微波辐射下2-[4-二-(4-氟苯)甲基]哌嗪乙酰腙化合物的合成

微波辐射条件下, 以丙酮作溶剂, 1-[二-(4-氟苯)甲基]哌嗪与氯乙酸乙酯反应得到2-[二-(4-氟苯)甲基]哌嗪乙酸乙酯(1), 1与水合肼在微波辐射条件下反应得到2-[二-(4-氟苯)甲基]哌嗪乙酰肼(2), 进一步在微波辐射条件下由2-[二- (4-氟苯)甲基]哌嗪乙酰肼(2)与取代芳香醛反应制得目标化合物3a～3f. 合成的6个目标化合物通过熔点测定和质谱、红外光谱、核磁共振氢谱分析、元素分析对其结构进行确证.     

微波辐射合成2-乙氧羰基甲硫基-4-取代苯基亚氨基-4H-1-萘酮类化合物

以对取代苯胺与2-乙氧羰基甲硫基-1,4-萘醌为底物,采用微波合成法合成了3个新型的蛋白酶体抑制剂的关键中间体——2-乙氧羰基甲硫基-4-苯基亚氨基-4H-1-萘酮类化合物(3a~3c),其结构经1H NMR和1D NOE表征。在最佳反应条件[THF为溶剂,TiCl4为催化剂,于60℃微波(240 W)反应15 min]下,2-乙氧羰基甲硫基-4-(4-硝基苯基)亚氨基-4H-1-萘酮(3a)的收率84.2%。     

9-咔唑-羧酸化合物的微波合成及其生物活性研究

9-咔唑 -羧酸化合物不但是医药[1] 、有机光导材料[2 ] 的中间体 ,而且其本身亦具有干扰素诱导能力[3] .近年来 ,我们[4 ] 应用 9-咔唑 -乙酸和丙酸作为高效液相色谱分析氨基酸、胺和醇类的衍生化试剂 .目前所合成的此类化合物很少 .近 1 5年以来 ,微波在有机合成中的应用已发展成为一个新的研究领域[5] ,许多反应已在微波炉中高产率快速地实现了 .本文采用微波辐照法快速合成了系列 9-咔唑 -羧酸化合物 3 a— 3 m,优化了反应条件 ,并测试了它们的生物活性 .反应式如下 :丷4R5丯HR3 R2R1( 1) +Br R6COOC2 H5( 2 ) 丷4R5丯R6COOHR3 R…     

3-甲基-2-戊烯-4-炔醛的合成新方法

化合物3-甲基-2-戊烯-4-炔-1-醛两端均为活性官能团,在分子连接及成环反应中能够起到非常重要的作用,是合成轮烯酮[1-7],脱落酸[8]和二苯基二苯并环辛烯[9]等的重要中间体.     

微波辐射下合成5-(2-甲基/三氟甲基-苯并咪唑-1-亚甲基)-3-(苯基/p-取代苯基)-2H-1'''',2'''',4''''-三唑[3,4-b]-1",3",4"-噻二嗪

分别采用微波辐射法和加热回流的常规方法,将1-氨基-2-(2-甲基/三氟甲基-苯并咪唑-1-亚甲基)-5-巯基-1,3,4-三唑与α-溴代芳基乙酮3a～3e反应,合成了一系列未见文献报道的1,2,4-三唑[3,4-b]-1',3',4'-噻二嗪类化合物4a～4e和5a～5e.微波辐射法具有反应时间短、产率高、副反应少等优点.标题化合物经元素分析,IR,1HNMR,MS确证结构.     

微波辐射下一锅法合成2-氨基-6-溴-4-芳基-5H-茚并[1,2-b]吡啶-3-腈衍生物

以芳香醛、4-溴茚酮、丙二腈和醋酸铵为原料,分别用微波辐射和传统加热法,一步法合成7种未见文献报道的2-氨基-6-溴基-4-芳基-5H-茚并[1,2-b]吡啶-3-腈衍生物.对比两种方法,在常压下微波具有反应时间短、产率较高等特点.所有化合物均经IR,1HNMR和元素分析确定.     

