N-苯基丙烯酰胺与草氨酸衍生物的脱羧氨甲酰化反应研究

报道了一种银催化的N-苯基丙烯酰胺与N-取代草氨酸类衍生物的脱羧氨甲酰化反应,通过分子间的氨甲酰自由基加成/环化过程,能够以良好的产率制备一系列3,3-二取代的氨甲酰官能化的吲哚酮类化合物.该反应具有广泛的官能团兼容性和良好的底物适用范围.     

无金属催化N-芳基丙烯酰胺的多氯甲基化/环化反应

以过氧苯甲酰为氧化剂,氯仿或二氯甲烷为多氯甲基源,在与N-芳基丙烯酰胺的反应中通过自由基加成环化,合成了一系列多氯甲基取代的2-吲哚酮类化合物.反应无需金属催化剂,简单高效,底物范围较广.     

N-（p-羟基苯基）甲基丙烯酰胺的合成与表征

N-芳基取代的甲基丙烯酰胺(结构式如图1所示)是一类非常有用的共聚单体,它们可以与甲基丙烯酸酯或N-取代马来酰亚胺等单体共聚,使共聚物的一些性能,如耐热性、耐水性、透明度、硬度等都有不同程度的改进[1-4].关于N-芳基取代的甲基丙烯酰胺的制备,文献[5-8]曾有报道,通常采用甲基丙烯酰氯与芳基胺在乙醚、苯等溶剂中反应,并加入适当的缚酸剂来完成.而N-(p-羟基苯基)甲基丙烯酰胺(此处R＝OH)是N-芳基取代甲基丙烯酰胺中一种比较特殊的单体,它即含有碳碳双键,又含有酚羟基,属于双官能团物质.关于它的制备及用途,尚未见有文献报道.文献[5]曾报道说,采用对胺基苯酚与甲基丙烯酰氯反应仅能得到甲基丙烯酸(N-(p-甲基丙烯酰胺基)苯酚酯(即酰胺-酯化合物).本文合成出了这种物质,并对其进行了表征和证实;我们推测它与一些单体(如N-取代马来酰亚胺等)的共聚物可以溶于碱性水溶液,并且有好的耐热性,因此在紫外光刻胶中可能有比较大的应用潜力[9-11],有关这方面的内容我们将另文报道.     

银催化的串联自由基环化合成3,3'-双取代氧化吲哚

发展了一种通过银催化氧化环丙醇开环对N-芳基丙烯酰胺的双键的双官能团化合成3,3'-双取代氧化吲哚的新方法,这个反应经历了环丙醇的自由基氧化开环和碳氢官能团化串联环化过程,条件温和,官能团兼容性好.     

亲水性二苯甲胺树脂制备及用于肽合成研究

通过反相悬浮共聚合成了含酯基的聚丙烯酰胺树脂, 再经乙二胺取代和两步缩合反应引入二苯甲胺功能基团。讨论了反应条件对各步反应的影响。测定了该载体与几种保护氨基酸的缩合率并合成了模型肽。缩合率和模型肽的纯度都令人满意。     

自由基加成/关环反应合成1,3-二氢吲哚-2-酮的研究进展

近两年来,关于自由基加成/关环反应合成1,3-二氢吲哚-2-酮的报道屡见不鲜.它们大多以N-芳基取代的丙烯酰胺类化合物为底物,在各种不同的金属、无金属和光的催化作用下,与不同的自由基反应,可以一步生成3,3-二取代的吲哚-2-酮衍生物.该类方法现已成为合成含氮五元杂环的一个重要手段,用来合成1,3-二氢吲哚-2-酮及其衍生物.目前对自由基加成/关环反应合成该类化合物的研究多集中在不同催化手段引发不同的自由基和反应机理上.按催化剂类型的不同,对近年来自由基加成/关环反应合成吲哚-2-酮的研究进展进行了综述.     

含胺基功能性单体的聚合研究——X.N-(N′-次甲基吗啉)取代丙烯酰胺的合成及其聚合

<正> 聚丙烯酰胺及其N-取代衍生物是一类医用水凝胶,据Ferruti等报道,含有叔胺基的丙烯酸衍生物的聚合物具有抑制路易斯肺癌扩散的作用,我们曾合成了芳香及脂肪叔胺基取代的丙烯酰胺,并对它们的聚合及其作为氧化还原引发体系组分进行了研究,这些叔胺基取代的丙烯酰胺的聚合物,经复钙法测试,证明具有较好的抗凝血性。     

铜催化N-烯基丙烯酰胺氰异丙基化/烯基化反应合成1,3-二氢吡咯-2-酮（英文）

报道了铜催化的化学选择性N-烯基丙烯酰胺氰异丙基化/环化级联反应,利用该反应可以实现1,3-二氢吡咯-2-酮的合成.丙烯酰胺的自由基环合反应中,用于捕获分子内自由基的基团主要局限于芳基、炔基和氰基,而本工作使用烯胺双键作为内置自由基捕获基团,以丙烯酰胺双键作为自由基受体.该反应的化学选择性可能是由自由基反应的极性匹配原则决定.     

