卷烟主流烟气气相水分的捕集及气相色谱法测定

提出了用剑桥滤片捕集烟气粒相物,以异丙醇和乙醇为吸收液、两级碰撞捕集器串联捕集烟气气相物,用气相色谱法测定主流烟气粒相和气相水分含量的方法。试验结果表明:线性范围为0.8～6.0g.L-1,相对标准偏差(n=5)小于2.5%之间,回收率为93.46%～106.15%。采用该法对7种卷烟主流烟气中粒相和气相水分进行测定,烟气总水分含量为6.77～9.43mg.支-1,其中气相水分约占总水分的65%～75%,表明气相水分是研究卷烟品质的重要参数。     

同时测定卷烟主流烟气中14种酸味成分的方法

公开(公告)号:CN106556665A公开(公告)日:2017.04.05申请(专利权)人:中国烟草总公司郑州烟草研究院摘要本发明公开了一种同时测定卷烟主流烟气中14种酸味成分的方法,包括下列步骤:(1)用剑桥滤片捕集卷烟主流烟气粒相物后,将剑桥滤片转入提取容器,加入丙酮溶液,再     

一种LC–MS/MS检测卷烟侧流烟气中茄尼醇的方法

<正>申请公布号:CN106198807A申请公布日:2016.12.07申请人:中国烟草总公司郑州烟草研究院摘要一种LC–MS/MS检测卷烟侧流烟气中茄尼醇的方法,其特征在于:该方法利用鱼尾罩和剑桥滤片捕集卷烟侧流烟气的粒相物,转移剑桥滤片至锥形瓶内,并采用甲醇反复淋洗鱼尾罩,将淋洗液加入上述锥形瓶中,对剑桥滤片进行超声萃取,采用LC–MS/MS对萃取液中的茄尼醇进行检测,采用LC–MS/MS对茄尼醇标准溶液进行检测,根据外标     

LC-MS-MS法测定卷烟侧流烟气中的亚硝胺

采用鱼尾罩和剑桥滤片捕集卷烟侧流烟气中的粒相颗粒物,建立了LC-MS-MS法测定卷烟侧流烟气中4种烟草特有的亚硝胺TSNAs(NNN,NAT,NAB,NNK)。剑桥滤片在醋酸铵水溶液中机械振荡40min后提取萃取液,萃取液经0.22μm滤膜过滤后,直接进LC-MS-MS分析。鱼尾罩壁上的冷凝物用甲醇溶液清洗,洗液通过氮吹浓缩后,采用PCX固相萃取小柱净化进样分析。测定方法的检测限为0.09～0.25ng/mL,线性相关系数均大于0.996,4种TSNAs的回收率均在88.2%～110.2%之间,相对标准偏差RSD均小于7%。方法适合作为卷烟侧流烟气中四种烟草特有亚硝胺(TSNAs)的定量分析方法。     

同时测定加热非燃烧卷烟主流烟气中14种酸味成分的方法

本发明公开了一种同时测定加热非燃烧卷烟主流烟气中14种酸味成分的方法,包括下列步骤:(1)用剑桥滤片捕集加热非燃烧卷烟主流烟气粒相物后,将剑桥滤片转入提取容器,加入丙酮溶液,再加入内标溶液进行震荡提取,取上清液加入衍生化试剂加热后得烟气样品;(2)采用气相色谱质谱联用(GC–MS)法对烟气样品进行检测,通过内标定量法检测出14种酸味成分含量。本发明采用溶剂萃取–GC–MS法,可同时测定加热非燃烧卷烟主流烟气中14种酸味成分的含量,具有快速检测、灵敏度高、选择性好、精确度高的优点;特别适用于测定加热非燃烧卷烟烟气中酸味成分的含量。     

离子色谱法测定卷烟主流烟气中的硫化氢

建立了测定卷烟主流烟气中硫化氢含量的离子色谱法.采用玻璃纤维滤片捕集卷烟烟气粒相物,并用0.5%(体积分数)乙二胺-50 mmol/L氢氧化钠-250 mmol/L乙酸钠溶液萃取粒相物,吸收液吸收气相物中的硫化氢,合并粒相萃取液与气相吸收液,经离子色谱柱分离,以1.5 mol/L氢氧化钠-1 mol/L乙酸钠-2%(体积分数)乙二胺(40∶50∶10,体积比)为流动相,安培检测器检测并施加-100 mv的检测电位.运用方法对12种市售卷烟样品进行了测定,结果表明:方法的线性范围为0.1~5.0μg/mL,检出限为1.03μg/mL,定量限为3.41μg/mL,回收率为102.3%~107.2%,相对标准偏差小于5%.方法处理简单、准确度高,可以用于卷烟烟气中硫化氢含量的测定.     