(2R，3R)-和(2S，3S)-2-(4-羟基-3-甲氧基)-3-羟甲基-1，4-苯并二氧六环-6-醛的对映选择性合成

1,4-苯并二氧六环木脂素类天然产物多数具有增加胆碱乙酰化酶和抗肝毒等活性 ,其活性主要源于 1 ,4-苯并二氧六环官能团 [1] . 1 ,4-苯并二氧六环木脂素的消旋全合成已有报道 [2 ] ,但其不对称合成还是空白[3] .我们发展了一条对映选择性合成 1 ,4-苯并二氧六环木脂素的简捷有效的路线 .基于前面的工作 [4 ] ,我们发现 1 ,4-苯并二氧六环醛类衍生物是合成此类天然产物的关键中间体 ,选择 2 - (4-羟基- 3-甲氧基 ) - 3-羟甲基 - 1 ,4-苯并二氧六环 - 6-醛 (1 )作为目标分子 ,其合成路线如下 :Reagents and conditions:( ) Me OH,H2 SO4,9…     

微波促进的Dimroth重排反应合成吡啶并[2,3-d]嘧啶-4-胺衍生物（英文）

研究了N-(3,5-二氯苯基)吡啶并[2,3-d]嘧啶-4-胺的合成新方法.在微波辐射条件下,以2-氨基-3-氰基吡啶为原料,依次通过缩合、环化和Dimroth重排两步反应,得到目标产物N-(3,5-二氯苯基)吡啶并[2,3-d]嘧啶-4-胺,总收率90%.并应用该方法,合成了20个吡啶并[2,3-d]嘧啶-4-胺类化合物.同时,比较了微波辐射和传统油浴加热条件下的反应结果.结果表明,微波辐射条件下,反应时间短,产率高.此方法有望成为一种高效、温和、对环境友好的合成吡啶并[2,3-d]嘧啶-4-胺的方法.     

微波促进下6,7-二氢-5H-环戊二烯并[4,5]噻吩并[2,3-d]嘧啶-4-胺的简便合成（英文）

微波辐射条件下,以乙醇作溶剂,环戊酮、丙二腈与单质硫反应得到2-氨基-5,6-二氢-4H-环戊二烯[b]噻吩-3-腈(1),1与N,N-二甲基甲酰胺二甲基缩醛在微波辐射条件下反应得到N-(3-氰基-5,6-二氢-4H-环戊二烯[b]-硫基-2-基)-N,N-二甲基亚甲基酰胺(2),进一步在微波辐射条件下由N-(3-氰基-5,6-二氢-4H-环戊二烯[b]-硫基-2-基)-N,N-二甲基亚甲基酰胺(2)与取代芳香胺反应制得目标化合物.合成的25个目标化合物通过熔点测定和核磁共振氢谱分析、红外光谱、高分辨质谱对其结构进行确证.     

微波法合成2-羟乙基苯并[d]异噻唑-3(2H)-酮

以苯并异噻唑-3(2H)-酮(BIT)及氯乙醇为原料微波法合成了2-羟乙基苯并[d]异噻唑-3(2H)酮。考察了氢氧化钠量,氯乙醇用量,反应时间,反应温度对反应的影响,经正交实验设计得到了最佳反应条件,最佳反应条件下收率为83.3%。结果表明,与传统工艺相比,微波技术合成2-羟乙基苯并[d]异噻唑-3(2H)-酮的方法具有操作方便、收率高等特点,具有一定的应用价值。     

Nitration of 4-Acetylamino-4'-nitrodiphenyl Sulfide

Procedures have been developed for the acylation of 4-amino-4'-nitrodiphenyl sulfide with an almost quantitative yield by the action of acetic anhydride in aprotic organic solvents and subsequent nitration of 4-acetylamino-4'-nitrodiphenyl sulfide with nitric acid in a mixture of acetic acid and an aprotic organic solvent with addition of a mixture of sulfuric and acetic acids by the end of the process.     

