水相中·OH, ·H和e-aq与2-氯酚反应机理研究

利用脉冲电子束辐解水产生*OH自由基、 *H及水合电子(e-aq), 研究了这些活性粒子在多种条件下与水相中2-氯酚的微观反应机理, 对其瞬态光谱中的主要吸收峰做了归属, 并初步考察了这些瞬态物种的生长、衰减等行为. 研究表明, *OH自由基与2-氯酚在碱性条件下可直接反应生成邻氯代酚氧自由基, 速率常数为1.0×109 L*mol-1*s-1, 也有部分*OH自由基与2-氯酚反应先生成OH-加合物, 再进一步消除水分子生成邻氯代酚氧基; 在酸性条件下要经过OH-加合物. *H则与2-氯酚反应生成H-加合物; e-aq可直接从2-氯酚分子夺氯, 在近中性和碱性环境中, 该反应的速率常数分别为1.25×109 L*mol-1*s-1和6.3×108 L*mol-1*s-1.     

水催化HBrO与OH自由基反应的微观机理

采用密度泛函理论,分别在B3LYP/6-311++g(d,p)和B3LYP/aug-cc-PVTZ理论水平下,系统研究了无水和水催化的OH自由基与HBrO反应,即HBrO+OH和HBrO+OH+H_2O 2个反应的微观反应机理,给出了所有可能发生的反应路径,并指出能量最低的反应通道.对于没有水参与的反应,由于OH自由基进攻HBrO方式不同,存在顺式方向和反式方向2种进攻方式的反应路径;当有一分子水参与反应时,考虑HBrO H_2O复合物与OH自由基的反应和HBrO与H_2O OH复合物2种反应情况,共发现4条不同的反应路径.这2种反应的所有路径均是在OH自由基提取氢之前以氢键复合物形式存在,反应过程均为无势垒加合过程,总反应为放热反应.水对目标反应起催化作用,有效地降低了反应的势垒,可以加快OH自由基和HBrO的消耗速度.     

黄芩苷与铝离子配合物的电喷雾质谱研究

利用电喷雾多级串联质谱(ESI-MS^n)研究了黄芩苷与铝离子在不同浓度配比时形成的络合物,并通过质谱碎裂规律对其结构进行了初步确认。研究结果表明,黄芩苷与铝离子主要形成比较稳定的1：1和1：2配合物,分别为[AIR^1R^2L]^ 和[AlL2]^ ,其中L=[M-H]^-,R^1=CH3OH,R^2=CH3O。     

黄芩苷元的Mannich反应

利用天然产物黄芩苷元（baicalein)在A环8－位碳上进行Mannich反应，合成 了11个新的Mannich碱化合物。反应温和，产物易纯化，收率达80％以上。同时考 察了伯胺与甲醛配比为1：2时，产物为二氢苯并E嗪类化合物和黄芩苷元A环上5－ ，6－，7－位羟基对8－位氢进行Mannich反应活性的影响。并对Mannich碱化合物 2b和2j进行盐酸成盐4b和4j，初步考察了它们的溶解度与黄芩苷元的差别。     

取代基(NH2,OH,F)对锂氟类硅烯构型及稳定性的影响

用从头计算方法研究了3种锂氟类硅烯R2SiLiF(R=NH2,OH,F)各异构体的构型和能量.由于取代基NH2,OH和F与Si的共轭作用,这3种类硅烯的三元环构型的热稳定性下降,其下降程度按取代基排列为NH2＞OH＞F.因取代基R与Li原子间的相互作用,形成2个LiASiF(A=N,O,F)四元环,该四元环构型是这3种类硅烯的各异构体中最稳定的一种,其稳定程度按取代基排列为F＞OH＞NH2.取代基的诱导效应则影响各类硅烯的线性构型的热稳定性.     