固相萃取新装置净化-超高效液相色谱法测定卷烟主流烟气中的苯并[α]芘

研究了用正相固相萃取净化,超高效液相色谱测定卷烟主流烟气中苯并[α]芘的方法。捕集有卷烟主流烟气总粒相物的剑桥滤片置于自主设计的样品萃取瓶中,用环己烷-乙醇(95:5,V/V)超声振荡萃取,提取液用硅胶固相萃取净化,然后以Waters ACQUITY UPLC BEH C18(2.1×50 mm,1.7μm)色谱柱为固定相,甲醇为流动相,超高效液相色谱-荧光检测测定;苯并[α]芘检出限为0.22 ng/支,样品加标回收率为89.6%~95.4%,日内相对标准偏差为3.2%,日间相对标准偏差为3.6%;结果令人满意。     

化学电离–气相色谱–串联质谱法测定卷烟侧流烟气中的4种烟草特有亚硝胺

建立了化学电离–气相色谱–串联质谱法测定卷烟侧流烟气中4种烟草特有亚硝胺(TSNAs)的方法。采用吸烟机对卷烟进行抽吸,利用鱼尾罩和剑桥滤片对卷烟侧流烟气进行捕集,用稀盐酸溶液进行鱼尾罩洗涤和剑桥滤片萃取,萃取液经阳离子交换固相萃取柱净化,采用氨水甲醇溶液洗脱,洗脱液经氮气吹干后用二氯甲烷定容至1 mL,过滤膜后检测,利用色谱峰面积内标法定量。4种TSNAs的质量浓度在1～500 ng/mL范围内与各目标物和内标的色谱峰面积比线性关系良好,相关系数均大于0.999 1,检出限为0.16～0.35 ng/mL。加标回收率为80.8%～107.4%,检测结果的相对标准偏差为3.2%～6.8%(n=6)。     

离子色谱法测定卷烟烟气中氨

用离子色谱法测定卷烟主流烟气中氨。选取同一包装中的卷烟,按行标YC/T 29-1996的规定用吸烟机抽吸。用剑桥滤片捕集卷烟烟气粒相部分,将所得滤片用0.005 mol.L-1盐酸溶液提纯。用0.005 mol.L-1盐酸溶液吸收卷烟烟气气相部分。将两份盐酸溶液合并后再通过装填有MCI-GEL反相树脂的固相萃取柱除去焦油和烟碱类物质,然后用离子色谱测定氨。方法的检出限(3S/N)为0.006 mg.L-1。在吸烟所得提取液中的加标回收率在95.6%~102.5%之间。试样平行7次测定的相对标准偏差为3.1%。方法用于10种品牌卷烟中氨的测定,氨量范围为7.62~14.0μg.支-1。     

卷烟主流烟气中8种羰基化合物的超高效液相色谱测定

建立了超高效液相色谱(UPLC）对卷烟主流烟气总粒相物中甲醛、乙醛、丙酮、巴豆醛等8种羰基化合物的测定方法。采用经2,4-二硝基苯肼酸性溶液处理过的剑桥滤片捕集烟气,再用含2%(体积分数）吡啶的乙腈溶液进行萃取,以KinetexTM C18(150 mm×2.1 mm,2.6 μm）为色谱柱,水-乙腈(35∶65）和水-乙腈-四氢呋喃-异丙醇(59∶30∶10∶1）为流动相梯度洗脱,采用二极管阵列检测器进行检测,分析时间为20 min。结果表明,该方法的相关系数r2≥0.999 97,检出限为25.81~67.74 ng/cig,平均加标回收率为95%~99%,相对标准偏差为1.4%~5.8%。各组分峰分离度高、分析时间短、流动相耗量少、结果准确可靠。用该方法对20种不同卷烟牌号样品中8种羰基化合物的含量进行测定,结果满意。     

Regioselectivity of olefin oxidation by iodosobenzene catalyzed by metalloporphyrins : control by the catalyst

