超高效液相色谱-串联质谱法快速分析烟叶中的8种生物碱

采用超高效液相色谱-串联质谱(UPLC-MS-MS)建立了快速分析烟叶中8种生物碱的分析方法。50 mg烟叶粉末样品经2 mL 6%氨水浸润后，以10 mL二氯甲烷超声提取20 min,有机相用N-丙基-乙二胺(PSA)净化后氮吹近干，再以乙腈超声复溶后用UPLC-MS-MS分析。烟叶中8种生物碱(烟碱、新烟碱、新烟草碱、降烟碱、二烯烟碱、2,3′-联吡啶、可替宁、麦斯明)的平均回收率在86.5%～102%之间，相对标准偏差(n=6)为2.1%～5.4%;方法对烟碱的检出限为0.45 mg/g,定量限为1.5 mg/g;对其余7种微量生物碱的检出限在0.15～0.6μg/g之间，定量限在0.5～2μg/g之间。本方法适用于烟叶中8种生物碱含量的快速测定。     

全扫描-选择离子数据采集技术应用于烟草中生物碱的快速测定

建立了应用气相色谱-质谱(GC-MS)全扫描-选择离子监测(Scan-SIM)数据采集方式同时测定烟草中8种含量相差较大的生物碱的方法,采用Scan模式分析烟碱、降烟碱、新烟碱、去氢新烟碱,同时采用SIM模式分析麦斯明、二烯烟碱、2,3′-联吡啶、可铁宁。结果表明,烟草中各生物碱的回收率为94.8%～98.8%,5次测定的相对标准偏差均小于6%。该方法具有简单、快速、准确的特点,应用于烟草样品测定,结果令人满意。     

高效液相色谱-光水解热裂解-热能分析联用技术测定烟草中的N′-亚硝基去甲烟碱

应用实验室自行设计的高效液相色谱仪-光水解热裂解器-热能分析仪联机装置,建立了一种准确有效的色谱分析方法,用于分离检测烟草中的烟草特有亚硝胺N'-亚硝基去甲烟碱（NNN）、4-亚硝基甲氨基-1-（3-吡啶基）-1-丁酮和另外两种挥发性亚硝胺二甲基亚硝胺、亚硝基吡咯烷。NNN浓度在1~10mg/L时NNN与NaNO2的色谱峰面积比与浓度呈线性关系,绝对检测下限为6ng。用该方法分离并测定了烟草样品中NNN的含量。     

UPLC-MS/MS对卷烟烟气中4种烟草特有亚硝胺的快速测定

建立了卷烟主流烟气中烟草特有亚硝胺的超高效液相色谱-电喷雾串联质谱(UPLC-MS/MS)测定方法。在标准吸烟条件下,采用剑桥滤片收集卷烟烟气粒相物,用醋酸铵缓冲液提取粒相物,经固相萃取净化后,以电喷雾正离子多反应监测方式,实现了烟气中N-亚硝基降烟碱、4-甲基亚硝基吡啶基丁酮、N-亚硝基新烟草碱和N-亚硝基假木贼碱的基线分离和快速测定。4种烟草特有亚硝胺在0~400μg/L范围内具有良好线性,相关系数大于0.998,定量下限为0.08~0.15μg/L,加标回收率为72%~104%,相对标准偏差为3.8%~9.7%。该方法灵敏、快速、准确,适用于卷烟烟气中烟草特有亚硝胺的测定。     

亲水作用色谱分离-高效液相色谱法测定烟草不同部位中烟碱的含量

提出了亲水作用-高效液相色谱法测定不同烟草部位中烟碱含量的方法。采用Atlantis HILIC色谱柱(150mm×4.6mm,5μm)分离,以乙腈、10mmol·L-1乙酸铵溶液和冰乙酸以体积比72比28比2组成的混合液为流动相,在检测波长260nm处进行测定。烟碱的质量浓度在0.001~0.1g·L-1范围内与峰面积呈线性关系,方法检出限(3S/N)为0.17mg·L-1。进行3个浓度水平的加标回收试验,测得回收率在98.2%~98.9%之间,相对标准偏差(n=6)小于2.0%。从烟草的不同部位取样,按本法分析,结果表明:其烟碱含量从烟叶的上部、中部、下部至烟梗逐渐减少。     