γ辐射下CMPO/[C2mim][NTf2]的辐解及其对Eu3+萃取的影响

主要考察了辛基(苯基)-N, N-二异丁基胺甲酰基甲基氧化膦(CMPO)在1-乙基-3-甲基咪唑双三氟甲基磺酰胺酸盐([C₂mim][NTf₂])中的γ辐解行为,同时考察辐射对CMPO/[C₂mim][NTf₂]萃取能力的影响。通过超高效液相色谱-四极杆飞行时间质谱联用仪(UPLC/Q-TOF-MS)进行定量分析、辐解产物认定以及产物半定量分析。CMPO/正十二烷作为对比条件进行了相同研究。结果表明：CMPO在[C₂mim][NTf₂]中的辐解率低于其在正十二烷中,并且辐解路径不同。在正十二烷体系中,CMPO主要发生C―P、C―N键的断链,而在离子液体体系中CMPO主要发生异丁基脱除反应,并与[C₂mim]^+·、·CF₃等离子液体产生的自由基发生取代反应。综合辐解研究结果,我们提出CMPO/[C₂mim][NTf₂]的辐解路径,这加深了CMPO在离子液体中辐解机理的认识。最后,通过萃取实验发现,当硝酸浓度为0.01 mol·L^-1,辐照剂量为800 kGy时,CMPO/[C₂mim][NTf₂]对Eu³⁺的萃取率依旧达到99%以上。     

红霉素A9-（1-异丙氧基环已基）肟的合成及其晶体结构

合成表征了红霉素A9-（1-异丙氧基环已基）肟的E和Z异构体，并在丙酮-水混 合溶液中培养出了前者的单晶，X射线衍射表明，其结构为正交晶系，P2_12_12_1 空间群，晶胞参数：a=2.3101(5) nm, b=2.3761(5) nm, c=0.97066(19)nm, V=5. 3279(8) nm~3，Z=4，μ=0.088 mm~(-1)，F(000)=2064, D_c=1.176 g/cm~3。E-红 霉素A 9-（1-异丙氧基环已基）肟的晶体结构图明显表明1-异丙氧基环已基保护基 确实使十四元大环的构象发生了扭曲，使6-OH的周围空间不再拥挤，从而导致6- OH甲基化的选择性提高。     

N-糖基-2-取代-氨基硫脲及N-糖基-N′-取代-联二硫脲类化合物的合成

芳香酸经酯化、肼解 ,合环后再引入肼基 ,得 2 肼基 5 芳基 1,3 ,4 二唑 ( 2 ) ,芳基硫脲经环化、肼解得 2 肼基 4/ 6 取代 -苯并噻唑 ( 3 ) .糖基异硫氰酸酯 ( 1)分别与 2 ,3及N 取代氨基硫脲 ( 4 )发生亲核加成反应 ,制得系列新的N 糖基 2 取代 -氨基硫脲衍生物 5 ,6及N 糖基 N′ 取代 -联二硫脲类化合物 7.所有化合物的结构均经IR ,1HNMR ,MS谱和元素分析证实 .IR谱中 90 0cm-1附近的吸收及1HNMR谱中偶合常数JCl—H=9～ 10Hz ,证明产物为 β 构型     

黄芩苷和栀子苷抗炎活性和抗炎机理的理论研究

药理实验研究表明，黄芩-栀子药对主要成分黄芩苷和栀子苷配伍可抗脑缺血炎性损伤，其作用机制可能与抑制COX-2的表达和活性有关。在此基础上，本文运用密度泛函理论和分子对接方法，以黄芩苷和栀子苷为研究对象，以环氧合酶COX-2为靶点，从分子水平上揭示黄芩苷和栀子苷的结构与抗炎活性之间的关系，探讨黄芩苷-栀子苷配伍治疗脑缺血炎性损伤的作用机制。综合研究结果可知，黄芩苷对COX-2的抑制作用大于栀子苷对COX-2的抑制作用，黄芩苷的抗炎活性强于栀子苷，从而为黄芩苷和栀子苷的抗炎活性和作用研究提供了实验基础和理论依据。     