The regioselectivity of the oxidation of three monosubstituted olefins, 6-phenoxyhex-1-ene, hex-1-ene and styrene, by iodosobenzene in the presence of various Fe-, Mn- or Cr-tetraaryl-porphyrins, was studied. It was found that, besides epoxides, known products from such systems, allylic alcohols and aldehydes were formed, the latter not being derived from the corresponding epoxides. The relative importance of these reactions greatly depends upon both the metal and porphyrin constituents of the catalyst. More particularly, the competition between epoxidation and allylic hydroxylation can be efficiently controlled by non-bonded interactions between the olefin and porphyrin substituents. No hydroxylation of the aromatic rings and no oxidative dealkylation of the ether function was detected.     

Enantiomer separation by CEC——Enantiomer separation by packed-capillary electrochromatography

Three chiral compounds were successfully separated in a short time with two enantiomer separation models on packed-capillary electrochromatography (CEC). (i) 75 μm I.D. capillaries were packed with 5 μm β-cyclodextrin (β-CD) chiral stationary phase (CSP). Effects of voltage, pH and concentration of organic modifier on electroosmotic flow (EOF) and chiral separations were investigated systematically. Enantiomers of a neutral compound (benzoin) and a neutral drug (mephenytoin) were separated within a short time with high efficiency. Efficiency of 32 000 theoretical plates per meter and resolution (R_s) of 1.42 were achieved for enantiomers of benzoin using a βCD packed column with 6.2 cm packed length. Efficiency of 45 000 theoretical plates per meter and R_s of 3.40 were obtained for enantiomers of mephenytoin. Especially, the enantiomer separation of mephenytion was performed in just 3.4 min with R_s of 2.60. (ⅱ) 75 μm I.D. capillary was packed with octadecylsilica particles (ODS). Chiral separat     

Membrane solubilization by detergent: resistance conferred by thickness

The commonly held model for membrane dissolution by detergents/surfactants requires lipid transport from the inner to the outer bilayer leaflet ('flip-flop'). Although applicable to many systems, it fails in cases where cross-bilayer transport of membrane components is suppressed. In this paper we investigate the mechanism for surfactant-induced solubilization of polymeric bilayers. To that end, we examine the dissolution of a series of increasingly thick, polymer-based vesicles (polymersomes) by a nonionic surfactant, Triton X-100, using dynamic light scattering. We find that increasing the bilayer thickness imparts better resistance to dissolution, so that the concentration required for solubilization, after a fixed amount of time, increases nearly linearly with membrane thickness. Combining our experimental data with a theoretical model, we show that the dominant mechanism for the surfactant-induced dissolution of polymeric vesicles, where polymer flip-flop across the membrane is suppressed, is the surfactant transport through the bilayer. This mechanism is different both qualitatively and quantitatively from the mechanisms by which surfactants dissolve pure lipid vesicles.     

Antibiotic recognition by binuclear metallo-beta-lactamases revealed by X-ray crystallography

Metallo-beta-lactamases are zinc-dependent enzymes responsible for resistance to beta-lactam antibiotics in a variety of host bacteria, usually Gram-negative species that act as opportunist pathogens. They hydrolyze all classes of beta-lactam antibiotics, including carbapenems, and escape the action of available beta-lactamase inhibitors. Efforts to develop effective inhibitors have been hampered by the lack of structural information regarding how these enzymes recognize and turn over beta-lactam substrates. We report here the crystal structure of the Stenotrophomonas maltophilia L1 enzyme in complex with the hydrolysis product of the 7alpha-methoxyoxacephem, moxalactam. The on-enzyme complex is a 3'-exo-methylene species generated by elimination of the 1-methyltetrazolyl-5-thiolate anion from the 3'-methyl group. Moxalactam binding to L1 involves direct interaction of the two active site zinc ions with the beta-lactam amide and C4 carboxylate, groups that are common to all beta-lactam substrates. The 7beta-[(4-hydroxyphenyl)malonyl]-amino substituent makes limited hydrophobic and hydrogen bonding contacts with the active site groove. The mode of binding provides strong evidence that a water molecule situated between the two metal ions is the most likely nucleophile in the hydrolytic reaction. These data suggest a reaction mechanism for metallo-beta-lactamases in which both metal ions contribute to catalysis by activating the bridging water/hydroxide nucleophile, polarizing the substrate amide bond for attack and stabilizing anionic nitrogen intermediates. The structure illustrates how a binuclear zinc site confers upon metallo-beta-lactamases the ability both to recognize and efficiently hydrolyze a wide variety of beta-lactam substrates.     

