新一类2,3—二氰基吡嗪除草剂的合成及其活性研究

新一类２，３－二氰基吡嗪除草剂的合成及其活性研究向纪明ａ谢周ｂ英柏宁ｂ（ａ陕西安康师专化学系，陕西．安康，７２５０００；ｂ中山大学化学系，广州，５１０２７５关键词５－芳胺基－６－氯－２，３－二氰基吡嗪除草剂合成中图分类号Ｏ６２６．４１５５位取代的２，...     

一系列氢键诱导液晶复合物的合成及表征

以２－氰基－３－（４－（２－氯－３－甲基－１－丁酰氧基）－苯基丙烯酸（Ａ）为质子给体，Ｎ－（４－吡啶基亚甲基）－４－烷氧基苯胺（ｎＳＳＺ）为质子受体，合成了一系列新的氢键复和物，经红外光谱证实了分子间氢键的存在，通过ＤＳＣ，偏光方法及Ｘ射线衍射方法对其液晶行为进行研究，结果表明复合物呈现近晶相行为。     

2—芳甲酰氨基硫羰基—3—异噻唑酮及4—氰基—5—甲硫基—2—芳甲…

通过３－羟基异噻唑和４－氰基－５－甲硫基－３－羟基异噻唑（５）分别与芳酰基异硫氰酰酯（３）反应,合成标题化合物２－芳甲酰氨基硫羟基－３－异噻唑酮和４－氰基－５－甲硫基－２－芳甲酰氨基硫羟基－３－异噻唑酮,对此反应及产物的结构特点进行了探讨。     

酶化学合成一对对映体Ro 25-8210和Ro 25-6630

利用白地霉菌株和啤酒酵母催化还原α－氯代酮　４分别制得光学活性的（Ｒ）和（Ｓ）－α－氯代酶 ８，并以它们作为关键步骤合成了 Ｒｏ２５－８２１０（１）和 Ｒｏ２５－６６３０（２）．     

3-甲基-3-氧杂丁环甲醇的阳离子型开环聚合

三元和四元环醚具有较大的环张力而易于聚合．Ｖａｎｄｅｎｂｅｒｇ等［１］曾经以（ｉ－Ｂｕ３）Ａｌ／Ｈ２Ｏ为引发剂,使３－甲基－３－（三甲基硅氧甲基）氧杂丁环进行开环聚合反应,合成的聚合物水解后得到线形的聚甲基羟甲基醚．本文以ＢＦ３·ＯＥｔ２为引发剂,对３－甲基－３－氧杂丁环甲醇进行直接引发,实现了开环聚合反应,得到基本线形或轻度支化的聚醚多元醇．１　实验部分１．１　聚合物的合成　聚合装置同文献［１］．所用试剂按文献［１］方法处理．向烧瓶中加入２０ｍＬ的二氯乙烷和０．１ｍｏｌ３－甲基－３－氧杂丁环甲…     

氯代酸气相热消除反应的理论研究

应用半经验分子轨道ＡＭ１法，辅以Ｂｅｒｎｙ梯度优化法对３－氯丙酸和２－氯丁酸在气相中的热消除反应进行了理论研究。计算结果表明：（１）３－氯丙酸在气相中的热消除反应可以通过六元环过渡态机理和四元环过渡态机平行进行得到产物；（２）２－氯丁酸的热消除则可以通过五元环过渡态机理和四元环过渡态机理平行进行；（３）对３－氯丙酸的热消除反应，以了环过渡态进行反应的活化势垒较低，而２－氯丁酸的热消除反应则是五元环     

新试剂2-(2-氰基-4-硝基-6-溴苯偶氮)-6-异丙基苯酚的合成及金属离子显色反应

本文以２－氰基－４－硝基－６－溴苯胺为原料，经重氮化后与邻异丙基苯酚偶联，合成２－（２－氰基－４－硝基－６－溴苯偶氮）－６－异丙基苯酚，用乙醇重结晶精制。用元素分析，波谱等鉴定其结构，并测定其离解常数，研究该试剂的一般性质。发现其与Ｃｕ２＋、Ｎｉ２＋、Ｃｏ２＋等的显色反应在吐温８０表面活性剂存在下有较高的灵敏度。     