甘油糖脂的合成 Ⅰ.1,2-二-O-脂酰基-3-O-(α-D-吡喃半乳糖基)-sn-甘油的合成

采用一种有效的方法合成了具有不同链长的二脂酰基α D 半乳糖型甘油糖脂 .将半乳糖烯丙苷化 ,重结晶得到α D 半乳糖烯丙苷 .随后将糖环的羟基用苄基保护 ,再利用OsO4 /NMO(N 甲基 N 氧吗啉 )的二羟基化条件将 1 O烯丙基氧化成为邻二羟基 ,得到 3 O ( 2′ ,3′ ,4′ ,6′ 四 O 苄基 α D 吡喃半乳糖基 ) sn 甘油 .其与不同链长的脂酰氯进行脂酰化反应 ,然后氢解去掉苄基得到五种二脂酰基α D 半乳糖苷基甘油 .利用1HNMR ,13 CNMR ,2DNMR ,IR和MS对化合物的结构进行了确证 .     

Rate constants for reactions of alkyl radicals with water and methanol complexes of triethylborane

Reactions of secondary alkyl radicals with triethylborane and several of its complexes were studied. The H-atom transfer reactions from Et3B-OH2 and Et3B-OD2 were suppressed by addition of pyridine to the reaction mixture. Rate constants for reactions of secondary alkyl radicals with triethylborane and its complexes with water, deuterium oxide, methanol, and THF at ambient temperature were determined by radical clock methods. Cyclization of the 1-undecyl-5-hexenyl radical and ring opening of the 1-cyclobutyldodecyl radical were evaluated as clock reactions. The cyclobutylcarbinyl radical ring opening had the appropriate velocity for relatively precise determinations of the ratios of rate constants for H-atom transfer trapping and rearrangement, and these ratios combined with an estimated rate constant for the cyclobutylcarbinyl radical ring opening gave absolute values for the rate constants for the H-atom transfer reactions. For example, the triethylborane-water complex reacts with a secondary alkyl radical in benzene at 20 degrees C with a rate constant of 2 x 10(4) M(-1) s(-1). Variable temperature studies with the Et3B-CH3OH complex in toluene indicate that the hydrogen atom transfer reaction has unusually high entropic demand, which results in substantially more efficient hydrogen atom transfer trapping reactions in competition with radical ring opening and cyclization reactions at reduced temperatures.     

Computational Study on OH Addition Reactions of Three Sulfonamides in Aqueous Solution

OH addition reactions of cationic,neutral and anionic forms of three sulfonamides(sulfamethoxazole,sulfadiazine and sulfapyridine)in aqueous solution were theoretically studied using density functional theory(DFT)method at the M06-2X/6-311+G(3df,2p)level.Transition state theory was applied to estimate the secondary rate constants for these elementary reactions.The obtained results indicate that OH addition reactions of sulfonamides can take place spontaneously at standard conditions.The anionic form of three sulfonamides has the highest addition activity,while the corresponding cationic form is the most inactive addition reagent.The benzene ring of neutral forms of three sulfonamides is always a more favorable site for OH radical addition than the oxazole,pyrimidine or pyridine ring.C(3)or(and)C(5)atoms of benzene ring are the most favorable positions for OH addition occurring in benzene ring.Although the water solvent has no remarkable effect on OH addition reactions of neutral sulfonamides,it exerts a significant adverse influence on OH addition reactions of ionic sulfonamides.     

Photofragment imaging study of the CH2CCH2OH radical intermediate of the OH+allene reaction

These velocity map imaging experiments characterize the photolytic generation of one of the two radical intermediates formed when OH reacts via an addition mechanism with allene. The CH2CCH2OH radical intermediate is generated photolytically from the photodissociation of 2-chloro-2-propen-1-ol at 193 nm. Detecting the Cl atoms using [2+1] resonance-enhanced multiphoton ionization evidences an isotropic angular distribution for the Cl+CH2CCH2OH photofragments, a spin-orbit branching ratio for Cl(2P1/2):Cl(2P3/2) of 0.28, and a bimodal recoil kinetic energy distribution. Conservation of momentum and energy allows us to determine from this data the internal energy distribution of the nascent CH2CCH2OH radical cofragment. To assess the possible subsequent decomposition pathways of this highly vibrationally excited radical intermediate, we include electronic structure calculations at the G3//B3LYP level of theory. They predict the isomerization and dissociation transition states en route from the initial CH2CCH2OH radical intermediate to the three most important product channels for the OH+allene reaction expected from this radical intermediate: formaldehyde+C2H3, H+acrolein, and ethene+CHO. We also calculate the intermediates and transition states en route from the other radical adduct, formed by addition of the OH to the center carbon of allene, to the ketene+CH3 product channel. We compare our results to a previous theoretical study of the O+allyl reaction conducted at the CBS-QB3 level of theory, as the two reactions include several common intermediates.     

