4-取代-3-烷基-4,5-二氢-1-(3-氯-4-氟苯基)-1,2,4-三唑-5-酮的合成及生物活性

为寻找活性强、作用时间长的新型非肽类血管紧张素II AT₁受体拮抗剂, 从易得原料3-烷基-4,5-二氢-1-(3-氯-4-氟苯基)-1,2,4-三唑-5-酮出发, 经过N-烃化反应、1,3-偶极反应、氢解、水解和酰化等反应, 合成得到一系列4-取代-3-烷基-4,5-二氢-1-(3-氯-4-氟苯基)-1,2,4-三唑-5-酮类衍生物, 总收率为58%～87%, 其结构经IR, ¹H NMR, MS和元素分析确证. 初步药理试验结果表明: 所有目标化合物均有一定的AT₁受体拮抗活性, 其中化合物12d抑制AII诱导的兔主动脉环收缩的IC₅₀值为4.0×10^－9 mol/L, 与阳性药坎地沙坦(candesartan)相当, 具有进一步的研究意义.     

1-乙基-4-氧-7-甲基-1,8-萘啶-3-羧酸的合成

乙基氧甲基萘啶羧酸;缩合反应;成环反应;乙基化反应;水解反应;光谱特征     

3-甲基-1-戊烯-4-炔-3-醇的合成

以甲基乙烯酮为原料,用乙炔基格氏试剂对其加成,然后水解得到目标物3-甲基-1-戊烯-4-炔-3-醇。研究了温度对反应的影响,发现在25℃的反应温度下,目标化合物的气相色谱产率为50%,减压蒸馏纯化后收率为30%。目标产物用1HNMR、IR进行了表征。     

2-乙氧羰基-3-溴-4-甲基-5-甲酰基-吡咯的合成

2-乙氧羰基-3-溴-4-甲基-5-甲酰基-吡咯的合成;乙氧羰基二甲基吡咯;乙氧羰基溴二甲基吡咯;乙氧羰基溴甲基甲酰基吡咯     

1-芳基-2-苯基-3-甲基-3-异丙基-2-氧代-1,4,2-二氮磷杂环戊-5-酮的合成及除草活性

利用取代苯基脲与苯基二氯化膦和3-甲基-2-丁酮进行的类Mannich反应合成了15种新的1,4,2-二氮磷杂环戊-5-酮类化合物(2a_2o), 其结构经     

3β-羟基-24-降胆-5-烯-23-酸的合成

以妊娠双烯醇酮醋酸酯为起始原料, 经过6步反应以28.2%的总收率, 合成了具有抗炎活性的海洋天然产物3β-羟基-24-降胆-5-烯-23-酸. 关键反应为钯催化的烯丙基烷基化.     

6-溴-7-异丙基-1,10-二甲基-1,2,3,4-四氢蒽-1-羧酸的合成

以脱氢松香酸为原料,经酯化、溴代、氧化、异构化、水解等反应,合成了一种新型的四氢蒽羧酸类衍生物———6-溴-7-异丙基-1,10-二甲基-1,2,3,4-四氢蒽-1-羧酸,其结构经1H NMR,13C NMR,MS和元素分析表征。     

3-氨基-5-取代苯氨基-6-苯基-1,2,4-三嗪的合成

3-氨基-1,2,4-三嗪化合物具有广泛的生理活性,如:治疗支气管扩张、抑制乳酸菌和症原虫繁殖杀菌等,因此,研究这类化合物合成方法应运而生。本文以苯甲酰基硫代甲酰胺为原料,进一步合成了氨基-5-取代苯氨基-6-苯基-1,2,4-三嗪。     

1-苯基-5-芳基-1,2-二氢-1,2,4-三唑-3-硫酮的合成

将取代苯甲酰氯1a～1f与硫氰酸钾反应, 得到的中间体不需纯化直接与苯肼反应, 成功地合成了1-苯基-5-芳 基-1,2-二氢-1,2,4-三唑-3-硫酮(2a～2f). 化合物2的结构通过红外光谱、核磁共振光谱和高分辨质谱进行了表征.     