加速溶剂萃取-气相色谱-串联质谱法检测烟草中生物碱

建立了气相色谱-串联质谱(GC-MS/MS)法同时测定烟草中烟碱、降烟碱、麦斯明、假木贼碱和新烟草碱等5种生物碱的分析方法。以甲醇和Na OH溶液混合溶剂作提取溶剂,样品经加速溶剂萃取(ASE)萃取后,利用GC-MS/M S的多反应监测模式(M RM)测定,内标法定量。5种生物碱的检出限在0.06~0.12μg/m L之间,加标回收率介于88.9%~106.8%,相对标准偏差(RSD)均小于6%。方法适用于批量烟草样品中生物碱的快速测定。     

烟草中烟碱的水相萃取和液相色谱分析

本文系统地研究了烟草中烟碱的水相萃取,建立了测定烟碱的萃取-色谱法。此法不仅简单、准确,而且克服了传统蒸馏法测定结果偏低的弊端。     

烟草及烟草制品总挥发酸的测定--连续流动法

采用连续流动方法测定烟草及其制品中的总挥发酸,详细研究了测定条件.结果表明最大吸收波长为350 nm,标准乙酸溶液在0.086～4.0 μg/mL的范围内服从比尔定律,摩尔吸光系数为1.174×104L·mol-1·cm-1,对烟草中挥发酸的检出限为0.012mg/g,相关系数为0.999 5,测定范围为0.12～5.0mg/g.方法具有很好的灵敏度和较高的精密度.     

溴甲酚绿光度法测定烟草中的烟碱

研究了酸性染料溴甲酚绿与烟碱形成缔合物的反应.发现在pH=4.5的乙酸-乙酸钠缓冲溶液中,溴甲酚绿与烟碱能形成离子缔合物,并能被氯仿所萃取.其最大吸收在42Onm处,烟碱在0～12μg·ml~(-1)范围内符合比耳定律,应用此法测定了烟草中的烟碱含量,结果满意.     

气相色谱/质谱分析烟草中的主要生物碱

用毛细管气相色谱法测定烟草中烟碱、降烟碱、麦斯明、二烯烟碱、新烟碱、去氢新烟碱、2,3′-联二吡啶、可替宁8种主要生物碱的方法。烟草样品经二氯甲烷/甲醇(V/V,3∶1)萃取,过一次性滤膜,进样,经DB-5MS毛细管柱分离,由气相色谱-氢火焰离子化检测器(FID)检测定量,质谱定性。该方法操作简单,重现性好,回收率较高。8种生物碱相对标准偏差为2.59%~7.07%;回收率为89.4%~98.7%。     

Polycations as displacer in high-performance bioseparation

Non-aqueous capillary electrophoresis with electrochemical detection (NACE-ED) was applied to the determination of nicotine. The measurements were performed using an acetonitrile-based buffer. Nicotine was shown to yield well defined voltammetric signals suitable for oxidative detection. The precision of NACE-ED regarding migration time and peak height for samples containing 8 micrograms/ml nicotine is expressed by relative standard deviations of 0.1% and 1.6%, respectively (n = 8). The limit of detection for nicotine was 13 ng/ml (286 fg). For nicotine determination in tobacco samples various solutions were studied regarding the extraction efficiency in an ultrasonic bath. The highest extraction efficiency was obtained using a solvent mixture consisting of acetonitrile-acetic acid-water (20:5:75, v/v). The results for nicotine determination in tobacco were evaluated using tobacco reference material with certified nicotine content. Analytical aspects such as accuracy, reproducibility and selectivity were addressed in this work. The measurements were based on the use of a newly developed electrochemical detector cell which was found to enable user-friendly operation of NACE-ED measurements.     

Flow injection Fourier transform infrared determination of nicotine in tobacco

A fully automated procedure is proposed for the Fourier transform infrared (FTIR) determination of nicotine in tobacco. The method is based on the on-line extraction of nicotine with CHCl3. Samples, weighed inside empty extraction cartridges, were humidified with NH3 and the cartridges were installed in a flow manifold in which they were extracted with 2 ml CHCl3 for 2 min, then 400 microliters of the extract were introduced into a micro-flow cell using a carrier of CHCl3 and the IR spectrum was registered continuously. The absorbance, in the wavenumber range 1334-1300 cm-1, was measured, obtaining a peak as a function of time. The area of this peak was interpolated on a calibration line established from standard solutions of nicotine in chloroform treated in the same way as samples. The method provided a limit of detection of 0.1 mg ml-1 nicotine, an RSD lower than 2% and a sampling frequency of the whole procedure of 6 h-1. Results obtained for natural samples of cut tobacco and cigar compared well with those obtained by a batch FTIR procedure, involving an off-line extraction with a total time of 16 min. However, for yellow tobacco cigarette, an on-line extraction time of 10 min was required to obtain a good recovery of nicotine.     

