N,N-二烯丙基-5-甲氧基色胺片剂的GC/MS检验

目的 建立N,N-二烯丙基-5-甲氧基色胺的气相色谱-质谱(GC/MS)定性分析方法。方法 未知片剂样品用甲醇超声溶解,吸取上清液采用气相色谱-质谱(GC/MS)联用仪检测。结果 测得未知组分(tR=10.45min)的质谱特征碎片峰(m/z)信息为110.1(基峰)、270.1、174.1、160.1、145.0、130.1和117.1。查阅资料并对该组分的质谱图谱进行解析,鉴定为N,N-二烯丙基-5-甲氧基色胺,属于色胺类化合物。结论 该方法简单,准确,可用于N,N-二烯丙基-5-甲氧基色胺的鉴定。     

3,4-亚甲二氧基甲卡西酮的鉴定

目的 建立基于傅里叶变换红外光谱(FTIR)、气相色谱-质谱(GC-MS)结合高分辨质谱技术联合鉴定未知样品的方法.方法 未知样品采用红外专用取样器直接检测;甲醇溶解后采用GC-MS和组合型高分辨质谱检测,以MDMA为内标物.结果 未知样品获得的红外光谱特征吸收峰为1679(C=O键),1603,1502,1453,1423,1259,1121,1090,1035,930,887,838,768,742和717cm-1,质谱特征碎片峰(m/z)为58.1,91.0,120.9,149.0和207.0,测得的精确质量数[M+H]+为208.0966.经信息分析未知样品鉴定为3,4-亚甲二氧基甲卡西酮,该物质属于新型化学合成卡西酮类精神活性物质,已经列入部分欧盟国家的管制药物目录.结论 本方法可用于3,4-亚甲二氧基甲卡西酮的鉴定.     

苯二氮卓类新精神活性物质去氯依替唑仑的定性检验方法研究

目的建立苯二氮卓类新精神活性物质去氯依替唑仑的气相色谱-质谱(GC-MS)和超高效液相色谱-四极杆-飞行时间质谱(UPLC-Q-TOF MS)定性检验方法。方法未知样品用甲醇和水提取,取上清液,采用GC-MS和UPLC-Q-TOF MS进行分析。结果经GC-MS检测,保留时间为17.73 min的未知组分的质谱碎片主要特征离子峰有m/z 279,308,239,252,225,77,126。经UPLC-Q-TOF MS检测,保留时间为4.781 min的未知组分的准分子离子峰为309.1173,碰撞诱导解离(CID)模式下二级质谱主要离子有m/z 280.0776,255.0952,240.0719,225.0604,206.0748。经缴获毒品分析科学工作组(Scientific Working Group for the Analysis of Seized Drugs,SWGDRUG)分析谱库检索和文献查询获得的信息资料进行比对,鉴定为去氯依替唑仑。结论该方法具有分析简便、快速的特点,可以用于实际案件的检测。     

自主合成标准物质鉴定缴获物中的新精神活性物质ADB-FUBINACA

目的新精神活性物质在世界范围内蔓延迅速,但相关标准物质的短缺制约着其分析方法的研究和案件检验。本文以我国首次出现的N-(1-氨甲酰基-2,2-二甲基丙基)-1-(4-氟苄基)吲唑-3-甲酰胺(ADB-FUBINACA)制毒案件为例,介绍在无法及时获得商业化标准物质的情况下,不得不通过自主合成制备标准物质解决案件检验难题,建立该新精神活性物质检验的方法。方法建立气相色谱-质谱检验方法,分析条件:色谱柱为Aglient DB-5MS石英毛细管柱(30.00m×0.25mm×0.25μm);初始柱温60℃,按15℃/min升至300℃,保持15min;载气为氦,流速1.0mL/min,分流进样,进样量1.0μL,分流比20∶1;进样口温度280℃;电子轰击(EI)离子源,电子能量70eV,离子源温度230℃,四级杆温度150℃,传输线温度280℃,质量扫描范围m/z 40~500amu,全扫描模式(SCAN)采集总离子流图,溶剂延迟3.0min。案件缴获的送检未知样品经甲醇提取,超声、离心后,取上清液以GC-MS分析;将所得主要质谱特征碎片峰(m/z)通过NIST质谱库、SWGDRUG质谱数据库以及相关文献进行检索,初步确定待测目标物。采用有机合成技术制备ADB-FUBINACA标准物质,合成路线为:吲唑-3-甲酸甲酯与4-氟苄溴发生取代反应,生成1-(4-氟苄基)-1H-吲唑-3-甲酸甲酯;取代产物在碱性条件下经水解反应得到有机酸1-(4-氟苄基)-1H-吲唑-3-甲酸;在催化剂作用下,有机酸与L-叔亮酰胺发生酰化反应,制得化合物ADB-FUBINACA。经气相色谱-质谱(GC-MS)、液相色谱-离子阱-飞行时间质谱(LCMS-IT-TOF)、核磁共振(NMR)等分析,合成化合物的结构得以确证;同时采用超高效液相色谱-二极管阵列检测器(HPLC-PDA)进行分析,对其归一化纯度进行测定。将案件未知样品和合成标准物质分别用甲醇提取,超声、离心后,再行上清液GC-MS分析。结果经GC-MS分析,案件未知样品(RT=19.818min)的质谱特征碎片峰(m/z)信息为109.0(基峰)、253.1、338.1、309.1和145.0,经与合成标准物质的保留时间及质谱图检测比对,证实为N-(1-氨甲酰基-2,2-二甲基丙基)-1-(4-氟苄基)吲唑-3-甲酰胺;通过查阅相关资料,对上述质谱特征碎片峰的产生机制进行了推断,并对1H-NMR、13C-NMR和DEPT-135等一维核磁谱图的信号进行了归属分析。结论本文报道的新精神活性物质ADB-FUBINACA其GC-MS分析方法,可用于实际案件检验鉴定;合成化合物的结构表征方法也可用于固体ADB-FUBINACA的定性分析。基于有机合成技术的新精神活性物质制备与案件检验方法,可缓解有关标准物质短缺制约该类案件检验鉴定的现状。     