3,3-二甲基-9-(5,5-二甲基-3-羟基-2-环己烯-1-酮-2-基)-1-氧代-2,3,4,9-四氢化氧杂蒽的合成和晶体结构

标题化合物C23H26O4是由水杨醛与5，5-二甲基-1，3-环己二酮在N，N-二甲基甲酰胺中反应而得．结构通过单晶X-射线行射法确定，其晶体属于单料晶系，空间群P21/c，a=7．056（7），b=20.263（3），c=13．665（2）A，β＝93．32（1）°，V=1950．7（4）A3，Mr=366．46，Dc=1.248g／cm3，Z=4，μ（MoKa）=0．84cm－1，F（000）=784。晶体结构用直接法解出，经全矩阵最小二乘法对原子参数进行修正，最后的偏离因子R=0．068，Rw=0．075。晶体结构分析结果表明，分子中存在一个共轭的烯醇式结构。     

Determination of patulin in apple juice by high-performance liquid chromatography-atmospheric pressure chemical ionization mass spectrometry

An HPLC-MS-MS method with selected reaction monitoring (SRM) for the determination of patulin in apple juice samples is described. Mass spectrometric detection was accomplished following atmospheric pressure chemical ionization (APCI) in both positive and negative ion modes. Collision induced dissociation (CID) of the protonated molecular ion led initially to the loss of H2O (fragment m/z 137). At higher energies CO is lost from both the protonated parent molecule (fragment m/z 127) and the dehydrated molecular ion (fragment m/z 109). In contrast, CID of the deprotonated molecular ion led initially to the fragment at m/z 109 corresponding to the loss of either CO2 or acetaldehyde, followed at higher CID energy by the loss of H2O (fragment m/z 135) and CO (fragment m/z 125) from the deprotonated molecular ion. Detection in the negative ion mode proved superior and a linear response was observed over the injected range from 6 to 200 ng patulin. Apple juice samples spiked with patulin between 10 and 135 microg/l were analyzed following liquid-liquid extraction with ethyl acetate and clean up with sodium carbonate. Utilizing reversed-phase HPLC with acetonitrile-water (10:90) at 0.5 ml/min, levels down to 10 microg/l were readily quantified and a detection limit of 4 microg/l was attainable at a signal-to-noise (SIN) ratio of 4. The MS data for the spiked samples compared well to the UV data and when plotted against each other displayed a correlation coefficient (R) of 0.99.     

Characterization of 4-Aryl-5-ethoxycarbonyl-6-methyl-3,4-dihydro- pyrimidin-2 （1H）-thiones by EI-TOF Mass Spectrometry

IntroductionIn1893,Pietro Biginelli reported the first synthe-sis(termed the Biginelli reaction)of3,4-dihydropyrim-idinone(denoted as“oxo-orO-Biginelli compound”in-cluding its derivatives,type A in Scheme1).In thelast decade,interest in these compounds …     

Identification of linoleic acid free radicals and other breakdown products using spin trapping with liquid chromatography-electrospray tandem mass spectrometry

Linoleic acid radical products formed by radical reaction (Fenton conditions) were trapped using 5,5-dimethyl-1-pyrrolidine-N-oxide (DMPO) and analysed by reversed-phase liquid chromatography coupled to electrospray mass spectrometry (LC-MS). The linoleic acid radical species detected as DMPO spin adducts comprised oxidized linoleic acid and short-chain radical species that resulted from the breakdown of carbon and oxygen centred radicals. Based on the m/z values, the short-chain products were identified as alkyl and carboxylic acid DMPO radical adducts that exhibited different elution times. The ions identified as DMPO radical adducts were studied by liquid chromatography-tandem mass spectrometry (LC-MS/MS). The LC-MS/MS spectra of linoleic acid DMPO radical adducts exhibited the fragment ion at m/z 114 and/or the loss of neutral molecule of 113 Da (DMPO) or 131 Da (DMPO + H2O), indicated to be DMPO adducts. The short-chain products identified allowed inference of the radical oxidation along the linoleic acid chain by abstraction of hydrogen atoms in carbon atoms ranging from C-8 to C-14. Other ions containing the fragment ion at m/z 114 in the LC-MS/MS spectra were attributed to DMPO adducts of unsaturated aldehydes, hydroxy-aldehydes and oxocarboxylic acids. The identification of aldehydic products formed by radical oxidation of linoleic acid peroxidation products, as short-chain product DMPO adducts, is a means of identifying lipid peroxidation products.     

Unimolecular dissociation reactions of methyl benzoate radical cation

The blackbody infrared radiation induced dissociation of methyl benzoate (C8H8O2(+*)) radical cation was investigated by using a Fourier transfer ion cyclotron resonance mass spectrometer equipped with a resistively heated (wire temperatures of 400-1070 K) wire ion guide. We observed product ion branching ratios that are strongly dependent upon wire temperature. At low temperatures (670-890 K) the major product ion C7H8 (+*) (m/z 92), which is formed by loss of CO2, and at higher temperatures (above 900 K), loss of methoxy radical ((*)OCH3) competes with loss of CO2. The energies of the various reactant ions and transition states for product ion formation were estimated by using density functional theory molecular orbital calculations, and a proposed mechanism for the dissociation chemistry of C8H8O2 (+*) involving a multistep rearrangement reaction is tested using the Master Equation formalism.     

