阳极氰化反应的研究进展

本文综述了近30年来阳极氰化反应在有机电合成中的应用,主要回顾了阳极氰化胺、阳极氰化杂环化合物和阳极氰化芳香化合物的研究.此外,还报道了乳化技术在阳极氰化反应中的应用.     

3-(3＇-乙酰基-5＇-芳基-1＇,3＇,4＇-二氢噁二唑-2＇-)色酮的微波促进合成

将微波应用于促进有机合成是近年来兴起的新技术,已受到极大注意,我们采用简单的微波反应装置,成功地合成了3－杂环基取代的色酮,杂环基取代的色酮因其显著的生理活性,而成为近年来的研究特点,以3－甲酰基色酮为原料,与芳酰肼反应得到相应的芳酰腙,再用乙酸酐关环,合成了一系列3位为1,3,4－二氢恶二唑基取代的色酮（3）,为在合适的母体上引入杂环提供了一系新思路,合成路线如下。     

3-杂环基硫取代-1,3,4,5-四氢-2-氧代-苯并氮杂衍生物的合成

以芳酰肼为原料,合成了一系列3-巯基-5-芳基-1,2,4-三唑、2-巯基-5-芳基-1,3,4-噁二唑和2-巯基-5-芳基-1,3,4-噻二唑,并通过硫原子对3-溴-2-氧代-苯并氮杂3-位上的亲核取代反应将杂环化合物引入了苯并氮杂的结构当中,合成了32个新的苯并氮杂杂环衍生物.为提高其在有机溶剂中的溶解性,在苯并氮杂的N原子上引入乙酸乙酯和乙酸叔丁酯基取代基,合成了36个新衍生物.所有化合物经质谱、核磁共振谱及元素分析确证了结构并初步测定了抗菌活性.     

3-杂环基硫取代-1,3,4,5-四氢-2-氧代-苯并氮杂衍生物的合成

以芳酰肼为原料, 合成了一系列3-巯基-5-芳基-1,2,4-三唑、2-巯基-5-芳基-1,3,4-噁二唑和2-巯基-5-芳 基-1,3,4-噻二唑, 并通过硫原子对3-溴-2-氧代-苯并氮杂3-位上的亲核取代反应将杂环化合物引入了苯并氮杂的结构当中, 合成了32个新的苯并氮杂杂环衍生物. 为提高其在有机溶剂中的溶解性, 在苯并氮杂的N原子上引入乙酸乙酯和乙酸叔丁酯基取代基, 合成了36个新衍生物. 所有化合物经质谱、核磁共振谱及元素分析确证了结构并初步测定了抗菌活性.     

超声促进2-磺酰基氮杂环化合物的合成研究

探索了一种超声促进合成2-磺酰基氮杂环化合物的反应.以氮杂环氮氧化物和亚磺酸为原料,以三吡咯烷基溴化鏻六氟磷酸盐(Py Bro P)为催化剂,室温下超声反应1.0 h,能够以良好的收率得到2-磺酰基氮杂环化合物.该反应具有底物适用性好,反应时间短,反应产率高等优点,为高效合成2-磺酰基氮杂环化合物及其衍生物提供了一种新的途径.     

