聚1,2-丁二烯的内聚能密度和玻璃化温度

本工作用环己烷-甲苯混合溶剂测定了不同1,2-链节含量的无定形聚1,2-丁二烯的溶解度参数,进而得到它们的内聚能密度,另外测定了它们的玻璃化温度。发现1,2-链节提高了聚1,2-丁二烯的玻璃化温度,同时稍稍降低了它们的内聚能密度。认为这是1,2-链节降低了聚1,2-丁二烯分子链柔顺性的缘故。     

端羧基聚丁二烯及端羧基聚（丁二烯－co－丙烯腈）离聚体的合成及表征

用溶液法由液体端羧基聚丁二烯（ＣＴＰＢ）及液体端羧基聚（丁二烯－ｃｏ－丙烯腈）（ＣＴＢＮ）合成了Ｌｉ＋、Ｎａ＋、Ｋ＋、Ｍｇ２＋、Ｚｎ２＋、Ａｌ３＋的遥爪型离聚体．考察了反应条件对离聚体形成的影响及离聚体稀溶液的性质。并用红外光谱，透射电子显微镜、动态粘弹谱仪研究和表征了部分ＣＴＰＢ、ＣＴＢＮ遥爪型离聚体．     

双烯类聚合物的热分析——Ⅲ.铁与其它催化体系聚1,2-丁二烯及其衍生物的热分析

<正> 由不同催化体系制得的聚1,2-丁二烯,由于其立体规整性(如等规、间规和无规)不同,其形态、热学性质也会有所不同。关于它们的热学性质文献报道不多。我们曾报道,由三乙酰基丙酮钴-三异丁基铝-二硫化碳催化体系制备的间规聚1,2-丁二烯是晶态的;而由正丁基锂和MoCl_4OR-(i-Bu),AlOR′制得的是无规聚1,2-丁二烯;是非晶态     

低乙烯基聚丁二烯橡胶的合成和表征

以钴催化体系为催化剂,用两步聚合法合成了1,2-链节含量范围在7—16%的低乙烯基聚了二烯橡胶。对聚合产物的表征结果表明,聚合物中存在着间同1,2-聚丁二烯的微晶,这些微晶起晶种的作用,能促进产物在低温下的结晶;当胶中1,2-链节含量小于10%时,不溶于CS₂的级分较少,加入1,2-聚合催化剂后主要生成顺1,4-间同1,2-丁二烯嵌段共聚物;当1,2-链节含量高于10%时,CS₂不溶物量较多,这时除上述嵌段物外尚可能生成少量间同1,2-聚了二烯均聚物。     

聚烯烃低聚物转化为双端正离子活性链及其遥爪三嵌段物的合成

非“活性”的端羧聚丁二烯及端羧聚丁腈胶通过THF开环聚合转变为双端正离子活性链。用液氨或二乙胺终止反应制得伯胺或叔胺端基遥爪聚丁二醇-聚烯烃-聚丁二醇三嵌段低聚物。     

超支化聚(酯-胺)分子结构及固化涂层性能研究

近年来,颜德岳等基于A2型单体二丙烯酸酯及BB2′型单体二胺化合物合成了多种端胺基超支化聚(酯-胺),并对反应机理及聚合物结构进行了系统研究[1,2],结果表明,由于B与B′活性差异,反应首先生成AB2′型和B4′型中间体,进一步聚合得到可溶性产物.我们基于A3型单体三丙烯酸酯与B2型单体二胺化合物合成了端丙烯酸酯基超支化聚(酯-胺)[3,4].在这些体系中,由于官能团反应活性高,难以控制反应程度.另外,由于超支化聚合物不能直接用作结构材料,其在涂料、粘合剂等领域的应用多基于末端官能团的固化反应[5].但通常由于官能团在分子表面密集分布,部…     

新型1, 6-二取代-5,6-二氢吡咯并[1,2-f]蝶啶衍生物的合成

以Pictet-Spengler型反应为基础, 设计了一条简便的合成1,6-二取代-5,6-二氢吡咯并[1,2-f]蝶啶衍生物的方法. 以4,6-二氯-5-氨基嘧啶为起始原料, 经Clauson-Kaas反应、胺亲核取代两步反应合成了4-氨基-6-氯-5-(1H-吡咯-1-基)-嘧啶, 然后与醛或脂肪酮在对甲苯磺酸催化下, 发生亲电关环得到1-氯-5,6-二氢-6-取代吡咯并[1,2-f]蝶啶, 其1位氯原子具有较高的反应活性, 易于被胺类亲核试剂取代.     

