薄层色谱扫描法测定光诱导反应生成的N-(α-吡啶基)咔唑

近年来,有机化学家对单电子转移的自由基链式亲核取代反应——S_(RN)1进行了广泛的研究。在这一反应中,由于作为亲核体的有机氮负离子的亲核性较弱,使反应产率低且不易分离,给产物的定量分析工作带来困难,从而影响了对该反应机理的探讨。为此,我们用薄层色谱扫描法对有机氮负离子参与的光诱导S_(RN)1反应产物的测定进行了研究。本工作对由咔唑钾氮负离子与α-溴代吡啶进行S_(RN)1反应的产     

α-芳基丙酸的新合成路线和芳卤与烷基氰碳负离子间光诱导S_(RN)1反应的定量研究

本文报道了一条合成α-(2-(6-甲氧基荼基))-丙酸的新合成路线,成功地从芳卤和丙腈经光诱导S_(RN)1反应一步合成所期待的α-芳基丙腈,随后的水解以极高的总产率获得α-芳基丙酸,在KNH_2-NH_3溶液中,α-溴苯和乙腈或丙腈的光反应生成相应的亲核取代产物,其量子产率均大于1,光反应的假一级速率常数分别是30.9×10~(-5)nol/L·s~(-1)和4.7×10~(-5)mol/L·s~(-1),光引发机理是基态CTC的被激发和在复合物内电子从负离子转移到芳卤,支持这种机理的关键性证据是φ>200和φ>313相等以及分子轨道计算结果。     

薄层光密度法在N-苄基咔唑S_(RN)l反应产物分析中的应用

S_(RN)l反应是自由基反应与离子型反应的结合,因而受到物理有机化学家们的注意。我们在近年来研究了一系列以氮负离子作为亲核体的S_(RN)l反应。在以咔唑氮负离子作为亲核体与苄基氯在光诱导下的S_(RN)l反应机理研究中,我们建立了N-     

(Z)-1-三苯基锡基-3-对氯苯基-1-丁烯-3-醇及其卤代物的合成、表征和晶体结构

在氮气保护下,3-对氯苯基-1-丁炔-3-醇与三苯基氢化锡进行游离基加成反应,获得加成物(Z)-1-三苯基锡基-3-对氯苯基-1-丁烯-3-醇(1).加成物(1)与卤素反应后,与锡原子相连的苯基被取代,得到一卤代、二卤代和混合二卤代物(2-8).通过元素分析、¹HNMR和IR表征了化合物1～8的结构,并测定了加成物(1)、一溴代物(3)和二溴代物(5)的晶体结构.在加成物(1)的晶体结构中存在一对对映体,由于分子内存在较弱的O→Sn配位作用,构成以锡原子为中心的扭曲四面体构型.在化合物3和5分子中,存在分子内O→Sn配位键,构成以锡为中心的扭曲三角双锥构型.该系列化合物分子内的O→Sn配位能力和Lewis酸性强弱的顺序为:二卤化物>一卤化物>加成物;氯代物>溴代物>碘代物.     

水溶性稠杂环均三唑并噻二唑体系的合成及生物活性(I): 哌嗪取代衍生物

4-氨基-5-吡啶-4-基-均三唑硫醇(1)在复合催化剂DMAP和TBAB作用下与对卤代苯甲酸经环缩合反应以高收率得到中间体6-(5-氯-3-甲基-1-取代苯基-1H-吡唑-4-基)-3-吡啶-3-基-均三唑并[3,4-b][1,3,4]噻二唑(2a～2c), 接着苯环卤原子与取代哌嗪在聚乙二醇催化作用下发生亲核取代反应得到相应的哌嗪游离碱(3a～3c). 其中, 单取代哌嗪游离碱3a与含功能基的卤代物缩合得到功能基取代的哌嗪衍生物(4a～4g). 这些产生的游离碱与盐酸反应得到相应的水溶性盐酸盐. 所合成新化合物的结构经元素分析和光谱数据表征, 并评价了它们的体外抗菌活性及构效关系.     