1-(2-苯并噻唑)-3-(4-硝基苯)-三氮烯的合成及其与镉(Ⅱ)的显色反应研究

报道了１－（２－苯并噻唑）－３－（４－硝基苯）－三氮烯（ＢＴＮＰＴ）的合成及与镉（Ⅱ）的显色反应研究。在ＴｒｉｔｏｎＸ－１００的存在下,ｐＨ１１．６时,镉（Ⅱ）与ＢＴＮＰＴ形成摩尔比＝１∶２型黄色络合物,在４３５ｎｍ处有一最大正吸收,在５３０ｎｍ处有最大负吸收。以４３５ｎｍ为参比波长,５３０ｎｍ为测量波长进行双波长测定,表观摩尔吸光系数为２．５２×１０５Ｌ·ｍｏｌ－１·ｃｍ－１,线性范围为０～１０μｇ／２５ｍＬ。已用于测定地面水和人发中的镉含量。     

(Z)-3-丁烯基-4-羟基苯酞的合成

（Ｚ）－３－丁烯基－４－羟基苯酞的合成李绍白,王志伟,方小平,李裕林（兰州大学应用有机化学国家重点实验室,兰州,７３００００）关键词（Ｚ）－３－丁烯基－４－羟基苯酞,苯酞,３－丙基－５－羟基异香豆素,异香豆素,合成（Ｚ）－３－丁烯基－４－羟基苯酞（１...     

3-(2-氧代环烷基)丙酸与(R)-2-硫代四氢噻唑-4-羧酸乙酯的反应

３－（２－氧代环烷基）丙酸与（Ｒ）－２－硫代四氢噻唑－４－羧酸乙酯的反应李叶芝,田颜清,黄化民（吉林大学化学,长春,１３００２３）关键词（Ｒ）－２－硫代四氢噻唑－４－羧酸乙酯,Ｎ－３－（２－氧代环烷基）丙酰－２－硫代四氢噻唑－４－羧酸乙酯,环合反应,...     

Synthesis of 3,4‐Dialkyl‐5‐(1‐oxo‐ethyl)‐3H‐thiazole‐2‐thiones Derivatives and Their Pesticidal Activity

By interaction of N‐methyl(ethyl)‐dithiocarbamate sodium salt with 3‐chloro‐pentane‐2,4‐dion the 1‐(3‐alkyl‐4‐methyl‐2‐thioxo‐2,3‐dihydro‐thiazol‐5‐yl)‐ethanones 1 , 2 and corresponding oximes 7 , 8 were synthesized. On the basis of the mentioned compounds hydrazono ( 3 , 4 ), ureayl and thioureayl ( 5 , 6 ) derivatives, substituted oximes ( 9 , 10 ) and azinyl oximes ( 11 , 12 ) were obtained. The structures of synthesized compounds were confirmed by proton nuclear magnetic resonance spectroscopy and elemental analysis. The pesticidal activities of synthesized compounds were studied. Some of the synthesized compounds simultaneously have shown growth stimulant and fungicidal activity.     

Green and Efficient Synthesis of 4‐Heteryl‐Quinolines and Their Antibacterial Evaluations

A green and efficient synthesis of 4‐heteryl‐quinolines ( 9a , 9b , 9c , 9d ), ( 10a , 10b , 10c , 10d ) and ( 11a , 11b , 11c , 11d ) has been described using PEG‐600 as a green solvent. Initially, 4‐chloro‐2‐methylquinolines ( 5a , 5b , 5c , 5d ) on reaction with aromatic heterocyclic thiols ( 6 ), ( 7 ), and ( 8 ) using PEG‐600 at 100°C for 30–40 min resulted in ( 9 ), ( 10 ), and ( 11 ) in good yields. Alternatively, ( 9 ), ( 10 ), and ( 11 ) could also be prepared in dimethylformamide using K2CO3 as base and tetrabutylammonium bromide as phase transfer catalyst at 100°C for 1–2 h. All the compounds were synthesized and characterized by IR, NMR, mass spectroscopy, and 13C NMR analysis. All synthesized compounds were screened for their antibacterial activity against clinical strains that include Gram‐positive (Bacillus subtilis MTCC 121, staphylococcus aureus MLS‐16 MTCC 2940, Micrococcus lutes MTCC 2470, and Staphylococcus aureus MTCC 96) and Gram‐negative bacteria (Candida albicans MTCC 3017, Klebsiella planticola MTCC 530, Escherichia coli MTCC 739, and Pseudomonas aeruginosa MTCC 2453). The results revealed that compounds ( 9a , 9d , 10a , 10c , 11b , and 11d ) exhibited significant antibacterial activity almost equal to the standard drug, that is, Ciprofloxacin.     