Characterizing the rovibrational distribution of CD2CD2OH radicals produced via the photodissociation of 2-bromoethanol-d4

This work characterizes the internal energy distribution of the CD(2)CD(2)OH radical formed via photodissociation of 2-bromoethanol-d(4). The CD(2)CD(2)OH radical is the first radical adduct in the addition of the hydroxyl radical to C(2)D(4) and the product branching of the OH + C(2)D(4) reaction is dependent on the total internal energy of this adduct and how that energy is partitioned between rotation and vibration. Using a combination of a velocity map imaging apparatus and a crossed laser-molecular beam scattering apparatus, we photodissociate the BrCD(2)CD(2)OH precursor at 193 nm and measure the velocity distributions of the Br atoms, resolving the Br((2)P(1/2)) and Br((2)P(3/2)) states with [2 + 1] resonance enhanced multiphoton ionization (REMPI) on the imaging apparatus. We also detect the velocity distribution of the subset of the nascent momentum-matched CD(2)CD(2)OH cofragments that are formed stable to subsequent dissociation. Invoking conservation of momentum and conservation of energy and a recently developed impulsive model, we determine the vibrational energy distribution of the nascent CD(2)CD(2)OH radicals from the measured velocity distributions.     

Kinetic and product study of the gas-phase reactions of OH radicals, NO(3) radicals, and O(3) with (C(2)H(5)O)(2)P(S)CH(3) and (C(2)H(5)O)(3)PS

Rate constants for the reactions of OH radicals and NO3 radicals with O,O-diethyl methylphosphonothioate [(C(2)H(5)O)(2)P(S)CH(3); DEMPT] and O,O,O-triethyl phosphorothioate [(C(2)H(5)O)(3)PS; TEPT] have been measured using relative rate methods at atmospheric pressure of air over the temperature range 296-348 K for the OH radical reactions and at 296 +/- 2 K for the NO(3) radical reactions. At 296 +/- 2 K, the rate constants obtained for the OH radical reactions (in units of 10(-11) cm(3) molecule(-1) s(-1)) were 20.4 +/- 0.8 and 7.92 +/- 0.27 for DEMPT and TEPT, respectively, and those for the NO(3) radical reactions (in units of 10(-15) cm(3) molecule(-1) s(-1)) were 2.01 +/- 0.20 and 1.03 +/- 0.10, respectively. Upper limits to the rate constants for the reactions of O(3) with DEMPT and TEPT of <6 x 10(-20) cm(3) molecule(-1) s(-1) were determined in each case. Rate constants for the OH radical reactions, measured relative to k(OH + alpha-pinene) = 1.21 x 10(-11) e(436/T) cm(3) molecule(-1) s(-1), resulted in the Arrhenius expressions k(OH + DEMPT) = 1.08 x 10(-11) e(871+/-25)/T cm(3) molecule(-1) s(-1) and k(OH + TEPT) = 8.21 x 10(-13) e(1353+/-49)/T cm(3) molecule(-1) s(-1) over the temperature range 296-348 K, where the indicated errors are two least-squares standard deviations and do not include the uncertainties in the reference rate constant. Diethyl methylphosphonate was identified and quantified from the OH radical and NO(3) radical reactions with DEMPT, with formation yields of 21 +/- 4%, independent of temperature, from the OH radical reaction and 62 +/- 11% from the NO(3) radical reaction at 296 +/- 2 K. Similarly, triethyl phosphate was identified and quantified from the OH radical and NO(3) radical reactions with TEPT, with formation yields of 56 +/- 9%, independent of temperature, from the OH radical reaction and 78 +/- 15% from the NO(3) radical reaction at 296 +/- 2 K.     