Analysis of FeII-mediated decomposition of a linoleic acid-derived lipid hydroperoxide by liquid chromatography/mass spectrometry

Intracellular Fe(II), which is up-regulated during oxidative stress and during iron overload, induces the formation of a hydroxyl radical by Fenton chemistry. The hydroxyl radical can convert the prototypic omega-6 polyunsaturated fatty acid, linoleic acid, to 13-hydroperoxy-9,11-(Z,E)-octadecadienoic acid (13-HPODE). Cyclooxygenases can also convert linoleic acid to 13(S)-HPODE during oxidative stress. Subsequent Fe(II)-mediated decomposition to protein- and DNA-reactive bifunctional electrophiles was examined by normal-phase liquid chromatography (LC)/atmospheric pressure chemical ionization (APCI)/mass spectrometry. The potential individual bifunctional electrophiles trans-4,5-epoxy-2(E)-decenal (EDE), cis-EDE, 4-oxo-2(E)-nonenal (ONE) and 4-hydroxy-2(E)-nonenal (HNE) exhibited protonated molecular ions at m/z 169, 169, 155 and 157, respectively. The MH(+) ion at m/z 173 for 4-hydroperoxy-2(E)-nonenal (HPNE) was very weak with an ion corresponding to the loss of OH at m/z 156 as the major ion in the APCI mass spectrum. The bifunctional electrophiles were all separated under normal-phase LC conditions. Interestingly, ions corresponding to ONE and HNE were detected at the same retention time as HPNE, suggesting that it decomposed in the source of the mass spectrometer to ONE and HNE. All five bifunctional electrophiles were formed when 13-HPODE was treated with 50 microM Fe(II). At this concentration of Fe(II), the addition of vitamin C resulted in increased bifunctional electrophile formation. At higher concentrations of Fe(II) (500 microM to 2 mM), no HPNE was detected and there was no additive effect of vitamin C. Additional experiments with synthetic HPNE revealed that it was quantitatively converted to a mixture of ONE and HNE by Fe(II). The HNE is thought to arise from a one-electron reduction of an alkoxy radical derived from HPNE. In contrast, ONE can arise through an alpha-cleavage of the HPNE-derived alkoxy radical or by direct dehydration of HPNE.     

Studies on the formation of N-methylperfluoroalkylnitrile cations from perfluoroacylphenethylamines in electron ionisation mass spectrometry: unique marker ion fragments in methamphetamine analysis

The mass spectra of the perfluoroacyl derivatives of methamphetamine show a unique and characteristic fragment ion identified as the N-methylperfluoroalkylnitrile cation (C(n)F(2n+1)CNCH(3))(+). This ion appears at various m/z values depending on the nature of the perfluoroacyl species and is generated via rearrangement of the perfluoroacyl immonium fragment formed by loss of the benzyl-radical from the molecular ion. Analogous ions have been described in the mass spectra of other methamphetamine-like side chain substances regardless of the aromatic ring substitution pattern. The scope and limitation of this rearrangement pathway were evaluated in this study by preparing a set of substituted phenethylamines and related compounds of varying structure. The perfluoroacyl moiety leads to the formation of the highest abundance of the N-methyl nitrile cation fragment while hydrocarbon acyl groups do not show the N-methylnitrile cation as a significant peak. The N-methyl group is required for the formation of the N-methyl nitrile cation and higher N-alkyl homologues eliminate the corresponding alkene species from the acyl immonium fragment. The loss of benzaldehyde and acetone from the perfluoroacylimmonium species produces the highest relative abundance of the unique N- methylperfluoroalkylnitrile cation.     

Detection and characterization by mass spectrometry of radical adducts produced by linoleic acid oxidation

The formation of linoleic acid radical species under the oxidative conditions of the Fenton reaction (using hydrogen peroxide and Fe (II)) was monitored by FAB-MS and ES-MS using the spin trap 5,5-dimethyl-1-pyrrolidine-N-oxide, DMPO. Both the FAB and ES mass spectra were very similar and showed the presence of ions corresponding to carbon- and oxygen centered spin adducts (DMPO/L*, DMPO/LO*, and DMPO/LOO*). Cyclic structures, formed between the DMPO oxygen and the neighboring carbon of the fatty acid, were also observed. Electrospray tandem mass spectrometry of these ions was performed to confirm the proposed structure of these adducts. All MS/MS spectra showed an ion at m/z 114, correspondent to the [DMPO + H]+, and a fragment ion due to loss of DMPO (loss of 113 Da), confirming that they are DMPO adducts. ES-MS/MS spectra of alkoxyl radical adducts (DMPO/LO*) showed an additional ion at m/z 130 [DMPO - O + H]+, while ES MS/MS of peroxyl radical adducts (DMPO/LOO*) showed a fragment ion at m/z 146 [DMPO - OO + H]+, confirming both structures. Other fragment ions were observed, such as alkyl acylium radical ions, formed by cleavage of the alkyl chain after loss of water and the DMPO molecule. The identification of fragment ions observed in the MS/MS spectra of the different DMPO adducts suggests the occurrence of structural isomers containing the DMPO moiety both at C9 and C13. The use of ES tandem mass spectrometry, associated with spin trapping experiments, has been shown to be a valuable tool for the structural characterization of carbon and oxygen-centered spin adducts of lipid radicals.     