接枝树形支化分子双亲性嵌段共聚肽的合成及性能研究

分别以叠氮丙胺和丙炔胺为引发剂,采用氨基酸环内酸酐开环聚合法(NCA-ROP),引发L-谷氨酸-γ-苄酯-N-羧基-环内酸酐和L-谷氨酸-γ-氯乙醇酯-N-羧基-环内酸酐聚合得到链端基为叠氮基的聚(L-谷氨酸-γ-苄酯)(PBLG)和链端基为炔基的聚(L-谷氨酸-γ-氯乙醇酯)(PCELG)均聚物.联合点击化学法(click chemistry)制备了一系列聚(L-谷氨酸-γ-苄酯)-b-聚(L-谷氨酸-γ-氯乙醇酯)(PBLG-b-PCELG),再通过对嵌段共聚物侧基氯进行化学修饰,将二代的甲基烷氧醚类亲水性树形枝化分子(G2)接枝到侧链上,形成一系列树形支化分子接枝聚肽双亲性嵌段共聚物,通过核磁(NMR)、红外光谱(IR)和凝胶渗透色谱(GPC)对其化学结构进行了表征,并采用紫外-可见光谱(UV-Vis)研究了聚合物结构及其溶液浓度对其温敏行为的影响规律.     

双端正离子活性链的研究——α,ω—二胺基聚丁二醇-聚酯-聚丁二醇三嵌段低聚物的合成

<正> 本实验室前项工作曾证明用脂肪二酰氯与高氯酸银引发四氢呋喃(THF)在0—50℃下聚合可形成没有链终止和链转移反应的活性聚合链.为了减少聚丁二醇醚结晶趋势,又制备了双端活性的THF-环氧丙烷无规共聚醚链.本文则通过THF的开环聚合,将一个非“活性”的聚酯转变成为双端活性链,合成了伯胺端基聚丁二醇-聚酯-聚丁二醇遥爪低聚物,并用以增韧环氧树脂.     

新型水溶性共轭嵌段含糖聚合物的合成与表征

以两端溴化的聚9,9-二己基芴作为大分子引发剂, 6-O-甲基丙烯酰基-1,2∶3,4-二-O-异亚丙基-D-吡喃型半乳糖(6-O-Methacryloyl-1,2∶3,4-di-O-isopropylidene-D-galactopyranose, MaIpGa)为单体, 氯化亚铜/1,1,4,7,10,10-六甲基三乙基四胺为催化剂, 通过原子转移自由基聚合(ATRP), 合成了一种新型的具有良好光学性能的三嵌段共聚物聚甲基丙烯酸羟基保护半乳糖酯-聚芴-聚甲基丙烯酸羟基保护半乳糖酯(PMaIpGa-PF-PMaIpGa). 在酸性条件下进一步水解, 得到水溶性的聚甲基丙烯酸半乳糖酯-聚芴-聚甲基丙烯酸半乳糖酯(PMaGa-PF-PMaGa)三嵌段聚合物, 其结构和分子量(分布)通过核磁共振、红外光谱和凝胶渗透色谱(GPC)确证, 并研究了其紫外-可见和荧光光谱特性.     

Chiral ligand exchange capillary electrophoresis using borate anion as a central ion

Native DL-pantothenic acid, having a 1,3-diol structure, was chirally resolved by ligand exchange capillary electrophoresis using (S)-3-amino-1,2-propanediol as a chiral selector and the borate anion as a central ion. The optimum conditions for both high resolution and short migration time of DL-pantothenic acid were found to be 200 mM (S)-3-amino-1,2-propanediol and 200 mM borate buffer (pH 9.2) containing 15% methanol with an applied voltage of +25 kV at 20 degrees C, using direct detection at 200 nm. With this system, the resolution (Rs) of racemic pantothenic acid was approximately 1.7. When (S)-1,2-propanediol, (S)-1,2,3-propanetriol, (S)-1,3-butanediol or (S)-1-amino-2-propanol were used as chiral ligand instead of (S)-3-amino-1,2-propanediol, DL-pantothenic acid was not enantioseparated. When borate was replaced with Tris or butylborate, no chiral separation was achieved. Therefore, the ionic interaction between the amino and carboxyl groups of the ternary complex may play an important role in the enantioseparation of DL-pantothenic acid by the proposed CE system.     