2-Allylaminothiazolin-4-one in acylation reactions

2-Acetylallylamino-4-acetoxythiazole is obtained via treatment of 2-allylaminothiazolin-4-one with acetic anhydride for a short period of time. After extended reaction times with a mixture of acetic anhydride and acetic acid a non-condensed bicyclic derivative of thiazolidin-4-one is obtained.Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 8, pp. 1135–1140, August, 1987.     

Synthesis of 4H-1,3,4-oxadiazino[5,6-b]quinoxalines from 2-substituted quinoxaline 4-oxides

The reaction of 6-chloro-2-(1-methylhydrazino)quinoxaline 4-oxide 8 with acetic anhydride resulted in the intramolecular cyclization to give 8-chloro-2,4-dimethyl-4H-1,3,4-oxadiazino[5,6-b]quinoxaline 7a , while the reaction of compound 8 with acetic anhydride/pyridine or acetic anhydride/acetic acid afforded 3-(2,2-diacetyl-1-memymydrazmo)-7-chloro-2-oxo-1,2-dihydroquinoxaline 9 , effecting no intramolecular cyclization. The reaction of 2-(2-acetyl-1-methylhydrazino)-6-chloroquinoxaline 4-oxide 10a or 6-chloro-2-(1-methyl-2-trifluoroacetylhydrazino)quinoxaline 4-oxide 10b with phosphoryl chloride provided compound 7a or 8-chloro-4-memyl-2-trifluoromethyl-4H-1,3,4-oxadiazino[5,6-b]quinoxaline 7b , respectively. The reaction of compound 7b with phosphorus pentasulfide gave 7-chloro-3-(1-methyl-2-trifluoroacetylhydrazino)-2-thioxo-1,2-dihydroquinoxaline 11 , whose dehydration with sulfuric acid in acetic acid afforded 8-chloro-4-methyl-2-trifluoromemyl-4H-1,3,4-thiadiazino[5,6-b]quinoxaline 12 .     

Synthesis of methyl 4-aryl-4-oxo-2-[(4-sulfamoylphenyl)amino]but-2-enoates and their reaction with ninhydrin

The reaction of methyl 4-aryl-2,4-dioxobut-2-enoates with 4-aminobenzenesulfonamide in acetic acid–ethanol (1: 1) afforded methyl (2Z)-4-aryl-4-oxo-2-(4-sulfamoylanilino)but-2-enoates which reacted with ninhydrin in glacial acetic acid to give 3-aroyl-4-(4-sulfamoylanilino]-5H-spiro[furan-2,2′-indene]-1′,3′,5-triones.     

Reduction of 4-arylazoindoles

It was established that 4-acetamido-5-hydroxyindole derivatives are formed in the reduction of 4-phenylazo-5-hydroxyindole derivatives with zinc dust in acetic acid in the presence of acetic anhydride and sodium acetate. However, p-semidine rearrangement of the intermediate hydrazo derivatives is observed in the analogous reduction of 4-arylazo-5-methoxyindoles, and 4-acetamido-5-methoxy-7-arylaminoindoles are formed. The latter are oxidized by oxygen and nitric acid to 4-oxo-7-arylimino-4,7-dihydroindoles; nitration of the arylimino ring occurs in some cases under the influence of nitric acid.Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 10, pp. 1374–1379, October, 1980.     

Synthesis of Derivatives of (4-Methyl-2-Quinolylthio)acetic and (4-Methyl-2-Quinolylthio)propionic Acids

An efficient synthesis has been developed for derivatives of (4-methyl-2-quinolylthio)acetic and (4-methyl-2-quinolylthio)propionic acids by the reaction of 4-methyl-2-thioxoquinoline with methyl methacrylate, the amide of methacrylic acid, acrylonitrile, ethyl bromoacetate, and ethyl acrylate. The hydrolysis of the resultant intermediates by (quinolylthio)acetic and (quinolylthio)propionic acids gave the corresponding acid products, which are also formed in the reaction of 4-methyl-2-thioxoquinoline with chloroacetic and acrylic acids. The reaction of 4-methyl-2-thioxoquinoline with allyl bromide was studied. The potassium permanganate oxidation of the resultant 2-allylthio-4-methylquinoline led to (4-methyl-2-quinolylthio)acetic acid.__________Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 4, pp. 403–406, April, 2005.     