溶剂棒微萃取-HPLC法快速测定常用蔬菜中的痕量尼古丁

建立了一种以溶剂棒微萃取为样品前处理技术,HPLC/UV法测定常用蔬菜中痕量尼古丁的方法。系统优化了溶剂棒微萃取条件以及HPLC法测定尼古丁的相关参数,方法的线性范围0.005~1 mg/L,相关系数为0.9999;检出限0.002 mg/L(S/N=3);在优化的实验条件下对尼古丁的富集倍数可达190倍。样品加标回收率72%~111%(除黄瓜加标样品为47%),相对标准偏差小于10.0%(n=3)。实验证明,本方法可用于常用蔬菜中痕量尼古丁的有效富集、测定。     

Determination of Nicotine in Tobacco by Capillary Electrophoresis with Electrochemical Detection

A sensitive, simple and low-cost method based on capillary electrophoresis(CE) with electrochemical(EC) detection at a carbon fiber microdisk electrode(CFE) was developed for the determination of nicotine. Effects of detection potential, concentration and pH value of the phosphate buffer, and injection time as well as separation voltage were investigated. Under the optimized conditions: a detection potential of 1.20 V, 40 mmol/L phosphate buffer(pH 2.0), a sample injection time of 10 s at 10 kV and a separation voltage of 16 kV, the linear range obtained was from 5.0×10^-7 mol/L to 1.0×10^-4 mol/L with a correlation coefficient of 0.9989 and the limit of detection(LOD, S/N=3) obtained was 5.0×10^-8 mol/L. The method was also used to determine the nicotine in cigarettes. Nicotine amount ranged from 0.211 mg/g to 0.583 mg/g in the pipe tobacco of seven brands of cigarette and the amount in one cigarette varied from 0.136 mg/cigarette to 0.428 mg/cigarette.     

Simultaneous determination of nicotine and 3-vinylpyridine in single cigarette tobacco smoke and in indoor air using direct extraction to solid phase

The aim of the present study was to develop a new analytical method of chromatographic determination of two important markers of ETS exposure: nicotine and 3-vinylpyridine (3-ethenylpyridine, 3-EP) in mainstream (MS) and sidestream (SS) smoke of one single cigarette and in indoor air using direct solid phase extraction combined with gas chromatography. The method can be utilised for both nicotine and 3-EP determination in SS and MS of one single cigarette as well as it allows for a precise determination of compound distribution in indoor air. The application of the same analytical method for both kinds of samples allows anticipating indoor air distribution of both analysed compounds in a very precise way. The precision of the method (calculated as a relative standard deviation) was 9.78% for nicotine and 2.67% for 3-EP; whereas the accuracy (evaluated by a recovery study conducted at three different levels) was 70.1 and 87.3%, respectively. The limit of detection was 0.06 µg per cigarette for both nicotine and 3-EP. The method was evaluated by determining the compounds of interest in two commercially available brands of cigarettes as well as in the reference cigarettes 3R4F and also in indoor air polluted with tobacco smoke. Determined levels of compounds of interest in MS varied from 586 to 772 (nicotine) µg per cigarette and from 3.5 to 10.7 (3-EP) µg per cigarette. In SS smoke the level varied from 14,370 to 22,590 (nicotine) µg per cigarette and from 185 to 550 (3-EP) µg per cigarette, whereas levels in indoor air polluted with tobacco smoke varied from 50.1 to 157.3 (nicotine) µg m^?3and from 7.7 to 20.8 (3-EP) µg m^?3.     