多聚氮杂环的脱氮自由基转化:C−N键的构建研究进展

多聚氮杂环化合物在有机合成、药物化学以及材料化学等领域具有重要的作用.人们已经在多聚氮杂环的修饰和可控转换领域取得了诸多突破性的研究成果.在多种多聚氮杂环转换反应中,脱氮是一类重要反应,可以快速地构建其他氮杂环或者C?N键.通常而言,多聚氮杂环化合物更易于脱氮形成金属卡宾中间体,继而发生后续串联或环化反应,但涉及自由基中间体的多聚氮杂环脱氮反应尚未得到充分关注和研究.在过去几年中,得益于现代合成手段如有机光化学合成、有机电化学合成和有机光电合成等的革新,自由基化学得到快速发展,建立了很多多聚杂环脱氮自由基串联反应,为高度复杂的杂环骨架或具有复杂杂环体系的天然产物提供了一条通用且便捷的合成路径.光催化剂在有效地将可见光中的能量转移至非吸收化合物方面的应用越来越受到关注,该方法可温和而有效地生成自由基,以新的方式形成化学键.此外,啉钴与卟啉铁催化剂在多聚杂环的脱氮反应中亦展现出较好的催化性能.本文综述了多聚氮杂环的脱氮自由基转化(C?N键的构建)领域的最新进展,重点讨论了脱氮生成自由基的方法与串联模式和反应机理,分析了存在的挑战.本文还根据反应底物的类别从四个模块展开讨论:(1)苯并三嗪和苯并噻三嗪的自由基脱氮串联反应;(2)苯并三氮唑的自由基脱氮串联反应;(3)吡啶三氮唑与四氮唑的脱氮反应;(4)3-氨基吲唑的自由基脱氮反应.综上,研究者们通过多聚氮杂环的脱氮自由基转化(C?N键的构建)的方法合成了一些重要的药物分子及其前体,并证明了该方法具有潜在的应用价值.未来,将多聚氮杂环脱氮反应应用于活性天然产物合成与修饰是非常可行的.     

2,5-取代-1,3,4-噁二唑衍生物的合成与杀菌活性

利用生物活性亚结构拼接原理,将吡啶环、噻唑环引入到1,3,4-噁二唑母体结构中,设计并合成了一系列新型含吡啶(噻唑)的1,3,4-噁二唑衍生物.通过IR,1H NMR,EI-MS及元素分析等方法对所合成的化合物进行了结构表征.代表化合物2-(6-氯吡啶-3-甲硫基)-5-(吡啶-4-基)-1,3,4-噁二唑(I)经单晶X衍射证实了结构.初步测定了所合成化合物的杀菌活性,并比较了在1,3,4-噁二唑母体结构中引入噻唑杂环和引入吡啶杂环后其杀菌活性的差异.结果表明:目标化合物对测试的5种菌均具有一定的杀菌活性,对水稻纹枯病的抑制效果普遍优于对其它菌种的抑制效果;在1,3,4-噁二唑母体结构中引入噻唑杂环比引入吡啶杂环对其杀菌活性更有利.     

CuI催化无溶剂一锅法合成苯二氮酮类化合物

含苯二氮?酮母核的化合物是一类具有重要生理活性的有机杂环化合物.以邻溴代苯甲酸乙酯和邻二胺类化合物为原料,在无溶剂状态下,通过Cu I催化偶联并进一步内酰胺化关环,一锅法合成了目标化合物.该方法绿色环保、反应条件温和、操作简便、一步反应且收率较高.通过最优的反应条件下,研究了一系列不同芳香环取代基对反应的影响,并验证了此方法能用于不同取代芳香二氮?酮类化合物的合成.在此基础上,将此合成方法应用于一些含有苯二氮?酮结构的生物活性化合物的合成,并取得满意的结果.     

米氏酸在杂环化合物合成中的应用研究进展

综述了近年来米氏酸在杂环化合物合成中的应用,涉及到吡喃环、吡啶环、呋喃环、吡咯环、噁唑环和异噁唑环重要杂环的形成.大多具有反应条件温和、便利、产率较高等优点.     

2-甲基氮杂环丙烷与CO_2的环加成反应

采用碱金属卤化物和季铵盐作为催化剂在温和条件下催化2-甲基氮杂环丙烷的CO2环加成反应,得到区域选择性的4-甲基-2-噁唑烷酮.实验结果表明,该合成路线具有反应条件温和、收率高、区域选择性好、操作简单、对环境安全友好等特点.     