3-取代酚酮5位偶联产物的溴氧化成环反应

报道了采用溴氧化3-异丙烯基(艹卓)酚酮和3-肉桂酰基(艹卓)酚酮合成杂环并(艹卓)酮化合物的新方法。3-异丙烯基(艹卓)酚酮5位偶联产物1a～1f和3-肉桂酰基(艹卓)酚酮5位偶联产物3a～3d分别在吡啶介质中与过量溴作用生成5-取代苯偶氮基-7-溴-3-甲基-8-氢环庚并呋喃-8-酮2a～2f和6-取代苯偶氮基-2-苯基-8-溴-4,9-二氢环庚并吡喃-4,9-二酮4a～4d。     

邻硝基酚醚上的异常取代反应

以2-(2-硝基苯氧基)-1-溴乙烷或3-(2-硝基苯氧基)-1-溴丙烷为原料分别在氢化钠作用下与N-Boc-4-羟基哌啶反应,得到了与预期结构不同的产物.该产物的结构经1H NMR,13C NMR,LC-MS分析表明,其并非为原料2-(2-硝基苯氧基)-1-溴乙烷与N-Boc-4-羟基哌啶发生Williamson反应生成预期的混合醚,而是芳环上的烷氧基被取代的异常产物.根据这个实验结果,推测上述反应的可能机理是发生了芳环上的亲核取代反应.     

糖苷合成研究(ⅩⅩⅠ)2-N-(β-D-吡喃葡萄糖-1-基)-6-(4-卤代苯基)-3-哒嗪酮的合成

在相转移催化条件下,2,3,4,6-四-O-乙酰基-1-溴-1-脱氧-α-D-吡喃葡萄糖1与6-(4-卤代苯基)-3(2H)-哒嗪酮2反应,合成了4种新的哒嗪酮葡萄糖苷3;然后用干燥的氨气在0～-5 ℃下处理,得相应的2-N-(β-D-吡喃葡萄糖-1-基)-6-(4-卤代苯基)-3-哒嗪酮4. 这些化合物的结构经IR、1H NMR、13C NMR及元素分析所证实.     

离子液体中卤代炔烃高效水解制取α-卤代甲基酮的研究

在离子液体中,硫酸促进卤代炔烃水解生成α-卤代甲基酮,反应收率高达85%~94%.离子液体-硫酸反应体系可多次(5次以上)循环使用而不影响反应收率.同时,此反应体系底物适用性强,高效制得一系列芳环上不同取代基的(如甲基、甲氧基、羟基、硝基等)α-氯/溴/碘代苯乙酮及脂肪类卤代甲基酮.     

Cu（OTf）2催化苄基卤代物与三丁基烯丙基锡的偶联反应

研究了苄基卤代物与三丁基烯丙基锡的偶联反应,当以10mol%Cu(OTf)2为催化剂,CH2Cl2为溶剂时,1-氯甲基-4-苯基萘与三丁基烯丙基锡于室温反应1h,交叉偶联反应产物1-(3-丁烯基)-4-苯基萘(3b)收率即达93%.结果表明,芳环含供电子基的底物反应活性较高,在室温反应几分钟即可完成,而芳环含吸电子基的底物反应活性低.反应产物3b,1-溴-4-(3-丁烯基)萘(3c)和1-(3-丁烯基)-4-硝基萘(3f)未见报道,且其结构经表征确认.     

两种氮杂环丁烷类药物中间体的合成

1-二苯甲基-3-羟基氮杂环丁烷(1)经过对甲苯磺酰氯取代、叠氮化及还原反应合成了药物中间体--1-二苯甲基-3-氨基氮杂环丁烷(4);1经过氧化、氰基化与还原反应合成了1-二苯甲基-3-羟基-3-氨甲基氮杂环丁烷(8).4和8的结构经1H NMR表征.     

两种新型丁二炔衍生物的合成

以3,5-二溴-1-｛3-（十二烷氧基）-2-［（十二烷氧基）甲基］丙氧基｝苯和2-甲基-3-丁炔-2-醇为原料,经选择性Sonogashira偶联反应,Sonogashira偶联反应和去硅保护基反应制得中间体--3-乙炔基-5-（3-甲基-3-羟基)-丁炔基-1-（3-十二烷氧基）-2-｛［（十二烷氧基）甲基］丙氧基｝苯（6）; 6经改良的Glaser偶联反应(CuI为催化剂,Et₃N为溶剂)合成了一个新型的丁二炔衍生物（1）。 6与2,2′-［（2,5-二碘-1,4-亚苯基）双（氧基）］双（四氢-2H-吡喃）经Sonogashira偶联,脱 THP保护基和改良的Glaser偶联反应合成了一个新型的丁二炔衍生物（2）。中间体,1和2的结构经¹H NMR, ¹³C NMR和MALDI-TOF-MS表征。     