无金属催化烯烃自由基环化合成多氟取代吲哚酮

一种无金属催化的活泼烯烃与全氟碘代丁烷自由基环化合成含氟吲哚酮的反应被发展。 在廉价易得的的偶氮二异丁腈(AIBN)介导下, 多种N-芳基丙烯酰胺类化合物与全氟碘代丁烷发生自由基串联环化反应,以53%~85%的产率合成了一系列的潜在生理活性的多氟取代吲哚酮。 此工作为潜在药用价值的多氟取代吲哚酮合成提供了一条高效、廉价、绿色的新途径。     

钯催化下芳基磺酰氯与丙烯酰胺的偶联反应

以二苯腈二氯化钯为催化剂，在固液相转移条件下，芳基磺酰氯能与Ｎ，Ｎ－双烷基取代丙烯酰胺发生偶联反应，生成柏应的Ｅ式不饱和酰胺。     

Synthesis of dragmacidin D via direct C-H couplings

Dragmacidin D, an emerging biologically active marine natural product, has attracted attention as a lead compound for treating Parkinson's and Alzheimer's diseases. Prominent structural features of this compound are the two indole-pyrazinone bonds and the presence of a polar aminoimidazole unit. We have established a concise total synthesis of dragmacidin D using direct C-H coupling reactions. Methodological developments include (i) Pd-catalyzed thiophene-indole C-H/C-I coupling, (ii) Pd-catalyzed indole-pyrazine N-oxide C-H/C-H coupling, and (iii) acid-catalyzed indole-pyrazinone C-H/C-H coupling. These regioselective catalytic C-H couplings enabled us to rapidly assemble simple building blocks to construct the core structure of dragmacidin D in a step-economical fashion.     

Mechanistic Study of Palladium-Catalyzed Oxidative C-H/C-H Coupling of Polyfluoroarenes with Simple Arenes

Pd-catalyzed oxidative C-H/C-H coupling reaction is an emerging type of C-H acti-vation reaction, which attracts great interests because both reaction partners do not re-quire pre-functionalization. In the present study, we employed DFT methods to investigatethe mechanism of Pd(OAc)₂-catalyzed oxidative C-H/C-H coupling of pentafluoroben-zene with benzene. Four possible pathways were examined in the C-H activation part: path A benzene-pentafluorobenzene mechanism (C-H activation of benzene occurs before the C-H activation of pentafluorobenzene), path B pentafluorobenzene-benzene mechanism (C-H activation of benzene occurs after the C-H activation of pentafluorobenzene), path C benzene-pentafluorophenylsilver mechanism (C-H activation of benzene and subsequenttransmetalation with pentafluorophenyl silver complex), path D pentafluorophenylsilver-benzene mechanism (transmetalation with pentafluorophenyl silver complex and subsequent C-H activation of benzene). Based on the calculations, the sequences of two C-H activation steps are found to be different in the oxidative couplings of same substrates (i.e. pentaflu-orobenzene and benzene) in different catalytic systems, where the additive Ag salts played a determinant role. In the absence of Ag salts, the energetically favored pathway is path B (i.e. the C-H activation of pentafluorobenzene takes place before the C-H cleavage of benzene). In contrast, with the aid of Ag salts, the coordination of pentafluorophenylsilver to Pd center could occur easily with a subsequent C-H activation of benzene in the second step, and the second step significantly raises the whole reaction barrier. Alternatively, in thepresence of Ag salts, the kinetically preferred mechanism is path C (i.e. the C-H activation of benzene takes place in the first step followed by transmetalation with pentafluorophenyl-silver complex), which is similar to path A. The calculations are consistent with the H/D exchange experiment and kinetic isotope effects. Thus the present study not only offers a deeper understanding of oxidative C-H/C-H coupling reaction, but also provides helpful insights to further development of more efficient and selective oxidative C-H/C-H coupling reactions.     

Manifestation of stereoelectronic effects on the calculated carbon-hydrogen bond lengths and one bond (1)J(C-H) NMR coupling constants in cyclohexane,six-membered heterocycles,and cyclohexanone derivatives

Cyclohexane (1), oxygen-, sulfur-, and/or nitrogen-containing six-membered heterocycles 2-5, cyclohexanone (6), and cyclohexanone derivatives 7-16 were studied theoretically [B3LYP/6-31G(d,p) and PP/IGLO-III//B3LYP/6-31G(d,p) methods] to determine the structural (in particular C-H bond distances) and spectroscopic (specifically, one bond (1)J(C-H) NMR coupling constants) consequences of stereoelectronic hyperconjugative effects. The results confirm the importance of n(X) --> sigma*(C-H)(app) (where X = O, N), sigma(C-H)(ax) --> pi*(C=O), sigma(S-C) --> sigma*(C-H)(app), sigma(C-S)-->sigma*(C-H)(app), beta-n(O) --> sigma*(C-H), and sigma(C-H) --> sigma*(C-H)(app) hyperconjugation, as advanced in previous theoretical models. Calculated r(C-H) bond lengths and (1)J(C-H) coupling constants for C-H bonds participating in more than one hyperconjugative interaction show additivity of the effects.     