Anodic cyanation of 1‐arylpyrroles

The electrooxidation of several 1‐arylpyrroles has been carried out in methanol containing sodium cyanide at a platinum anode in a divided cell. In all instances, replacement of a heteroaromatic hydrogen by a cyano group occurred. On the basis of electroanalytical results, the anodic cyanation of the title compounds could be designed an EC process. As a result of two‐electron oxidation, the corresponding pyrrole cyanides were obtained in yields ranging from 76‐85%. The advantages of electrochemistry synthesis of pyrrole cyanides are simple reaction condition, low cost and high purity products.     

Regio- and stereodirection of addition of tetrazole to α,β-acetylenic γ-hydroxy nitrile: synthesis of 1- and 2-(<Emphasis Type="Italic">Z</Emphasis>)-(2-cyanoethenyl- 1-hydroxyalkyl)tetrazoles

Using the example of the reaction of tetrazole with 4-hydroxy-4-methyl-2-pentynonitrile, conditions were found under which (Z)-4-hydroxy-4-methyl-3-(1H-tetrazol-1-yl)2-pentenonitrile was formed by regio- and stereoselective addition at atom N(1) of tetrazole (yield 85%, selectivity 95%).     

Nitration Products of 5‐Amino‐1H‐tetrazole and Methyl‐5‐amino‐1H‐tetrazoles – Structures and Properties of Promising Energetic Materials

The nitration of 5‐amino‐1H‐tetrazole ( 1 ), 5‐amino‐1‐methyl‐1H‐tetrazole ( 3 ), and 5‐amino‐2‐methyl‐2H‐tetrazole ( 4 ) with HNO₃ (100%) was undertaken, and the corresponding products 5‐(nitrimino)‐1H‐tetrazole ( 2 ), 1‐methyl‐5‐(nitrimino)‐1H‐tetrazole ( 5 ), and 2‐methyl‐5‐(nitramino)‐2H‐tetrazole ( 6 ) were characterized comprehensively using vibrational (IR and Raman) spectroscopy, multinuclear (¹H, ¹³C, ¹⁴N, and ¹⁵N) NMR spectroscopy, mass spectrometry, and elemental analysis. The molecular structures in the crystalline state were determined by single‐crystal X‐ray diffraction. The thermodynamic properties and thermal behavior were investigated by using differential scanning calorimetry (DSC), and the heats of formation were determined by bomb calorimetric measurements. Compounds 2, 5 , and 6 were all found to be endothermic compounds. The thermal decompositions were investigated by gas‐phase IR spectroscopy as well as DSC experiments. The heats of explosion, the detonation pressures, and velocities were calculated with the software EXPLO5, whereby the calculated values are similar to those of common explosives such as TNT and RDX. In addition, the sensitivities were tested by BAM methods (drophammer and friction) and correlated to the calculated electrostatic potentials. The explosion performance of 5 was investigated by Koenen steel sleeve test, whereby a higher explosion power compared to RDX was reached. Finally, the long‐term stabilities at higher temperatures were tested by thermal safety calorimetry (FlexyTSC). X‐Ray crystallography of monoclinic 2 and 6 , and orthorhombic 5 was performed.     

Synthesis and structures of 5-(pyridyl)tetrazole complexes of Mn(II)

New Mn(II) complexes containing 5-(2-pyridyl)tetrazole, 5-(3-cyano-4-pyridyl)tetrazole or 5-(4-pyridyl)tetrazole ligands are described. The complexes are prepared by reaction of the corresponding cyanopyridines with sodium azide in the presence of Mn(II) salts. All the complexes have been characterized by X-ray crystallography, which reveals that 5-(pyridyl)tetrazole ligands can coordinate to Mn through either type of nitrogen atom in the tetrazole residue or via the pyridyl group. In the solid state, extended 2D and 3D structures are produced through networks of hydrogen bonding (involving water molecules and the tetrazolate residue). Acidification of the complexes produces the corresponding free 5-(pyridyl)-1H-tetrazole.     

