Theoretical study on the reaction of N-(4-dehydrophenyi)pyridinium ion with nitroxides within the steric effects

应用量子化学密度泛函理论(DFT),在B3LYP/cc-pVDZ基组水平上,对N-(4-脱氢苯基)吡啶离子与不同结构的氮氧自由基反应进行了热动力学研究.优化了反应通道上反应物、中间体、过渡态和产物的几何构型并计算出它们的零点振动能( Ezpv)和焓值,分析数据研究位阻效应对反应的影响.研究表明3类氮氧自由基均与N-(4-脱氢苯基)吡啶离子自由基反应经过1个无位垒的放热过程生成1个中间体,然后发生自由基的重排,开环的氮氧自由基DTBN相较于闭合的氮氧自由基TMIO和TEMPO化学性质活泼、反应过程复杂.表明反应物本身的位阻效应为此类自由基反应的主要影响因素.     

2,2,6,6-四甲基哌啶氧铵盐与吩噻嗪类化合物单电子转移反应动力学——Marcus理论的应用

2 ,2 ,6 ,6 四甲基哌啶氧铵盐 ( 1a ,1b)与吩噻嗪类化合物 ( 2a～ 2g)迅速反应 ,生成相应的氮氧自由基 ( 3a ,3b)和吩噻嗪类化合物的正离子自由基 ( 4a～ 4g) .通过EPR和NMR的谱线增宽效应 ,测定了乙腈中 1和 3以及 2和 4之间的电子自交换反应速率常数 ,应用Marcus理论研究了 1和 2之间的反应动力学     

N-芳基氮氧方酸的合成研究

N-芳基氮氧方酸(3-芳胺基-4-羟基-3-环丁烯二酮)是合成不对称方酸衍生物的关键中间体之一，开展了对其合成方法的研究，发现并实现了方酸与芳伯胺在水中的脱水反应，制得17个N-芳基氮氧方酸3a～3q，其中N-8'-喹啉基氮氧方酸(3q)具有热致变色性质，根据实验事实，提出了可能的反应历程。该合成方法产率较高，产物易于分离纯化，是制备N-芳基氮氧方酸简便有效的好方法。     

新型刚性芳环桥连甲硫基-二茂铁苯胺化合物的合成及其电化学性质研究

二茂铁苯胺(3a～3c)分别与对甲硫基苯甲醛反应合成了三个新型的含对甲硫苯基的二茂铁席夫碱化合物(4a～4c);4a和4b经硼氢化钠还原碳氮双键得到两个N-(对甲硫苄基)二茂铁苯胺化合物——N-(对甲硫苄基)对二茂铁苯胺(5a)和N-(对甲硫苄基)间二茂铁苯胺(5b),其结构经1H NMR,IR和MS表征。电化学循环伏安研究表明,4a～4c与5a,5b略有差异,其中5a不易得到电子。     

含吡啶环系西佛碱大环配合物和氮杂大环自由配体的合成

2, 6-二羟甲基吡啶(1)经活性MnO~2氧化得到2, 6-二甲酰基吡啶(2)。邻硝基苯酚与N-取代的二(氯乙基)胺在DMF溶液中反应, 得到N-取代的1, 5-二(邻硝基苯氧基)-3-氮杂戊烷(3a～3c), 再经水合肼/Raney Ni还原, 获得N-取代的1, 5-二(邻氨基苯氧基)-3-氮杂戊烷(4a～4c)。利用Ba^2^+作为模板离子, (2)分别与(4a～4c)反应, 合成了一类新的含吡啶环系西佛碱大环配合物I-III, 配合物I、III与NaBH~4的乙醇溶液还原解络, 得到氮杂大环自由配体IV和V。所有西佛碱大环配合物和氮杂大环自由配体均经元素分析、IR、^1H NMR、MS等证实了它们的结构和组成。     

N-(2-苦胺基乙基)单氮杂冠醚的合成

研究并比较了氮支套索型生色冠醚1a和1b两条不同的合成路线, 结果表明, 由N-苦基乙二胺(2)与1,11-二碘-3,6,9-三氧杂十一烷进行N-烷基化环化反应, 可方便地制备N-(2-苦胺基乙基)单氮杂-12-冠-4(1a), 但按此法未能获得更大环的-15-冠-5(1b);若从N-对甲苯磺酰基乙二胺(6)或N-(2-对甲苯磺酰胺基乙基)二乙醇胺(7)出发, 经环化, 脱除对甲苯磺酰基而制得的N-(2-氨基乙基)单氮杂冠醚5a和5b分别与苦基氯反应, 则可获得高产率的生色生色冠醚11a和1b.     