新精神活性物质Dibutylone的鉴定

目的建立基于气相色谱-质谱(gas chromatography-mass spectrometry,GC-MS)、高分辨质谱和核磁共振波谱技术联合鉴定未知样品的方法。方法样品用含内标盐酸双苯戊二氨酯(SKF525A)的甲醇溶液溶解后,采用GC-MS和高分辨质谱检测。混合样品经硅胶柱层析分离纯化后,用氘代甲醇溶液溶解进行核磁共振氢谱(~1H nuclear magnetic resonance spectroscopy,~1H NMR)的结构解析。结果 GC-MS检测获得样品中主要组分的质谱特征碎片离子m/z为86.1(基峰)、71.2、121.1、149.0,高分辨质谱实测分子离子峰的精确质量数为236.128 89,经数据分析再结合数据库比对在未知样品中检索出卡西酮类新精神活性物质1-[3,4-(亚甲二氧基)苯基]-2-二甲氨基-1-丁酮(Dibutylone),另外未知样品中还含有少量咖啡因。样品纯化后经~1H NMR鉴定,进一步确证为Dibutylone。此外,样品中主要组分的GC-MS保留时间和特征碎片离子与Dibutylone对照品一致。结论本研究建立的方法可用于混合样品中Dibutylone的鉴定。     

GC-MS检测新型策划毒品K3

目的基于气相色谱-质谱（GC-MS）检测结合特殊质谱库信息检索建立新型策划毒品的鉴定方法。方法未知样品用甲醇超声溶解,吸取上清液采用气相色谱-质谱（GC-MS）联用仪检测。结果测得A组分（t R=19.47min）的质谱特征碎片峰（m/z）信息为215.1（基峰）、144.9、294.1、337.1和365.1,B组分（tR=23.29min）的质谱特征碎片峰（m/z）信息为359.1（基峰）、127.1、144.0、155.0、232.1、284.1和342.0。经美国缉毒署毒品分析谱库检索获得的信息资料,鉴定为新型策划毒品＂K3＂,其主要组分为＂AKB48＂和＂AM2201＂,此类化合物具有大麻类似精神活性,归属合成大麻素。结论本方法可用于新型策划毒品组分的鉴定。     

MDMA前体PMK methyl glycidate的定性检验

目的利用PMK methyl glycidate来合成胡椒基甲基酮(piperonyl methyl ketone,PMK),可进一步合成3,4-亚甲二氧基甲基苯丙胺(MDMA)。本文首次报道了中国大陆出现的PMK methyl glycidate,并应用气相色谱-质谱联用(GC-MS)和核磁共振(NMR)技术对化合物结构进行了分析与确证。方法样品分别用甲醇和DMSO-d₆提取后,使用GC-MS和NMR进行检测。结果通过GC-MS分析测得化合物的质谱特征碎片和保留时间信息,并对氢谱碳谱的信号峰进行归属,确定了化合物结构。结论该方法简便可靠,能用于PMK methyl glycidate的检验。     