Synthesis of 5-{[(1-Aryl-1H-1,2,3-triazol-4-yl)methyl]sulfanyl}-1-phenyl-1H-tetrazoles

Russian Journal of Organic Chemistry - A series of novel 5-(1,2,3-triazolylmethylsulfanyl)tetrazole derivatives were synthesized by the click reaction from...     

Oxidation of 1-(4-nitrophenyl)-2-formylpyrrole

Pyrrole aldehydes interact with oxidizing agents to yield products which are oxidized to different degrees. Pyrrolecarboxylic acids are formed under the influence of silver oxides, an alkaline solution of permanganate, and 2–10% sulfuric acid [1–3]. With peroxidation of hydrogen, 5-unsubstituted pyrrole aldehydes convert to pyrrolone [4], and pyrrol-2-aldehyde converts to succinimide [5]. Chromacetate and chromium sulfuric acids oxidize pyrrole aldehydes to maleinimides [3].Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 4, pp. 495–499, April, 1982.     

Alkylation of tetrazoles with 3-(2-bromoethyl)-1-methoxy-3-methyltriaz-1-ene 2-oxide

Alkylation of tetrazoles with 3-(2-bromoethyl)-1-methoxy-3-methyltriaz-1-ene 2-oxide proceeded at positions 1 and 2 of the tetrazole ring to give a mixture of two isomers.

     

A short-cut from 1-acetyl adamantane to 2-(1-adamantyl)pyrroles

The oxime of 1-acetyl adamantane 2 is added to acetylene (KOH/DMSO, 70 °C, initial acetylene pressure 13 atm, 30 min) to afford the corresponding O-vinyl oxime 5 in 80% yield. The latter upon heating (DMSO, 120 °C, 1 h) gives 2-(1-adamantyl)pyrrole 3, 1-acetyl adamantane 1, and adamantane (6:3:1 mass ratio), the yield of the pyrrole 3 being 83% (based on 1-acetyl adamantane 1 consumed). Under harsher conditions (NaOH/DMSO, 130 °C, atmospheric pressure of acetylene, 4 h) oxime 2 reacts with acetylene to furnish pyrrole 3, 1-acetyl adamantane 1, 1-vinyl adamantane 9, and adamantane (6:7:3:1 mass ratio), with the isolated yield of pyrrole 3 reaching 34%. Under pressure (NaOH/DMSO, 120 °C, initial acetylene pressure 14 atm, 1 h) the same reaction leads to 2-(1-adamantyl)-1-vinylpyrrole 4 and ketone 1 in 48% (based on consumed ketone 1) and 24% yields, respectively. The pyrrole 4 is easily deprotected to the corresponding 1H-pyrrole 3 in 77% yield by treatment (aqueous MeCN) with Hg(OAc)₂ and NaBH₄.     

新型5-取代吲哚-3-甲酰胺化合物的合成

以5-取代吲哚为原料,经维尔斯迈尔-哈克反应制得5-取代吲哚-3-甲醛(2a~2e); 2a~2e在DMF催化下,与盐酸羟胺反应制得5-取代吲哚-3-甲腈（3a~3e）; 3a~3e在H₂O₂和NaOH溶液中水解合成了5-取代吲哚-3-甲酰胺（4a~4e, 4b~4e为新化合物）,产率62.0%~75.0%,其结构经¹H NMR, ¹³C NMR和ESI-MS表征。     

Synthesis and properties of 1-(2-hydroxyethyl)tetrazole

The heterocyclization of monoethanolamine with ethyl orthoformate and sodium azide in acetic acid was studied. It was shown that the reaction proceeds through a step involving the formation of a disubstituted formamidine and leads to the production of 1-(2-hydroxyethyl)tetrazole in high yield. A method for the purification of 1-(2-hydroxyethyl)tetrazole by complexing with cupric chloride was developed, and its physicochemical properties and some chemical transformations were investigated.Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 10, pp. 1422–1424, October, 1985.