生物抗氧化剂的研究——维生素C还原氮氧自由基反应中的胶束效应

本文用停止-流动ESR技术研究了在正离子胶束CTAB、负离子胶束SDS及非离子胶束Triton X-100中,维生素C对三种不同亲脂性的哌啶氮氧自由基,即4-羟基TEMPO、4-甲氧基-TEMPO及4-已酰氧基-TEMPO的还原反应动力学,提出了在胶束中该反应的机理并求出了各基元反应的速率常数。发现有氮氧自由基参与的两步单电子转移反应的速率均与胶束的性质及氮氧自由基的亲脂性有关。在TritonX-100中反应速率没有改变,在CTAB中反应速率增大,在SDS中反应速率减小;氮氧自由基的亲脂性愈强,反应速率的改变愈显著,4-已酰氧基-TEMPO在CTAB和SDS中的反应速率之差高达3600倍。通过对氮氧自由基在胶束中的ESR参数及线型的分析,讨论了胶束效应产生的原因。     

含吡啶环系西佛碱大环配合物和氮杂大环自由配体的合成

2,6-二羟甲基吡啶(1)经活性MnO_2氧化得到2,6-二甲酰基吡啶(2)。邻硝基苯酚与N-取代的二(氯乙基)胺在DMF溶液中反应,得到N-取代的1,5-二(邻硝基苯氧基)-3-氮杂戊烷(3a～3c),再经水合肼/Raney Ni还原,获得N-取代的1,5-二(邻氨基苯氧基)-3-氮杂戊烷(4a～4c)。利用Ba~(2 )作为模板离子,(2)分别与(4a～4c)反应,合成了一类新的含吡啶环系西佛碱大环配合物Ⅰ～Ⅲ,配合物Ⅰ、Ⅲ经与NaBH_4的乙醇溶液还原解络,得到氮杂大环自由配体Ⅳ和Ⅴ。所有西佛碱大环配合物和氮杂大环自由配体均经元素分析、IR、~1H NMR、MS等证实了它们的结构和组成。     

4,4'-二甲氧基二苯基氮氧自由基调控甲基丙烯酸甲酯聚合

以4,4'-二甲氧基二苯胺为原料,过硫酸氢钾复合盐(Oxone)为氧化剂,通过一步反应合成了苯环类氮氧自由基——4,4'-二甲氧基二苯基氮氧自由基(DMDPN),并与引发剂偶氮二异丁腈(AIBN)组成双分子体系进行甲基丙烯酸甲酯(MMA)的调控聚合.用重量法测定转化率、凝胶渗透色谱(GPC)测定分子量及分布.研究了氮氧自由基/引发剂比以及聚合温度对聚合动力学和聚合物分子量及分布的影响,并对得到聚合物进行了再引发反应以及1H核磁共振表征.结果表明该体系下,氮氧自由基与增长自由基之间无明显的氢转移副反应发生,聚合过程中分子量随转化率线性增加,且聚合物末端具有活性,能进行再次链增长,体现出可控/"活性"自由基聚合的特点.确定了最佳氮氧自由基/引发剂摩尔比为1.6∶1、最佳聚合温度为120℃,并在70℃下实现了MMA的调控聚合.     

N-(2-对甲苯磺酰胺基乙基)单氮杂冠醚的合成及其晶体结构

N-对甲苯磺酰基乙二胺分别与1,11-二碘-3,6,9-三氧杂十一烷和1,14-二碘-3,6,9,12-四氧杂十四烷反应,制得N-(2-对甲苯磺酰胺基乙基)单氮杂-12-冠-4或15-冠-5;当用N-(2-对甲苯磺酰胺基乙基)二乙醇胺与1,11-二对甲苯磺酸酯-3,6,9-三氧杂十一烷反应时,才能获得N-(2-对甲苯磺酰胺基乙基)单氮杂-18-冠-6.从甲醇溶液中培养得N-(2-对甲苯磺酰胺基乙基)单氮杂-12-冠-4单晶,属单斜晶系,P2₁/a空间群;a=1.4229(1)nm,b=0.9595(2)nm,c=1.4564(1)nm,β=102.20(1)°,V=1.9435nm³,Z=4.最终偏离因子R=0.043.     