Synthese und Molekülstrukturen von N‐substituierten Diethylgallium‐2‐pyridylmethylamiden

Synthesis and Molekular Structures of N‐substituted Diethylgallium‐2‐pyridylmethylamides (2‐Pyridylmethyl)(tert‐butyldimethylsilyl)amine ( 1a ) and (2‐pyridylmethyl)‐di(tert‐butyl)silylamine ( 1b ) form with triethylgallane the corresponding red adducts 2a and 2b via an additional nitrogen‐gallium bond. These oily compounds decompose during distillation. Heating under reflux in toluene leads to the elimination of ethane and the formation of the red oils of [(2‐pyridylmethyl)(tert‐butyldimethylsilyl)amido]diethylgallane ( 3a ) and [(2‐pyridylmethyl)‐di(tert‐butyl)silylamido]diethylgallane ( 3b ). In order to investigate the thermal stability solvent‐free 3a is heated up to 400 °C. The elimination of ethane is observed again and the C‐C coupling product N, N′‐Bis(diethylgallyl)‐1, 2‐dipyridyl‐1, 2‐bis(tert‐butyldimethylsilyl)amido]ethan ( 4 ) is found in the residue. Substitution of the silyl substituents by another 2‐pyridylmethyl group and the reaction of this bis(2‐pyridylmethyl)amine with GaEt₃ yield triethylgallane‐diethylgallium‐bis(2‐pyridylmethyl)amide ( 5 ). The metalation product adds immediately another equivalent of triethylgallane regardless of the stoichiometry. The reaction of GaEt₃ with 2‐pyridylmethanol gives quantitatively colorless 2‐pyridylmethanolato diethylgallane ( 6 ).     

Monomeric Homoleptic (2‐Pyridylmethyl)(tert‐butyldimethylsilyl)amido Complexes of the Divalent Metals Mg,Mn, Fe,Co, and Zn

The transamination reaction of M[N(SiMe₃)₂]₂ with (2‐pyridylmethyl)(tert‐butyldimethylsilyl)amine yields the corresponding homoleptic metal bis[(2‐pyridylmethyl)(tert‐butyldimethylsilyl)amides] of Mg ( 1 ), Mn ( 2 ), Fe ( 3 ), Co ( 4 ) and Zn ( 5 ). All these compounds crystallize from hexane isotypic in the space group C2/c. From toluene the zinc derivative precipitates as toluene solvate 5 ·toluene. The molecular structures of these compounds are very similar with large NMN angles to the amide nitrogen atoms with NMN values of 148° ( 1 ) and 150° ( 5 ) for the diamagnetic compounds and 156° for the paramagnetic derivatives 2 and 3 . The Co derivative 4 displays a rather small NCoN angle of 142°. Different synthetic routes have been explored for compound 3 which is also available via the metallation reaction of bis(2,4,6‐trimethylphenyl)iron with (2‐pyridylmethyl)(tert‐butyldimethylsilyl)amine and via the metathesis reaction of lithium (2‐pyridylmethyl)(tert‐butyldimethylsilyl)amide with [(thf)₂FeCl₂]. In course of the metathesis reaction, an equimolar amount of lithium (2‐pyridylmethyl)(tert‐butyldimethylsilyl)amide and [(thf)₂FeCl₂] yields heteroleptic (2‐pyridylmethyl)(tert‐butyldimethylsilyl)amido iron(II) chloride ( 6 ) which crystallizes as a centrosymmetric dimeric molecule. The oxidative C‐C coupling reaction of 5 with Sn[N(SiMe₃)₂]₂ leads to the formation of tin(II) 1,2‐bis(2‐pyridyl)‐1,2‐bis(tert‐butyldimethylsilylamido)ethane, tin metal and Zn[N(SiMe₃)₂]₂.     

Synthesis and conversion of 2‐(pyrazol‐1‐yl)quinoxaline 4‐oxides

The reaction of 6‐chloro‐2‐hydrazinoquinoxaline 4‐oxide 1b with acetylacetone or benzoylacetone gave 6‐chloro‐2‐(3,5‐dimethylpyrazol‐i‐yl)quinoxaline 4‐oxide 5a or 6‐chloro‐2‐(3‐methyl‐5‐phenylpyrazol‐1‐yl)quinoxaline 4‐oxide 5b , respXectively. Compound 5a or 5b was converted into the pyrrolo[1,5‐a]quinoxaline 6a or 6b , triazolo[4,3‐a]quinoxaline 9a or 9b , and tetrazolo[1,5‐a]quinoxaline 10.     