Sydnone Compounds XXX. The Syntheses and Reactions of 3-Aryl-4-Cyanosydnones and 3-Aryl-4-Formylsydnone Oximes

In the presence of pyridine, 3-aryl-4-formylsydnone (II) reacts with hydroxyl-amine hydrochloride to produce 3-aryl-4-formylsydnone oxime (III). This reaction was performed in ethanol solution with reflux or at room temperature; the latter procedure gave an excellent yield (74-98%) and high purity. (III) reacts in acetic anhydride at room temperature to give 3-aryl-4-formylsydnone oxime O-acetate (IV). A convenient method for the synthesis of 3-aryl-4-cyanosydnone (V) is to dehydrate (III) with acetic anhydride at reflux. When (IV) was refluxed with acetic anhydride, (V) was similarly obtained. Another convenient method to prepare (V) from (III), dehydration with thionyl chloride at room temperature, was also investigated.     

Synthesis of 4-aryl-2-hydroxy-4-oxo-2-butenoic (Aroylpyruvic) acids N-(4-Acetylaminosulfonylphenyl)amides

Methyl aroylpyruvates react with sodium 4-aminobenzenesulfonylacetamide in acetic acid to afford 4-aryl-2-hydroxy-4-oxo-2-butenoic acids N-(4-acetylaminosulfonylphenyl)amides. The latter were studied in reactions with hydrazine hydrate.     

A Novel Synthesis of 4‐Pyridazineacetic Acids via Ring Expansion of N‐Cyanomethylated 3‐Pyrazoline‐4‐acetic Acids

A novel synthetic route to 4‐pyridazineacetic acids 10 – 12 has been achieved by the ring‐expansion reaction of N‐cyanomethylated 3‐pyrazoline‐4‐acetic acids 7 – 9 . 1H‐Pyrazole‐4‐acetic acids 1 – 3 were reacted with iodoacetonitrile in the presence of triethylamine in refluxing acetonitrile to give the corresponding C‐cyanomethylated 1H‐pyrazole‐4‐acetic acids 4 – 6 as major products together with N‐cyanomethylated 3‐pyrazoline‐4‐acetic acids 7 and 8 as minor products. On the other hand, reactions of 1 and 3 with chloroacetonitrile in the presence of triethylamine in refluxing chloroform afforded the corresponding N‐cyanomethylated 3‐pyrazoline‐4‐acetic acids 7 and 9 as major products. Thermal treatment of 7 – 9 with sodium hydride in N,N‐dimethylformamide caused ring expansion to yield the corresponding 4‐pyridazineacetic acids 10 – 12 .     

Different Protonation Equilibria of 4‐Methylimidazole and Acetic Acid

Dynamic protonation equilibria in water of one 4‐methylimidazole molecule as well as for pairs and groups consisting of 4‐methylimidazole, acetic acid and bridging water molecules are studied using Q‐HOP molecular dynamics simulation. We find a qualitatively different protonation behavior of 4‐methylimidazole compared to that of acetic acid. On one hand, deprotonated, neutral 4‐methylimidazole cannot as easily attract a freely diffusing extra proton from solution. Once the proton is bound, however, it remains tightly bound on a time scale of tens of nanoseconds. In a linear chain composed of acetic acid, a separating water molecule and 4‐methylimidazole, an excess proton is equally shared between 4‐methylimidazole and water. When a water molecule is linearly placed between two acetic acid molecules, the excess proton is always found on the central water. On the other hand, an excess proton in a 4‐methylimidazole‐water‐4‐methylimidazole chain is always localized on one of the two 4‐methylimidazoles. These findings are of interest to the discussion of proton transfer along chains of amino acids and water molecules in biomolecules.