Theoretical and experimental investigations on the reactions of positively charged phenyl radicals with aromatic amino acids

The chemical behavior of positively charged phenyl radicals 3-dehydro-N-phenylpyridinium (a), N-(3-dehydro-5-chlorophenyl)pyridinium (b), and N-(3-dehydrophenyl)pyridinium (c) toward L-tyrosine, phenylalanine, and tryptophan was investigated in the gas phase both theoretically by performing molecular orbital calculations and experimentally by using FT/ICR mass spectrometry. All radicals react with phenylalanine and tryptophan nearly at the collision rate. The overall reactivity of the radicals toward tyrosine follows the order a > b > c, which is consistent with the electron affinity (EA) ordering of the radicals. The higher the electrophilicity (or EA) of the radical, the greater the reactivity. As expected, all radicals abstract a hydrogen atom from all of the amino acids. However, the most electrophilic radical a was also found to react with these amino acids via NH2 abstraction. A new reaction observed between radicals a-c and aromatic amino acids is the addition of the radical to the aromatic ring of the amino acid followed by Calpha-Cbeta bond cleavage, which leads to side-chain abstraction by the radical.     

Gas-phase reactivity of charged pi-type biradicals

Four pi,pi-biradicals, 2,6-dimethylenepyridinium and the novel isomers N-(3-methylenephenyl)-3-methylenepyridinium, N-phenyl-3,5-dimethylenepyridinium, and N-(3,5-dimethylenephenyl)pyridinium ions, were generated and structurally characterized in a Fourier transform ion cyclotron resonance mass spectrometer. Their gas-phase reactivity toward various reagents was compared to that of the corresponding monoradicals, 2-methylenepyridinium, N-phenyl-3-methylenepyridinium, and N-(3-methylenephenyl)pyridinium ions. The biradicals reactivity was found to reflect their predicted multiplicity. The 2,6-dimethylenepyridinium ion, the only biradical in this study predicted to have a closed-shell singlet ground state, reacts significantly faster than the other biradicals, which are predicted to have triplet ground states. In fact, this biradical reacts at a higher rate than the analogous monoradical, which suggests that to avoid the costly uncoupling of its unpaired electrons, the biradical favors ionic mechanisms over barriered radical pathways. In contrast, the second-order reaction rate constants of the isomeric biradicals with triplet ground states are well approximated by those of the analogous monoradicals, although the final reaction products are sometimes different. This difference arises from rapid radical-radical recombination of the initial monoradical reaction products. The overall reactivity toward the hydrogen-atom donors benzeneselenol and tributylgermanium hydride is significantly greater for the radicals with the charged site in the same ring system as the radical site. This finding indicates that polar effects play an important role in controlling the reactivity of pi,pi-biradicals, just as has been demonstrated for sigma,sigma-biradicals.     

Joint theoretical experimental investigation of the electron spin resonance spectra of nitroxyl radicals: application to intermediates in in situ nitroxide mediated polymerization (in situ NMP) of vinyl monomers

Density functional theory (DFT) calculations have been performed to address the structure of nitroxide intermediates in controlled radical polymerization. In a preliminary step, the reliability of different theoretical methods has been substantiated by comparing calculated hyperfine coupling constants (HFCCs) to experimental data for a set of linear and cyclic alkylnitroxyl radicals. Considering this tested approach, the nature of different nitroxides has been predicted or confirmed for (a) the reaction of C-phenyl- N- tert-butylnitrone and AIBN, (b) N- tert-butyl-alpha-isopropylnitrone and benzoyl peroxide, (c) tert-butyl methacrylate polymerization in the presence of sodium nitrite as mediator, and (d) for the reaction of a nitroso compound with AIBN. Values of HFCC experimentally determined have been confirmed by DFT calculations.     