Intermolecular and intramolecular, platinum-catalyzed, acceptorless dehydrogenative coupling of hydrosilanes with aryl and aliphatic methyl C-H bonds

Intermolecular acceptorless dehydrogenative coupling of silanes with arene C-H bonds and intramolecular coupling of silanes with aryl and alkyl C-H bonds occur in good yield in the presence of 5 mol % of TpMe2PtMe2H (TpMe2 = hydridotris(3,5-dimethylpyrazolyl)borate) and related platinum(IV) complexes. The intermolecular reactions of arenes occurred with both trialkyl and dialkylaryl silanes. Intramolecular reactions of dialkylsilylalkylarenes occurred at aryl C-H bonds, and reactions of tributylsilane or dibutylphenylsilane occurred intramolecularly at the aliphatic, primary C-H bond. The reactions of arenes occurred preferentially at the least sterically hindered C-H bonds and preferentially with more electron-poor arenes. Crossover experiments and the lack of reactivity of the arylsilanes with H2 imply that the dehydrogenative silylation of arenes can be irreversible, even in a closed reaction vessel.     

Copper-catalyzed oxidative coupling of benzylic C-H bonds with 1,3-dicarbonyl compounds

A copper-catalyzed oxidative coupling of benzylic C-H bonds with 1,3-dicarbonyl compounds is described. The reaction utilizes an inexpensive copper catalyst-oxidant system that is suitable for the coupling of a range of benzylic C-H bonds with various 1,3-dicarbonyl compounds. Kinetic isotope studies support a mechanism involving a benzylic hydrogen abstraction.     

Structural basis for the discrepancy of spectral behavior in C-H stretching band between steroids and long chain hydrocarbon compounds

The discrepancies of the spectral behavior for the C-H stretching band between some long chain hydrocarbon compounds and steroids were investigated. At low temperature, the C-H stretching bands exhibit complex fine structure in steroids but remain simple in long chain hydrocarbon compounds. MM3 molecular mechanics calculation indicates that, for long chain hydrocarbon compounds, the C-H groups vibrate with large scale coupling. There exist a few bands where the C-H groups vibrate in synchronous and inphase mode. Thus the variations of dipole moment for these bands are enhanced and the intensities are obviously stronger than others and cover other band in the spectra. This is just the reason why the C-H stretching bands are simple even at low temperature environment. Nevertheless, for the steroids, the C-H stretching bands vibrate with local coupling mode. The synchronous enhancement effect does not occur, the differences of intensities for various modes are not as large as those in long chain hydrocarbo     

Rhodium-catalyzed regioselective C-H functionalization via decarbonylation of acid chlorides and C-H bond activation under phosphine-free conditions

Efficient rhodium(I)-catalyzed regioselective functionalization of aromatic C-H bonds has been realized with acid chlorides as the coupling partners via decarbonylation and C-H activation under phosphine-free conditions.     

Dehydrative C-H alkylation and alkenylation of phenols with alcohols: expedient synthesis for substituted phenols and benzofurans

A well-defined cationic Ru-H complex catalyzes the dehydrative C-H alkylation reaction of phenols with alcohols to form ortho-substituted phenol products. Benzofuran derivatives are efficiently synthesized from the dehydrative C-H alkenylation and annulation reaction of phenols with 1,2-diols. The catalytic C-H coupling method employs cheaply available phenols and alcohols, exhibits a broad substrate scope, tolerates carbonyl and amine functional groups, and liberates water as the only byproduct.     

Tandem dual C(sp3)-H/C(sp2)-H functionalization: a radical cyclization of 2-isocyanobiphenyl with ether to 6-alkylated phenanthridine

<正>1 General experimental details 1H NMR and 13 C NMR spectra were measured on 400 MHz spectrometer, using CDCl3 as the solvent with tetramethylsilane(TMS) as the internal standard at room temperature. Chemical shifts(δ) are given in ppm relative to TMS, the coupling constants J are given in Hz. HRMS were recorded on a TOF LC/MS equipped with electrospray ionization(ESI) probe operating in positive or negative ion mode.     

Rh-Catalyzed Intermolecular Carbenoid Functionalization of Aromatic C-H Bonds by α-Diazomalonates

A Rh-catalyzed intermolecular coupling of diazomalonates with arene C-H bonds is reported. The reaction is initiated by electrophilic C-H activation, which is followed by coupling of the arylrhodium(III) complex with the diazomalonate. In most cases, arenes with oximes, carboxylic acids, and amines as directing groups cross-couple with diazomalonates with excellent regioselectivities and functional group tolerance, and thus, this reaction offers a new route to α-aryl carbonyl compounds for specific applications.