合成大麻素类新精神活性物质4F-MDMB-BICA的检测

目的建立基于红外光谱(fourier transform infrared,FT-IR)、气相色谱-质谱联用(gas chromatographymass spectrometry,GC-MS)、高分辩质谱(high resolution mass spectrometer,HRMS)和核磁共振波谱(nuclear magnetic resonance spectroscopy,NMR)多技术联用鉴定可疑未知物的方法。方法样品分别用FT-IR、GC-MS、HRMS(溶剂为甲醇)及NMR(溶剂为氘代甲醇)检测。结果GC-MS测得样品中主要组分的质谱特征离子m/z分别为218(基峰)、362、306、274、246、144、116,HRMS实测的精确质量数[M+H]+为363.20774,经FT-IR、GC-MS和HRMS数据分析,推断未知样品为一种新的合成大麻素类新精神活性物质4F-MDMB-BICA,并用1H NMR对其结构进行确证。结论建立的多技术联合鉴定方法能用于未知样品中4F-MDMB-BICA的鉴定。该方法快速、方便、准确、可靠、实用,能够对今后涉及此类物质的案件检测鉴定提供参考依据。     

5F-UR-144的热不稳定性研究

目的利用气相色谱-质谱法(GC-MS)、液相色谱-四级杆-飞行时间质谱(LC-Q-TOF/MS)和核磁共振光谱法(NMR)研究合成大麻素5F-UR-144遇热分解的具体变化情况。方法对照品用无水乙醇定容稀释后,经GC-MS和LC-Q-TOF/MS检测得到对应的色谱图和质谱图;对照品分别于常温和280℃密封加热后用无水乙醇定容稀释,经LC-Q-TOF/MS和NMR检测得到对应的质谱图、¹H和¹³C核磁共振波谱;对照品分别于常温逐步提升至300℃密封加热后用无水乙醇定容稀释,经LC-Q-TOF/MS检测得到对应的色谱图。结果5F-UR-144在高温下会开环产生新的物质;5F-UR-144从130℃开始分解,随着温度升高分解程度提升,240℃时分解率达到98%;随着温度继续升高,超过260℃,分解产物会碳化。结论基于5F-UR-144的热不稳定性,在检测时应考虑若通过烫食方式吸食5F-UR-144,其进入人体的成分会发生变化;气相色谱或气相色谱-质谱法不适合定量检测5F-UR-144。     

新型合成大麻素ADB-BUTINACA的波谱分析及结构确证

本文旨在对新型氨基烷基吲哚类合成大麻素ADB-BUTINACA进行结构确认。对缴获的电子烟油经柱层析法提取纯化后，用气相色谱-质谱(GC-MS)、高效液相色谱-四极杆串联飞行时间质谱(UPLC-QTOF)、核磁共振(¹H-NMR、¹³C-NMR)、红外光谱(IR)进行分析，确定化合物结构式。通过UPLC-QTOF获得未知化合物的精确质量数为330.212 7，结合¹H-NMR确定质子数为26及其归属，¹³C-NMR确定碳的类型，GC-MS及UPLC-QTOF二级质谱裂解碎片离子为m/z 286.2、201.1(基峰)、145.0、257.1推断其结构可能断裂路径，IR的吸收特征确定其含有苯环、酰胺、伯胺、仲胺、叔胺、甲基及偕二甲基等官能团，确认该化合物分子式为C₁₈H₂₆N₄O₂，化学名称为N-(1-amino-3,3-dimethyl-1-oxobutan-2-yl)-1-butyl-1H-indazole-3...     

利用高分辨液质联用仪检测新型合成大麻素

目的介绍一种鉴别非法合成大麻素(AMB-FUBINACA)结构的方法。方法巧用GC-MS质谱谱库检索提示信息,利用高分辨液质联用仪的一级质谱碎片推导的分子式与GC-MS的质谱谱库检索物质的分子式进行比较,推测目标物的结构式。目标物的结构式符合液质联用仪(LC-MS/MS)的二级质谱碎片(误差4×10-7)和GC-MS的质谱碎片归属,并结合文献报道进行综合研判。结果对一例网络售卖合成大麻素的案件进行了检验,准确判定缴获样品“小树枝”中含有的合成大麻素为AMB-FUBINACA。结论该方法可为解析一些未知物的结构提供新途径。     

Electron impact mass spectrometric detection of Freon in biological specimens.