Syntheses, characterization, and catalytic ability in alkane oxygenation of chloro(dimethyl sulfoxide)ruthenium(II) complexes with tris(2-pyridylmethyl)amine and its derivatives

New ruthenium(II) complexes having a tetradentate ligand such as tris(2-pyridylmethyl)amine (TPA), tris[2-(5-methoxycarbonyl)pyridylmethyl]amine [5-(MeOCO)3-TPA], tris(2-quinolylmethyl)amine (TQA), or bis(2-pyridylmethyl)glycinate (BPG) have been prepared. The reaction of the ligand with [RuCl2(Me2SO)4] resulted in a mixture of trans and cis isomers of the chloro(dimethyl sulfoxide-kappaS)ruthenium(II) complexes containing a TPA or a BPG, whereas a trans(Cl,N(amino)) isomer was selectively obtained for 5-(MeOCO)3-TPA and TQA. The trans and cis isomers of the [RuCl(TPA)(Me2SO)]+ complex were easily separated by fractional recrystallization. The molecular structures of trans- and cis(Cl,N(amino))-[RuCl(TPA)(Me2SO)]+ complexes and the trans(Cl,N(amino))-[RuCl{5-(MeOCO)3-TPA}(Me2SO)]+ complex have been determined by X-ray structural analyses. The reaction of TPA with [RuCl2(PhCN)4] gave a single isomer of the chloro(benzonitrile)ruthenium(II) complex, whereas the bis(benzonitrile)ruthenium(II) complex was obtained with BPG. The cis(Cl,N(amino))-[RuCl(TPA)(Me2SO)]+ complex is thermodynamically much less stable than the trans isomer and isomerizes in dimethyl sulfoxide at 65-100 degrees C. Oxygenation of alkanes catalyzed by these ruthenium(II) complexes has been examined. The chloro(dimethyl sulfoxide-kappaS)ruthenium(II) complexes with TPA and its derivatives using m-chloroperbenzoic acid as a cooxidant showed high catalytic ability. Adamantane was efficiently and selectively oxidized to give 1-adamantanol up to 88%. The chloro(dimethyl sulfoxide-kappaS)ruthenium(II) complex with 5-(MeOCO)3-TPA was found to be the most active catalyst among the complexes examined.     

Quinolone analogues 2. A facile synthesis of novel 3‐substituted 1‐alkyl‐4‐oxo‐1,4‐dihydropyridazino[3,4‐b]quinoxalines

The reaction of the 2‐(1‐alkylhydrazino)‐6‐chloroquinoxaline 4‐oxides 1a,b with diethyl acetone‐dicarboxylate or 1,3‐cyclohexanedione gave ethyl 1‐alkyl‐7‐chloro‐3‐ethoxycarbonylmethylene‐1,5‐dihydropyridazino[3,4‐b]quinoxaline‐3‐carboxylates 5a,b or 6‐alkyl‐10‐chloro‐1‐oxo‐1,2,3,4,6,12‐hexahydroquinoxalino[2,3‐c]cinnolines 7a,b , respectively. Oxidation of compounds 5a,b with nitrous acid afforded the ethyl 1‐alkyl‐7‐chloro‐3‐ethoxycarbonylmethylene‐4‐hydroxy‐1,4‐dihydropyridazino‐[3,4‐b]quinoxaline‐4‐carboxylates 9a,b , whose reaction with base provided the ethyl 2‐(1‐alkyl‐7‐chloro‐4‐oxo‐1,4‐dihydropyridazino[3,4‐b]quinoxalin‐3‐yl)acetates 6a,b , respectively. On the other hand, oxidation of compounds 7a,b with N‐bromosuccinimide/water furnished the 4‐(1‐alkyl‐7‐chloro‐4‐oxo‐1,4‐dihydropyridazino[3,4‐b]quinoxalin‐3‐yl)butyric acids 8a,b , respectively. The reaction of compound 8a with hydroxylamine gave 4‐(7‐chloro‐4‐hydroxyimino‐1‐methyl‐1,4‐dihydropyridazino[3,4‐b]quinoxalin‐3‐yl)‐butyric acid 12 .     