Reactivity and selectivity of charged phenyl radicals toward amino acids in a Fourier transform ion cyclotron resonance mass spectrometer

The reactivity of 10 charged phenyl radicals toward several amino acids was examined in the gas phase in a dual-cell Fourier transform ion cyclotron resonance mass spectrometer. All radicals abstract a hydrogen atom from the amino acids, as expected. The most electrophilic radicals (with the greatest calculated vertical electron affinities (EA) at the radical site) also react with these amino acids via NH(2) abstraction (a nonradical nucleophilic addition-elimination reaction). Both the radical (hydrogen atom abstraction) and nonradical (NH(2) abstraction) reaction efficiencies were found to increase with the electrophilicity (EA) of the radical. However, NH(2) abstraction is more strongly influenced by EA. In contrast to an earlier report, the ionization energies of the amino acids do not appear to play a general reactivity-controlling role. Studies using several partially deuterium-labeled amino acids revealed that abstraction of a hydrogen atom from the α-carbon is only preferred for glycine; for the other amino acids, a hydrogen atom is preferentially abstracted from the side chain. The electrophilicity of the radicals does not appear to have a major influence on the site from which the hydrogen atom is abstracted. Hence, the regioselectivity of hydrogen atom abstraction appears to be independent of the structure of the radical but dependent on the structure of the amino acid. Surprisingly, abstraction of two hydrogen atoms was observed for the N-(3-nitro-5-dehydrophenyl)pyridinium radical, indicating that substituents on the radical not only influence the EA of the radical but also can be involved in the reaction. In disagreement with an earlier report, proline was found to display several unprecedented reaction pathways that likely do not proceed via a radical mechanism but rather by a nucleophilic addition-elimination mechanism. Both NH(2) and (15)NH(2) groups were abstracted from lysine labeled with (15)N on the side chain, indicating that NH(2) abstraction occurs both from the amino terminus and from the side chain. Quantum chemical calculations were employed to obtain insights into some of the reaction mechanisms.     

N-3-Oxoalkylamides and -Thioamides in the Synthesis of Heterocyclic Compounds. 6. The Effect of Structural Factors on the Regiodirection of Cyclization of Pyridinium Derivatives of N-(3-Oxoalkyl)chloroacetamides. Structure of 1-(4-Hydroxy-4,6,6-trimethyl-2-oxo-3-piperidyl)pyridinium Chloride

The structure of 1-(4-hydroxy-4,6,6-trimethyl-2-oxo-3-piperidyl)pyridinium chloride has been established. Reasons have been found influencing the regiodirection of cyclization of pyridinium derivatives of N-(3-oxoalkyl)chloroacetamides.     

Kinetics and mechanism of oxidation of phosphorus oxyacids by pyridinium hydrobromide perbromide

Oxidation of three lower oxyacids of phosphorus, viz. phosphinic, phenylphosphinic and phosphorous acids by pyridinium hydrobromide perbromide (PHPB), is first-order with respect to both oxyacid and PHPB. There is no effect on addition of acylonitrile and pyridinium bromide. On oxidation, deuterated phosphinic and phosphorous acids exhibit substantial kinetic isotope effects. The effect of solvent composition on reaction rate indicates that the transition state is more polar than the reactants. Reaction rates were determined at different temperatures and the activation parameters calculated. Alternative mechanisms, involving the two tautomeric forms of the oxyacid, have been formulated and it has been concluded that the reaction proceeds through the pentacoordinated tautomer. Transfer of a hydride ion from the oxyacid to PHPB, in the rate-determining step, has been proposed.     

Nature of the reducing agent and mechanism of the reductive condensation of trichloromethylarenes with hydroxylamine and hydrazines in pyridine

Summary It was shown that during the reductive condensation of trichloromethylarenes .with hydroxylamine or hydrazines in pyridine the event of reduction with replacement of one chlorine atom by a hydrogen atom occurs without the participation of hydroxylamine or hydrazine. The first step of the reaction is the formation of N- (a, adichloroarylmethyl)pyridinium chlorides, which are converted by the action of the chloride anion or a second pyridine molecule to the corresponding 4-substituted 1,4-dihydropyridines. The latter undergo further aromatization with transfer of hydrogen from the 4-position of the dihydropyridine ring to the benzyl dichloromethylene group and the formation of N-(a-chloroarylmethyl)-4-chloropyridinium chlorides or N-(-chloroarylrnetluyl)-4-(pyridirao)pyridinium dichlorides, which give the corresponding aldehydes in hydrolysis or products of reductive condensation under the action of hydroxylamine or hydrazines.N. D. Zelinksii Institute of Organic Chemistry, Russian Academy of Sciences, Moscow, 117913. Translanted from Khimiya Geterotsiklicheskikh Soedinenii, No. 6, pp. 830–842, June, 1995. Original article submitted April 14, 1995.     

