胺类、四环素类、喹诺酮类共45种抗生素的检测方法。尿液样品经提取后，采用HLB固相萃取柱（200 mg/6 mL）净化，使用ThermoAccucore RP-MS(100 mm×2.1 mm,2.6μm)色谱柱进行分离，以乙腈-0.02%甲酸溶液为流动相梯度洗脱。在正离子扫描模式下（ESI+），以选择反应监测模式（SRM）检测，外标法定量。45种目标化合物在3个加标水平（2.0、5.0、10.0μg/L）下的回收率为78.6%～114%，相对标准偏差为0.60%～18%；方法的检出限为0.1～0.5μg/L，定量下限为0.3～1μg/L。将所建方法用于280个尿液样品中抗生素的检测，均未检测到抗生素残留。所建方法的精密度和准确度高，操作简单便捷，为尿液中抗生素残留的筛查提供了方法支持。     

测定2-萘磺酰氯的二丁胺柱前衍生化反相高效液相色谱法

报道了一种测定有机中间体2-萘磺酰氯的方法。2-萘磺酰氯试样先与过量二丁胺在室温下磺酰胺化反应 ,再用反相高效液相色谱法分析 ,以HypersilBDS-C18(4.0mm×200mm ,5μm)为色谱柱 ,以67 % ( φ)乙腈水溶液 ,加1 % ( φ)二丁胺并用磷酸调节 pH至6.5为流动相 ,以224nm为检测波长。在0.006～0.4g/L范围试样质量浓度与峰面积呈线性相关 ,相关系数为0.9993,检出限为0.5ng(S/N=3)。方法简单、快速、灵敏、准确。     

免疫亲和柱净化-超高效亲水色谱-三重四极杆质谱联用法测定人尿液和血浆中河豚毒素

建立了测定人尿液和血浆中河豚毒素( TTX)的超高液相色谱-三重四极杆质谱联用分析方法。尿液和血浆样品经免疫亲和柱净化,以0.1%甲酸-乙腈和0.1%甲酸溶液作为流动相进行梯度洗脱,在UPLC BEH Amide柱上实现分离,正离子电喷雾多反应监测( MRM)模式检测,溶剂标准外标法定量。尿液和血浆中TTX的测量范围为0.05~400μg/L,平均加标回收率分别为92%~95%和91%~96%,相对标准偏差在3.3%~7.2%和3.9%~7.8%(n=5)之间,样品中 TTX的检出限(S/N=3)均为0.02μg/L,定量限(S/N=10)为0.05μg/L。本方法适用于尿液和血浆中TTX的中毒检测和临床监测。     

超高效液相色谱三重四极杆质谱联用法快速检测尿液和血浆中鹅膏毒肽和鬼笔毒肽

建立了同时快速检测尿液和血浆中3种鹅膏毒肽和2种鬼笔毒肽的超高效液相色谱三重四极杆质谱联用分析方法。尿液样品直接进样,血浆样品经乙腈沉淀除蛋白后,在UPLCHSST3色谱柱上分离,正离子电喷雾多反应监测(MRM)模式检测,基体匹配标准外标法定量。尿液和血浆样品的线性范围分别为2～100和1～100μg/L;加标回收率分别在92.0%～108.0%和85.0%～100.0%的范围内;相对标准偏差为1.0%～22.0%和2.0%～22.0%(n=6);样品的检出限为0.2～1.0μg/L和0.1～0.5μg/L(S/N=3)。本方法灵敏,简单,快速,特异性强。     

高效液相色谱-离子阱质谱法测定尿液中β2-受体激动剂及β-受体阻断剂

建立了尿液中23种β2-受体激动剂及5种β-受体阻断剂的高效液相色谱-离子阱质谱(HPLC-IT-MS)测定方法。尿液样品采用冷冻高速离心沉淀蛋白,上清液过ExtrelutTM硅藻土柱,用乙酸乙酯洗脱后,洗脱液经旋转蒸发仪浓缩并复溶待测。HPLC分离采用AtlantisT3-150 mm色谱柱,以甲醇和含0.1%甲酸的水溶液为流动相梯度洗脱,IT-MS采用电喷雾离子源在多反应离子监测模式下测定。定量分析选择9种经过氘代同位素标记的β2-受体激动剂为内标。各化合物的线性范围为0.005～0.16 mg/L,尿液中的检出限均能达到0.2 μg/L。空白尿液样品中不同加标水平的回收率为57.1%～127.1%,相对标准偏差为1.1%～31.1%。该方法简便快速,灵敏度高,适用于人或动物尿液中23种β2-受体激动剂及5种β-受体阻断剂的定性和定量分析。     

高效液相色谱串联质谱法测定水体中氨基脲、5-甲基吗啉-3-氨基-2-恶唑烷基酮、1-氨基乙内酰脲和3-氨基-2-唑烷基酮

建立了高效液相色谱三重四极杆串联质谱检测水体中痕量氨基脲(SEM)、5-甲基吗啉-3-氨基-2-恶唑烷基酮(AMOZ)、1-氨基乙内酰脲(AHD)和3-氨基-2-唑烷基酮(AOZ)的分析方法。水样在pH 1.5～3条件下衍生8 h,经乙酸乙酯萃取,氮吹浓缩,流动相溶解后,内标法定量。分析条件为:CAPCELLPAK C18色谱柱,以甲醇和2 mmol/L乙酸铵(含0.1%甲酸)溶液为流动相进行梯度洗脱。结果表明:AMOZ、AHD和AOZ在0.005～1μg/L范围内,SEM在0.01～1μg/L范围内呈现良好的线性关系,相关系数均大于0.9980。AMOZ、AHD和AOZ的定性检测限和定量检测限为分别为0.0025μg/L和0.005μg/L;SEM的定性检测限和定量检测限为分别为0.005μg/L和0.01μg/L。4种化合物在水体中3个不同浓度添加水平下的平均回收率为84.9%～110.4%,相对标准偏差为1.2%～7.8%。方法可用于分析环境水体中4种化合物的残留。     

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.     

多环芳二酐型聚酯亚胺膜的透气性能

多环芳二酐型聚酯亚胺膜的透气性能李悦生，丁孟贤，徐纪平（浙江大学高分子科学与工程研究所，杭州，３１００２７）（中国科学院长春应用化学研究所）关键词聚醚酰亚胺，聚酯酰亚胺，膜，透气性通常的聚酰亚胺加工性能较差，在芳环二酐的苯环间引入醚键等柔性基团后，其...     

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).