水杨酸钠紫外分光光度法测定烟草中的总氮

建立水杨酸钠紫外分光光度法测定烟草中总氮含量的方法。烟草样品经硫酸铜–硫酸钾–浓硫酸消化,用水杨酸钠–二氯异氰尿酸钠显色后用紫外分光光度计检测,并对波长、显色剂用量和反应时间等实验条件进行了优化。总氮的质量浓度在5~60 mg/L范围内与其吸光度呈良好的线性关系,线性相关系数为0.998 8,方法的检出限为0.14 mg/L。样品分析结果的相对标准偏差为3.22%(n=6),样品加标回收率为99.30%~101.62%。该方法具有较高的精密度和准确度,尤其适用于样品量少时对烟草中总氮的测定。     

Polyaniline/graphene oxide nanocomposite as a sorbent for extraction and determination of nicotine using headspace solid-phase microextraction and gas chromatography–flame ionization detector

A solid-phase microextraction fiber was prepared by polyaniline/graphene oxide nanocomposite as sorbent on the surface of a platinized stainless steel wire using electrospinning technique. The nanocomposite structure was characterized by scanning electron microscopy and Fourier transform infrared spectroscopy. The polyaniline/graphene oxide nanocomposite fiber was used for the determination of nicotine from tobacco samples using headspace solid-phase microextraction method and gas chromatography–flame ionization detection. Influential experimental variables on the extraction efficiency of nicotine, such as extraction time and temperature, humidity and desorption conditions, were evaluated and optimized. Under the optimal experimental conditions? the limit of detection, linear dynamic range, intraday and inter-days precisions were found to be 0.01 μg g^?1, 0.05–700 µg g^?1 (R²?=?0.996), 6.9 and 8.1%, respectively. Comparison of the polyaniline/graphene oxide nanocomposite sorbent with polyaniline and commercial fibers shows longer durability, larger capacity and higher extraction efficiency. The polyaniline/graphene oxide nanocomposite fiber was successfully applied for the determination of nicotine in tobacco samples.     

超高效液相色谱法测定烟用香精中的欧前胡素

建立了测定烟用香精中欧前胡素的超高效液相色谱方法.以体积比为1∶1的乙腈-水溶液为萃取剂,采用ACQUITY UPLC(R)BEH C18(50 mm×2.1mm,1.7 μm)色谱柱,柱温为30℃,流动相为乙腈-水,进行梯度洗脱,流速为0.2 mL/min,检测波长为248 nm,对20种烟用香精样品进行测定.欧前胡...     

Application of response surface methodology to vortex‐assisted dispersive liquid–liquid extraction for the determination of nicotine and cotinine in urine by gas chromatography–tandem mass spectrometry

A method of vortex‐assisted dispersive liquid–liquid extraction coupled with gas chromatography and tandem mass spectrometry for the determination of nicotine and cotinine in urine was developed. Response surface methodology was applied to obtain the optimum extraction conditions. In this method, Plackett–Burman design was utilized to evaluate the impact of five selected factors on pretreatment procedure. Then, three main factors were optimized using a Box–Behnken design. The optimized method showed good linearities at 1–2000 μg/L with correlation coefficients of 0.9998 for nicotine and 0.9986 for cotinine. Recovery was 91.4–106 and 91.7–108% for nicotine and cotinine, respectively. The intraday relative standard derivations of determination were 1.47–4.06% for nicotine and 0.41–3.16% for cotinine, and interday relative standard derivations were 3.03–6.70% for nicotine and 1.64–6.38% for cotinine. The method detection limits for nicotine and cotinine were 0.33 and 0.34 μg/L, respectively. A total of 87 urine samples from smokers and nonsmokers were tested with the proposed method. Urinary nicotine and cotinine were 23.0–6.67 × 10³ and 18.4–4.17 × 10³ μg/(g·cr) for smokers and 1.31–286 and 1.39–131 μg/(g·cr) for nonsmokers, respectively. The method is sensitive, suitable and reliable for the determination of nicotine and cotinine in urine and meets the requirements for evaluating short‐term tobacco exposure.     

Potentiometric determination of nicotine in tobacco products with a nicotine-sensitive liquid membrane electrode

A simple potentiometric method with standard additions is described for the rapid determination of nicotine in tobacco products. A nicotine-sensitive electrode with a liquid membrane of nicotine hydrogen tetra(m-chlorophenyl)borate dissolved in o-nitrotoluene is used. The electrode exhibits near-Nernstian response to monoprotonated nicotine cation activity from 0.08 to 10^-5 M, in the pH range 4–7. Nicotine down to 2 mg per g of sample can be determined with a standard deviation of about 0.5 mg of nicotine. Comparison with an official method gave satisfactory results.