Generation of radical species from dihydropyrazines having DNA strand-breakage activity and other characteristics

The various biological activity of dihydropyrazines(DHPs)due to the radical generation potency has been described in previous papers. Detailed data about radical species generating be mentioned here. The electron spin resonance (ESR) spin-trapping technique revealed that DHPs generate free radical species such as ·OH, ·OOH, ·CHR(2) and ·CR(3). Oxygen radicals and two carbon-centered radicals were detected as adducts of the spin traps DMPO and DBNBS, respectively. All the 5,5-dimethyl-1-pyrroline-N-oxide (DMPO)- and 3,5-dibromo-4-nitrosobenzenesulfonate (DBNBS)-adducts of compounds DHP-1-8 exhibited approximately the same signal patterns, with various levels of intensity depending on the substituent of the dihydropyrazine ring. The ESR signal intensity of DHPs also increased remarkably upon addition of Cu(2+), resulting that the effects of DHPs were enhanced.     

DFT and MP2 molecular orbital determination of OH–toluene–O2 isomeric structures in the atmospheric oxidation of toluene

We have performed an exhaustive theoretical study, using a density functional theory (DFT) and ab initio techniques, of the possible isomers of the OH–toluene–O₂ radical. DFT calculations of the all electron type using the hybrid B3LYP approach and 6‐31G* orbital basis set were employed. In addition to the well‐established ortho position, addition of OH at C₁ on the benzene ring of toluene was also considered for the initial methylhydroxycyclohexadienyl adduct. In all, 28 different intermediate structures of the OH–toluene–O₂ system, consisting of peroxyl radicals, bicyclic structures, and epoxides, have been explored through fully optimized electronic structure calculations. Starting from the 1,3‐O₂‐methylorthohydroxycyclohexadienyl radical, or ortho‐OH adduct, several peroxyl radicals are found to have low‐lying structures contained within a small energy range (about 1 kcal/mol). Only two bicyclic structures are stable with respect to the methylhydroxycyclohexadienyl radical plus O₂, one of them being clearly favored. The four possible epoxy structures are all found to lie more than 15 kcal/mol lower than any of their peroxyl and bicyclic isomers. The preference, first noted by Bartolotti and Edney, for structures in which the OH group lies on the same side of the ring as the O₂ group, is obeyed in all cases. If the 1‐CH₃, 1‐OH cyclohexadienyl radical (or C₁–OH adduct) is used as the initial adduct, three peroxyl radicals are expected to be formed, while two bicyclic structure and three epoxides need to be considered. These structures are found to be, in general, less stable than the ones arising from the ortho adduct. However, the 4‐O, 2,3‐epoxy, 1,1‐methylhydroxycyclohexadienyl radical is found to be the most stable of all the isomers considered, and this, by more than 3 kcal/mol. In this work, most structures were also calculated with the MP2 method with a 6‐31G* basis set. The geometries obtained with the two methods are similar. Contrary to the B3LYP method, MP2 always yields an extra stability to structures in which the C₁ carbon atom has sp³ hybridization. © 2000 John Wiley & Sons, Inc. J Comput Chem 21: 716–730, 2000     

OH-initiated oxidation mechanism and kinetics of organic sunscreen benzophenone-3: A theoretical study

Benzophenone-3 (BP-3), as an important organic UV filter, is widely used in the sunscreen, cosmetic, and personal care products. The chemical reaction mechanism and kinetics of BP-3 degradation initiated by hydroxyl (OH) radical was investigated in the atmosphere based on the density functional theory (DFT). The results showed that the OH radical is more easily added to the C3 position of the aromatic ring (pathway 3), while the H atom abstraction from the OH group on the aromatic ring (pathway 23) is an energetically favorable reaction pathway. At ambient temperature, 298 K, the overall rate constant for the primary reaction is about 1.50 × 10^?10 cm³ mol^?1 s^?1 with the lifetime of 1.92 h. OH addition reactions play the key role in the OH-initiated reaction of BP-3. The study is helpful for better understanding of the removal, transformation, and fate of BP-3 in the atmosphere.     