Freons from an aerosol spray can were detected in the blood, liver, brain, and lung of a 14-year-old girl who died after intentional inhalation. A headspace mass spectrometric analytical technique was employed to detect the fluorocarbons. The spectra from the specimens showed the presence of m/e peaks at 101, 103, and 105 from the ion (CFCL2)+ which arises from fragmentation of trichlorofluoromethane (Freon 11) and dichlorodifluoromethane (Freon 12), and peaks at 85 and 87 from the ion (CF2Cl)+ which arises from fragmentation of dichlorodifluoromethane (Freon 12). The technique presented here provides greater specificity than previously reported analytical procedures for the identification of these volatile toxic chemical compounds in biological specimens.     

Positive- and negative-ion mass spectrometry and rapid clean-up of 19 phenothiazines

Positive-ion electron impact (PIEI), positive-ion chemical ionization (PICI) and negative-ion chemical ionization (NICI) mass spectra of 19 phenothiazines are presented. In the PIEI mode, peaks due to M, M minus side chain (M - R1), M - R1 + H, and side chain itself (R1) appeared for most compounds. The M - R1 and R1 ions were very useful for drug screening. In the PICI mode, most spectra showed base or intense peaks due to M + H, and small peaks due to M + C2H5; peaks due to M - R1 + 2H and R1 also appeared in many compounds. In the NICI mode, fragmentation modes were different in different compound groups; molecular or [M - H]- quasi-molecular anions appeared in many compounds with aliphatic side chains. Anions at m/z 98 and 115 were characteristic for compounds with (N-methylpiperazinyl)propyl side chains. Selected ion monitoring in the PIEI mode generally gave much higher sensitivity than in the PICI and NICI modes. Phenothiazines present in urine or plasma could be rapidly isolated by use of Sep-Pak C18 cartridges. Thirteen of 19 phenothiazines could be detected by HP-17 wide-bore capillary gas chromatography with satisfactory separation from impurities in their underivatized forms.     

Positive and negative ion mass spectrometry of antiepileptic hydantoins and their analogs

Positive ion electron impact (PIEI), positive ion chemical ionization (PICI), and negative ion chemical ionization (NICI) mass spectra of seven compounds of hydantoins and their analogs are presented; their probable fragmentation modes are also presented. In the PIEI mode, intensities of molecular ions differed according to different compounds. Cleavage at outsides of both carbonyl groups was commonly observed for all compounds. In the PICI mode, all compounds showed [M + 1]+ quasi-molecular ions constituting the base peaks. In the NICI mode, [M - 1]- quasi-molecular anions were the base peaks except for trimethadione and paramethadione. All negative spectra showed anions at m/z 42 due to [NCO]-; these peaks seem useful for screening of antiepileptics. An extraction procedure for the anti-epileptics from human urine or plasma, and their separation by gas chromatography (GC), are also presented to serve for their actual identification by GC/mass spectrometry.     

A detailed mechanistic fragmentation analysis of methamphetamine and select regioisomers by GC/MS

A novel ring-substituted methamphetamine regioisomer, N,alpha,4-trimethyl phenmethylamine, was synthesized in order to study the validity of proposed structures for various mass spectrometry (MS)-derived peaks in a methamphetamine fragmentation pattern. While other research efforts have studied aspects of methamphetamine in detail, a full fragmentation study has not been reported previously. In addition to showing molecular structures represented by fragment peaks, mechanisms for selected processes are detailed. An empirically derived procedure to easily determine by simple spectral peak pattern recognition the geometry of dimethyl- or ethyl-substituted immonium ions (RRC = N+ RR) where m/z = 58 is outlined. These results are platform independent for electron ionization (EI) instruments, but have also proven to be helpful in explaining spectral peaks observed in spectra from ion trap systems. The spectrum for the synthesized methamphetamine regioisomer was accurately predicted using this methodology. While this approach is useful in some casework, the converse may be more useful: when an unexpected or unusual peak pattern arises in a spectrum, being able to analyze it to determine the structure of the molecule. This paper gives an analyst the means to begin such retro-synthetic analyses.     

Qualitative and quantitative analysis of seized street drug samples and identification of source

In this paper we describe the identification of constituents of the illicit drugs seized from different regions of eastern India by GC-MS. The constituents were identified to be heroin, acetyl morphine, morphine and acetyl codeine. Quantitative estimation of the constituents were made by GC-MS and HPTLC. In view of non-availability of the authentic samples of drugs of different origin, nothing positive can be said about the origin of illicit drug samples. The possibility of isotopic substitution, an important method for identification of source, was examined from the comparison of the intensity of different (ion) peaks 369 (heroin, m/z=369), 370, 371 and 372 using selective ion monitoring mode. No isotopic substitution in the constituents was observed. Attempts were made to identify the source of the illicit samples from heroin/acetylcodeine ratios in the way described in the literature.