Reactions of SO3 with the O/H radical pool under combustion conditions

The reactions of SO3 with H, O, and OH radicals have been investigated by ab initio calculations. For the SO3 + H reaction (1), the lowest energy pathway involves initial formation of HSO3 and rearrangement to HOSO2, followed by dissociation to OH + SO2. The reaction is fast, with k(1) = 8.4 x 10(9)T(1.22) exp(-13.9 kJ mol(-1)/RT) cm(3) mol(-1) s(-1) (700-2000 K). The SO3 + O --> SO2 + O2 reaction (2) may proceed on both the triplet and singlet surfaces, but due to a high barrier the reaction is predicted to be slow. The rate constant can be described as k(2) = 2.8 x 10(4)T(2.57) exp(-122.3 kJ mol(-1)/RT) cm(3) mol(-1) s(-1) for T > 1000 K. The SO3 + OH reaction to form SO2 + HO2 (3) proceeds by direct abstraction but is comparatively slow, with k(3) = 4.8 x 10(4)T(2.46) exp(-114.1 kJ mol(-) 1/RT) cm(3) mol(-1) s(-1) (800-2000 K). The revised rate constants and detailed reaction mechanism are consistent with experimental data from batch reactors, flow reactors, and laminar flames on oxidation of SO2 to SO3. The SO3 + O reaction is found to be insignificant during most conditions of interest; even in lean flames, SO3 + H is the major consumption reaction for SO3.     

天然产物Combretastatin A-1和Combretastatin B-1的合成

基于Perkin反应策略合成了具有强效抗肿瘤、抗血管活性的天然产物Combretastatin A-1(CA1)和Combretastatin B-1(CB1).以2,3,4-三羟基苯甲醛(1)为起始物, 经单甲基化反应得到2,3-二羟基-4-甲氧基苯甲醛(2), 再经酚羟基保护得到2,3-二异丙基-4-甲氧基苯甲醛(3), 该化合物与3,4,5-三甲氧基苯乙酸(4)发生Perkin反应分离得到E-2-(3,4,5-三甲氧基苯基)-3-(2',3'-二异丙氧基-4'-甲氧基)丙烯酸(E-5), 经脱羧反应得到Z-3,4,4',5-四甲氧基-2',3'-二异丙氧基二苯乙烯(6), 最后经脱保护反应得到CA1.另外, 将E-2-(3,4,5-三甲氧基苯基)-3-(2',3'-二异丙氧基-4'-甲氧基)丙烯酸(E-5)脱去保护基得到E-2-(3,4,5-三甲氧基苯基)-3-(2',3'-二羟基-4'-甲氧基)丙烯酸(7), 该化合物经脱羧-异构化反应得到E-3,4,4',5-四甲氧基-2',3'-二羟基二苯乙烯(E-CA1), 最后经催化氢化得到CB1.     

Kinetics Investigation of OH reaction with isoprene at 240-340 K and 1-3 torr using the relative rate/discharge flow/mass spectrometry technique

The kinetics of the reaction of OH radical with isoprene has been investigated at a total pressure of 1-3 Torr over a temperature range of 240-340 K using the relative rate/discharge flow/mass spectrometry (RR/DF/MS) technique. The reaction of isoprene with OH was found to be independent of pressure over the pressure range of 1-3 Torr at 298 K, and the reaction had reached its high-pressure limit at 1 Torr. However, the rate constant of this reaction is found to positively depend on pressure at 1-3 Torr and 340 K. At 298 K, the rate constant of this reaction was determined to be k1 = (10.4 +/- 1.9) x 10(-11) cm3 molecule(-1) s(-1), which is in good agreement with literature values. The Arrhenius expression for this reaction was determined to be k1 = (2.33 +/- 0.09) x 10(-11) exp[(444 +/- 27)/T] cm3 molecule(-1) s(-1) at 240-340 K. The atmospheric lifetime of isoprene was estimated to be 2.9 h based on the rate constant of isoprene + OH determined at 277 K in the present work.     