Polyphosphate ions encapsulated in oxothiomolybdate rings: synthesis, structure, and behavior in solution

Cyclic oxothiomolybdates containing polyphosphate ions were prepared by simple reactions in aqueous medium of the corresponding polyphosphate ions and the cyclic precursor K(2)I(2)Mo(10)S(10)O(10)(OH)(10)(OH(2))(5).15H(2)O. K(5)[Cl(P(2)O(7)]Mo(12)S(12)O(12)(OH)(12)(H(2)O)(4)].22H(2)O (1) was isolated from concentrated chloride solution (2.5 mol.L(-1)). 1 reveals a remarkable complex containing two different substrates encapsulated in a dodecanuclear ring, a H-bonded Cl(-) ion, and a covalently bonded [P(2)O(7)] group. The chloride ion in 1 can be selectively removed for a monohydrogenophosphate group yielding K(6)[(HPO(4))(P(2)O(7))Mo(12)S(12)O(12)(OH)(12)(H(2)O)(2)].19H(2)O (2), a mixed species containing a [P(2)O(7)] and a [HPO(4)] group. The substitution is accompanied by a significant change of the ring, which adopts a "pear-shape" conformation. In the presence of triphosphate ion, the "heart-shaped" decanuclear ring Rb(3)[(H(2)P(3)O(10))Mo(10)S(10)O(10)(OH)(10)].17.5H(2)O (3) is formed containing a linear [P(3)O(10)] group intimately embedded in the inorganic cyclic host. The three compounds were structurally characterized by single-crystal X-ray diffraction. The behaviors of 1, 2, and 3 in solution were studied by (31)P NMR. Variable temperature experiments, supported by a two-dimensional COSY (31)P experiment, revealed that the supramolecular interaction existing between the chloride ion and the ring in solid 1 is maintained in solution. Nevertheless, 1 remains labile, and successive equilibria were evidenced and interpreted as an ion-pair association involving a halide ion (Cl, Br, or I), responsible for the conformational change of the [P(2)O(7)] group within the cavity. The influence of the nature of the halide guest (Cl(-), Br(-), and I(-)) on the successive equilibria was studied, and the thermodynamic constant related to the postulated equilibrium was determined. The stability of the supramolecular association decreases in the order Cl > Br > I. In solution, a phosphate exchange is observed for 2 while for 3 the absence of temperature dependence of the (31)P NMR spectrum confirms the conformation of the host-guest system is blocked. Elemental analysis and infrared characterizations are also supplied.     

Key role of chemical hardness to compare 2,2-diphenyl-1-picrylhydrazyl radical scavenging power of flavone and flavonol O-glycoside and C-glycoside derivatives

The antioxidant activities of flavonoids and their glycosides were measured with the 2,2-diphenyl-1-picrylhydrazyl radical (DPPH radical, DPPH(·)) scavenging method. The results show that free hydroxyl flavonoids are not necessarily more active than O-glycoside. Quercetin and kaempferol showed higher activity than apigenin. The C- and O-glycosides of flavonoids generally showed higher radical scavenging activity than aglycones; however, kaempferol C3-O-glycoside (astragalin) showed higher activity than kaempferol. In the radical scavenging activity of flavonoids, it was expected that OH substitutions at C3 and C5 and catechol substitution at C2 of B ring and intramolecular hydrogen bonding between OH at C5 and ketone at C3 would increase the activity; however, the reasons have yet to be clarified. We here show that the radical scavenging activities of flavonoids are controlled by their absolute hardness (η) and absolute electronegativity (χ) as a electronic state. Kaempferol and quercetin provide high radical scavenging activity since (i) OH substitutions at C3 and C5 strikingly decrease η of flavones, (ii) OH substitutions at C3 and C7 decrease χ and η of flavones, and (iii) phenol or o-catechol substitution at C2 of B ring decrease χ of flavones. The coordinate r(χ,?η) as the electron state must be small to increase the radical scavenging activity of flavonoids. The results show that chemically soft kaempferol and quercetin have higher DPPH radical scavenging activity than chemically hard genistein and daidzein.