DNA damage by sulfite autoxidation catalyzed by cobalt complexes

DNA damage was investigated in the presence of sulfite, dissolved oxygen and cobalt(II) complexes with glycylglycylhistidine, glycylhistidyllysine, glycylglycyltyrosylarginine and tetraglycine. These studies indicated that only Co(II) complexed with glycylglycylhistidine (GGH) induced DNA strand breaks at low sulfite concentrations (1-80 microM) via strong oxidants formed in the reaction. In the presence of the other complexes, some damage occurred only in the presence of high sulfite concentrations (0.1-2.0 mM) after incubation for 4 h. In the presence of GGH, Co(II) and dissolved O2, DNA damage must involve a reactive high-valent cobalt complex. The damaging effect was increased by adding S(IV), due to the oxysulfur radicals formed as intermediates in S(IV) autoxidation catalyzed by the complex. SO3 -, HO and H radicals were detected by EPR-spin trapping experiments with DMPO (5,5-dimethyl-1-pyrroline N-oxide). The results indicate that Co(II) binds O2 in the presence of GGH, and leads to the formation of a DMPO-HO adduct without first forming free superoxide or hydroxyl radical, supporting the participation of a reactive high-valent cobalt complex.     

Substitution of 2-phosphaindolizines by bromine and by chlorophosphines

Bromine does not add to phosphorus in a 2-phosphaindolizine 1 but substitutes its 1-position. The 1-bromo derivatives 2 are best prepared with Br₂/NEt₃ or N-bromosuccinimide. Their hydrolysis is remarkable; it involves a debromination of C-1, an oxidation of P and a selective opening of the P/C-3 bond. PCl₃ also causes a substitution of the 1-position. The resulting 1-dichlorophosphino derivatives 5 easily undergo a substituent exchange at the exocyclic phosphorus. More 1-phosphino derivatives are formed in the reaction of 1 with phenyl and diazaphospholyl dichlorophosphine.     

Multitargeting by curcumin as revealed by molecular interaction studies

Curcumin (diferuloylmethane), the active ingredient in turmeric (Curcuma longa), is a highly pleiotropic molecule with anti-inflammatory, anti-oxidant, chemopreventive, chemosensitization, and radiosensitization activities. The pleiotropic activities attributed to curcumin come from its complex molecular structure and chemistry, as well as its ability to influence multiple signaling molecules. Curcumin has been shown to bind by multiple forces directly to numerous signaling molecules, such as inflammatory molecules, cell survival proteins, protein kinases, protein reductases, histone acetyltransferase, histone deacetylase, glyoxalase I, xanthine oxidase, proteasome, HIV1 integrase, HIV1 protease, sarco (endo) plasmic reticulum Ca(2+) ATPase, DNA methyltransferases 1, FtsZ protofilaments, carrier proteins, and metal ions. Curcumin can also bind directly to DNA and RNA. Owing to its β-diketone moiety, curcumin undergoes keto-enol tautomerism that has been reported as a favorable state for direct binding. The functional groups on curcumin found suitable for interaction with other macromolecules include the α, β-unsaturated β-diketone moiety, carbonyl and enolic groups of the β-diketone moiety, methoxy and phenolic hydroxyl groups, and the phenyl rings. Various biophysical tools have been used to monitor direct interaction of curcumin with other proteins, including absorption, fluorescence, Fourier transform infrared (FTIR) and circular dichroism (CD) spectroscopy, surface plasmon resonance, competitive ligand binding, Forster type fluorescence resonance energy transfer (FRET), radiolabeling, site-directed mutagenesis, matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS), immunoprecipitation, phage display biopanning, electron microscopy, 1-anilino-8-naphthalene-sulfonate (ANS) displacement, and co-localization. Molecular docking, the most commonly employed computational tool for calculating binding affinities and predicting binding sites, has also been used to further characterize curcumin's binding sites. Furthermore, the ability of curcumin to bind directly to carrier proteins improves its solubility and bioavailability. In this review, we focus on how curcumin directly targets signaling molecules, as well as the different forces that bind the curcumin-protein complex and how this interaction affects the biological properties of proteins. We will also discuss various analogues of curcumin designed to bind selective targets with increased affinity.