Thermochemistry of N-N containing ions: a threshold photoelectron photoion coincidence spectroscopy study of ionized methyl- and tetramethylhydrazine

The unimolecular dissociation reactions of the methylhydrazine (MH) and tetramethylhydrazine (TMH) radical cations have been investigated using tandem mass spectrometry and threshold photoelectron photoion coincidence spectroscopy in the photon energy ranges 9.60-31.95 eV (for the MH ion) and 7.74-29.94 eV (for the TMH ion). Methylhydrazine ions (CH3NHNH2(+*)) have three low-energy dissociation channels: hydrogen atom loss to form CH2NHNH2(+) (m/z 45), loss of a methyl radical to form NHNH2(+) (m/z 31), and loss of methane to form the fragment ion m/z 30, N2H2(+*). Tetramethylhydrazine ions only exhibit two dissociation reactions near threshold: that of methyl radical loss to form (CH3)2NNCH3(+) (m/z 73) and of methane loss to form the fragment ion m/z 72 with the empirical formula C3H8N2(+*). The experimental breakdown curves were modeled with Rice-Ramsperger-Kassel-Marcus theory, and it was found that, particularly for methyl radical loss, variational transition state theory was needed to obtain satisfactory fits to the data. The 0 K enthalpies of formation (delta(f)H0) for all fragment ions (m/z 73, m/z 72, m/z 45, m/z 31, and m/z 30) have been determined from the 0 K activation energies (E0) obtained from the fitting procedure: delta(f)H0[(CH3)2NNCH3(+)] = 833 +/- 5 kJ mol(-1), delta(f)H0 [C3H8N2(+*)] = 1064 +/- 5 kJ mol(-1), delta(f)H0[CH2NHNH2(+)] = 862 +/- 5 kJ mol(-1), delta(f)H0[NHNH2(+)] = 959 +/- 5 kJ mol(-1), and delta(f)H0[N2H2(+*)] = 1155 +/- 5 kJ mol(-1). The breakdown curves have been measured from threshold up to h nu approximately 32 eV for both hydrazine ions. As the photon energy increases, other dissociation products are observed and their appearance energies are reported.     

Gas-phase reactions for selective detection of the explosives TNT and RDX

Highly selective gas-phase reactions with ethyl vinyl ether (EVE) of major electron (EI) and chemical ionization (CI) fragment ions of the explosives TNT and RDX have been uncovered. The fragment ion of m/z 210 from TNT undergoes [4(+)+ 2] cycloaddition with EVE to form an oxo-iminium ion of m/z 282, which dissociates by acetaldehyde loss after a [1,5-H] shift to form a quinolynium ion of m/z 238. The fragment ion of m/z 149 from RDX reacts with EVE by a formal vinylation reaction, that is, the elusive cyclic adduct loses ethanol to yield a nitro-iminium ion of m/z 175, which reacts further with EVE to form a second cyclic product ion of m/z 247. Calculations and MS/MS experiments support the proposed structures. These highly characteristic reactions of diagnostic EI and CI fragment ions improve selectivity for TNT and RDX detection.     

Radical identification by liquid chromatography/thermospray mass spectrometry

Radical adducts of 5,5-dimethyl-1-pyrroline N-oxide (DMPO) with hydroxyl, methanol-derived, and ethanol-derived radicals were detected by a combination of liquid chromatography with either electron paramagnetic resonance or thermospray mass spectrometry (LC/EPR or LC/TSP-MS) in the Fenton system (with methanol or ethanol). One radical adduct was observed in the reaction of DMPO with the hydroxyl radical or the methanol-derived radical, while two adducts were detected in the reaction of DMPO with ethanol-derived radicals. The LC/TSP-MS spectra showed quasi-molecular ions [M + H]+ at m/z 146 and m/z 160 for the methanol-derived and ethanol-derived radical adducts, respectively, and an apparent molecular ion M+ at m/z 130 for the hydroxyl radical adduct. Use of methyl-D3 alcohol (CD3OH) and ethyl-D5 alcohol (CD3CD2OH) indicated that carbon-centered radicals are formed. Experiments with partially deuterated ethanol (CD3CH2OH and CH3CD2OH) indicated that the two adducts observed in the reaction of DMPO with ethanol-derived radicals correspond to the two diastereomeric adducts of DMPO with the alpha-hydroxyethyl free radical.