Intercalating, cytotoxic, antitumour activity of 8-chloro and 4-morpholinopyrimido [4',5':4,5]thieno(2,3-b)quinolines

Circular dichroism, hydrodynamic methods, absorbance and fluorescence titration's were employed to study the interaction of 8-chloropyrimido[4',5':4,5]thieno(2,3-b)quinolin-4(3H)-one (chloro-PTQ) and 4-morpholinopyrimido[4',5':4,5]thieno(2,3-b)quinoline (morpholino-PTQ) with DNA. The association constant of chloro-PTQ and morpholino-PTQ were of the order of 10(5) and 10(6) M(-1). The fluorescence properties at ionic strength of 10mM are best fit by the neighbor exclusion model, with Ki of 0.3 x 10(4) M(-1) to 3.2 x 10(6) M(-1). CD spectra indicate that stacking of these compounds with DNA induces strong helicity in the usually disordered structure of the double strand. Viscosity experiments with sonicated rod like DNA fragments, produced a calculated length of 2.4A/bound of chloro/morpholino-PTQ molecule. The binding of chloro/morpholino-PTQ to DNA increased the melting temperature by about 1.5-7.0 degrees C. The cytotoxicity of these compounds on K-562, HL-60, Colo-205 and B16F10 melanoma are quite similar and IC(50) was in the range of 1.1-8muM. The anticancer efficacy against B16F10 melanoma has provided evidence of major anticancer activity for morpholino-PTQ. Single or multiple i.p. doses of compounds showed high level of activity against the subcutaneous (s.c.) grafted B16 melanoma with a significant increase in life span (161% and 272%). The aim of this study was to analyze the physicochemical properties of the chloro/morpholino-PTQ in an attempt to understand their superior biological activity. This research offers a new intercalation functional group to DNA targeted drug design.     

Capillary GC using pyridyl β‐cyclodextrin stationary phase

A new β‐CD derivative, heptakis [2,6‐di‐O‐pentyl‐3‐O‐(4′‐chloro‐5′‐pyridylmethyl)]‐β‐CD, was synthesized by the selective introduction of a pyridyl group on the 3‐positions of β‐CD. The chromatographic properties of the pyridyl β‐CD derivative were studied by using it as the stationary phase in capillary GC. The polarity of the prepared stationary phase was moderate, and the separation results demonstrated that the prepared stationary phase possessed excellent separation ability and chiral recognition for a wide range of analytes. Not only the aromatic positional isomers, such as o‐, m‐, p‐xylene and α‐, β‐naphthol isomers, but also some compounds with multi‐stereogenic centers, such as n‐(1‐methylpropyl)‐3‐(2,2‐dichloroethenyl)‐2,2‐dimethylcyclopropanecarboxamide and n‐(1‐methylpropyl)‐3‐(2‐chloro‐3,3,3‐trifluoropropenyl)‐2,2‐dimethylcyclopropanecarboxamide with three stereogenic centers including eight configurational isomers, were successfully separated. The results also indicated that the polarity of the β‐CD derivative, and the hydrogen bonding between the β‐CD derivative, and the analytes had a very important effect on separation.     

Synthesis,Characterization, and Screening for Anti‐inflammatory and Antimicrobial Activity of Novel Indolyl Chalcone Derivatives

Because of the great biological importance of substituted indole derivatives, in the present study, a series of pyrazolylindole, thiazolylindole, and pyrimidinylindole derivatives have been synthesized with good yield. The precursor indolyl chalcone 2a – d was prepared by reaction of 3‐chloro‐1H‐indole‐2‐carbaldehyde 1 with different ketones. Then, compounds 3b – d , 4 , and 5a – d have been synthesized by the reaction of chalcones 2a – d with hydrazine, phenylhydrazine, and thiosemicarbazide. When the chalcone derivative 2b subjected to react with hydroxylamine hydrochloride gave isoxazolylindole derivative 6b . N‐thiazolidine pyrazolyl indole 7 was obtained by reacting compound 5a with ethyl chloroacetate. On the other hand, when chalcone derivative 2b allowed to react with urea and thiourea gave the corresponding pyrimidinylindole derivatives 8 and 9 . Finally, when chalcone derivative 2b reacted with ethyl cyanoacetate or malononitrile gave pyridinylindole derivatives 10 and 11 . The structures of the all synthesized compounds were elucidated on the basis of spectral analysis infrared, NMR, and mass spectroscopy. Some of the synthesized compounds were screened for their antimicrobial and anti‐inflammatory activity. Compound 4b was the highest antibacterial activity against all strains of bacteria with values higher than those of the corresponding reference antibiotics (ciprofloxacin and levofoxacin, respectively) and almost the same as (gemifloxacin, moxifloxacin, clindamycin, gentamycin, and streptomycin). Compounds 4 , 5 , 6 , and 7 showed high anti‐inflammatory activity compared with the standard drug indomethacin.