氘代AZD9291的合成

吲哚和2,4-二氯嘧啶经偶联反应制得3-(2-氯嘧啶-4-基)-1H-吲哚(1); 1与CD₃I 经取代反应制得3-(2-氯嘧啶-4-基)-1-(甲基-d₃)-吲哚(2); 2经两步亲核取代反应制得N′-(2-二甲基氨基乙基)-2-甲氧基-N′-甲基-N-{［4-(1-(甲基-d₃)吲哚-3-基)］嘧啶-2-基}-5-硝基苯-1,4-二胺(4); 4经还原反应后,与氯丙酰氯发生缩合反应合成了氘代AZD9291,总收率8.5%,其结构经¹H NMR, ¹³C NMR和ESI-MS表征。     

Solvent-free reaction of 3-aryl-6-(3-nitrophenyl)-1,2,4-triazines with 4-(cyclohex-1-en-1-yl)morpholine

The aza-Diels–Alder reaction of 3-aryl-6-(3-nitrophenyl)-1,2,4-triazines with 4-(cyclohex-1-en-1-yl)morpholine as dienophile was accompanied by reduction of the nitro group to amino. In the reaction of 3-(4-methoxyphenyl)-6-(3-nitrophenyl)-1,2,4-triazine with 4-(cyclohex-1-en-1-yl)morpholine, 3-[3-(4-methoxyphenyl)-1,2,4-triazin-6-yl)aniline was formed together with the cycloaddition product.     

1H NMR analysis of the tolylene-2,4-diisocyanate – methanol reaction

<正>Tolylene-2,4-diisocyanate(2,4-TDI) 1 reacts with methanol through two simultaneous paths in the polyurethane reaction,which involve two different intermediates-tolylene-4-carbamatic-2-isocyanate 2 and tolylene-2-carbamatic-4-isocyanate 3,and the final product is tolylene-2,4-dicarbamate 4.The-CH_3 chemical shifts in benzene ring in compounds 1,2,3 and 4 can be easily tested and well distinguished,through which those four compounds are quantified and their kinetics are investigated.It shows that four rate constants for the tolylene-2,4-diisocyanate-methanol reaction in CCl_4 at 50℃are k_1=9.6×10~(-2)h~(-2)mol~(-2)min~(-1), k_2=1.4×10~(-2)h~(-2)mol~(-2)min~(-1),k_3=4.0×10~(-3)h~(-2)mol~(-2)min~(-1),k_4=1.4×10~(-3)h~(-2)mol~(-2)min~(-1).(k_1 is the reaction rate constant from compounds 1 to 2;k_2 is the reaction rate constant from compounds 1 to 3;k_3 is the reaction rate constant from compounds 3 to 4;k_4 is the reaction rate constant from compounds 2 to 4).     

Novel formation of iodobenzene derivatives from 1-(methylthio)-3-tosylhexa-1,3-dien-5-ynes via iodine-induced intramolecular cyclization

The reaction of (1E,3E)-1-(methylthio)-3-tosylhexa-1,3-dien-5-ynes (3) with iodine to form iodine-substituted benzenes (4) is reported. The reaction of 3 with iodine proceeded very slowly, but UV irradiation accelerates the reaction to give 4 in high-to-excellent yields. Irradiation induces the cis-trans isomerization of the C1-C2 double bond, leading to the (1Z,3E)-geometric isomer (3'), which easily reacts with iodine to afford 4. This reaction is applicable to 3-(methoxycarbonyl)-1-(methylthio)-6-phenylhexa-1,3-dien-5-yne (11), which is synthesized as a geometric mixture. Interestingly, this mixture can be used as the starting material. Irradiation of the mixture (the geometric isomer ratio = 50:28:5:17) with iodine resulted in the formation of methyl 3-iodo-4-phenylbenzoate (12) in 80% yield.     

Microwave Induced Conversion of Dialkyl 2-(3-Acetyl-4-hydroxy-1-naphthyl)-3-(triphenylphosphoranylidene)Butanedioates to Dialkyl 2-(3-Acetyl-4-hydroxy-1-naphthyl)-2-butenedioates in the Presence of Silica Gel Powder in Solvent-Free Conditions

Protonation of the highly reactive 1:1 intermediates, produced in the reaction between triphenylphosphine and dialkyl acetylenedicarboxylates, by 1-hydroxy-2-acetonaphthone leads to vinyltriphenylphosphonium salts, which undergo aromatic electrophilic substitution reaction with conjugate base to produce dialkyl 2-(3-acetyl-4-hydroxy-1-naphthyl)-3-(triphenylphosphoranylidene) butanedioates. Microwave was found to catalyze conversion of dialkyl 2-(3-acetyl-4-hydroxy-1-naphthyl)-3-(triphenylphosphoranylidene) butanedioates to dialkyl 2-(3-acetyl-4-hydroxy-1-naphthyl)-2-butenedioates in the presence of silica gel powder in solvent-free conditions.