Aromatic substitution by N-arylhydroxylamines—II : Generation of nitrenes from arylhydroxylamines and N-benzenesulfonylhydroxylamines and phosphorous pentoxide

Substitution of benzene by N-benzene- and N-(4-methylbenzenesulfonyl)hydroxylamines occurs in the presence of phosphorous pentoxide whereas N-methyl-N-benzenesulfonylhydroxylamine gave no substitution product under the same conditions. When N-(4-methylbenzenesulfonyl)hydroxylamine was treated with phosphorous pentoxide in pyridine, N-(4-methylbenzenesulfonimido)pyridinium ylide was formed. Nitrene intermediates are postulated to account for these products. Similarly carbazole was formed from 2-hydroxylamino[1,1′-biphenyl] and phosphorous pentoxide but with phosphorous pentachloride, 3- and 3-chloro-2-amino[1,1′-biphenyls] were formed, most likely via a nitrenium ion intermediate.     

The solid-phase Zincke reaction: preparation of omega-hydroxy pyridinium salts in the search for CFTR activation

A study of structural modifications of MPB-07 was undertaken as part of a synthetic program aimed at discovering small molecules with CFTR activation potential. Solid-phase synthesis techniques were used to prepare derivatives of MPB-07 employing the Zincke reaction for the construction of aromatic, quaternary ammonium salts such as those found in 2 or 3. In this transformation, primary amines react with highly electrophilic N-2,4-dinitrophenylpyridinium (DNP) salt 4 to afford pyridinium salt 8 with release of 2,4-dinitroaniline 6. Thus, the reaction of 1-(2,4-dinitrophenyl)pyridinium salts with various polymer-bound amino ethers, followed by cleavage from the resin, delivers the desired salts in good yield and high purity.     

Reaction of cyclic nitroxides with nitrogen dioxide: the intermediacy of the oxoammonium cations

Piperidine and pyrrolidine nitroxides, such as 2,2,6,6-tetramethylpiperidinoxyl (TPO) and 3-carbamoylproxyl (3-CP), respectively, are cell-permeable stable radicals, which effectively protect cells, tissues, isolated organs, and laboratory animals from radical-induced damage. The kinetics and mechanism of their reactions with .OH, superoxide, and carbon-centered radicals have been extensively studied, but not with .NO2, although the latter is a key intermediate in cellular nitrosative stress. In this research, .NO2 was generated by pulse radiolysis, and its reactions with TPO, 4-OH-TPO, 4-oxo-TPO, and 3-CP were studied by fast kinetic spectroscopy, either directly or by using ferrocyanide or 2,2'-azinobis(3-ethylbenzothiazoline-6-sulfonate), which effectively scavenge the product of this reaction, the oxoammonium cation. The rate constants for the reactions of .NO2 with these nitroxides were determined to be (7-8) x 10(8) M(-)(1) s(-)(1), independent of the pH over the range 3.9-10.2. These are among the highest rate constants measured for .NO2 and are close to that of the reaction of .NO2 with .NO, that is, 1.1 x 10(9) M(-1) s(-1). The hydroxylamines TPO-H and 4-OH-TPO-H are less reactive toward .NO2, and an upper limit for the rate constant for these reactions was estimated to be 1 x 10(5) M(-1) s(-1). The kinetics results demonstrate that the reaction of nitroxides with .NO2 proceeds via an inner-sphere electron-transfer mechanism to form the respective oxoammonium cation, which is reduced back to the nitroxide through the oxidation of nitrite to .NO2. Hence, the nitroxide slows down the decomposition of .NO2 into nitrite and nitrate and could serve as a reservoir of .NO2 unless the respective oxoammonium is rapidly scavenged by other reductant. This mechanism can contribute toward the protective effect of nitroxides against reactive nitrogen-derived species, although the oxoammonium cations themselves might oxidize essential cellular targets if they are not scavenged by common biological reductants, such as thiols.