Frustrated Lewis Pair Mediated 1,2-Hydrocarbation of Alkynes

Frustrated Lewis pair (FLP) chemistry enables a rare example of alkyne 1,2-hydrocarbation with N-methylacridinium salts as the carbon Lewis acid. This 1,2-hydrocarbation process does not proceed through a concerted mechanism as in alkyne syn-hydroboration, or through an intramolecular 1,3-hydride migration as operates in the only other reported alkyne 1,2-hydrocarbation reaction. Instead, in this study, alkyne 1,2-hydrocarbation proceeds by a novel mechanism involving alkyne dehydrocarbation with a carbon Lewis acid based FLP to form the new C−C bond. Subsequently, intermolecular hydride transfer occurs, with the Lewis acid component of the FLP acting as a hydride shuttle that enables alkyne 1,2-hydrocarbation.     

Frustrated Lewis Pair Mediated 1,2‐Hydrocarbation of Alkynes

Frustrated Lewis pair (FLP) chemistry enables a rare example of alkyne 1,2‐hydrocarbation with N‐methylacridinium salts as the carbon Lewis acid. This 1,2‐hydrocarbation process does not proceed through a concerted mechanism as in alkyne syn‐hydroboration, or through an intramolecular 1,3‐hydride migration as operates in the only other reported alkyne 1,2‐hydrocarbation reaction. Instead, in this study, alkyne 1,2‐hydrocarbation proceeds by a novel mechanism involving alkyne dehydrocarbation with a carbon Lewis acid based FLP to form the new C−C bond. Subsequently, intermolecular hydride transfer occurs, with the Lewis acid component of the FLP acting as a hydride shuttle that enables alkyne 1,2‐hydrocarbation.     

An Efficient Solid Acid Promoted Synthesis of Quinoxaline Derivatives at Room Temperature

Quinoxaline derivatives have been synthesized in a very short time with excellent yields by the condensation of 1,2-diamines with aliphatic or aromatic 1,2-dicarbonyl compounds or benzilmonoxime in the presence of silica sulfuric acid as a very inexpensive solid acid catalyst at room temperature. The recovery and reuse of the catalyst are also satisfactory.     

PHOTOCHEMICAL AND PHOTOBIOLOGICAL PROPERTIES OF KETOPROFEN ASSOCIATED WITH THE BENZOPHENONE CHROMOPHORE

Abstract Irradiation of ketoprofen in neutral aqueous medium gave rise to 3-ethylbenzophenone as the major photoproduct. Its formation is justified via protonation of a benzylic carbanion or hydrogen abstraction by a benzylic radical. Minor amounts of eight additional compounds were isolated. Four of them are derived from the benzylic radical: 3-(1-hydroperoxyethyl)benzophenone, 3-(1-hydroxyethyl)benzophenone, 3-acetylbenzophenone and 2,3-bis- (3-benzoylphenyl)butane. The other four products involve initial hydrogen abstraction by the excited benzophenone chromophore of ketoprofen: 1,2-bis-(3-ethylphenyl)-1,2-diphenyl-1,2-ethanediol, 2-(3-benzoylphenyl)-1-(3-ethylphenyl)-1 -phenylpropan-1 -01,α -(3-ethylphenyl)phenylmethanol, 1,2-bis-[3-(2-hydroxycarbonylethyl)phenyl]-1,2-di-phenyl-1,2-ethanediol. The latter process was found to mediate the photoperoxidation of linoleic acid through a type I mechanism, as evidenced by the inhibition produced by the radical scavengers butylated hydroxyanisole and reduced glutathione. The major photoproduct, which contains the benzophenone moiety but lacks the propionic acid side chain, also photosensitized linoleic acid peroxidation. Because lipid peroxidation is indicative of cell membrane lysis, the above findings are highly relevant to explain the photobiological properties of ketoprofen.     

Glycosidation-anomerisation reactions of 6,1-anhydroglucopyranuronic acid and anomerisation of beta-D-glucopyranosiduronic acids promoted by SnCl(4)

The reaction of silylated nucleophiles with 6,1-anhydroglucopyranuronic acid (glucuronic acid 6,1-lactones) catalysed by tin(IV) chloride provides 1,2-trans or 1,2-cis (deoxy)glycosides in a manner dependent on the donor structure. The alpha-glycoside was obtained for reactions of the donor with the 2-acyl group and 2-deoxydonors, whereas the 2-deoxy-2-iodo donor gave the beta-glycoside. Experimental evidence shows that when 1,2-cis-glycoside formation occurs, the anomerisation of initially formed 1,2-trans-glycosides catalysed by SnCl(4) is possible. The anomerisation of beta-D-glucopyranosiduronic acids was found to be faster, in some cases, than anomerisation of related beta-D-glucopyranosiduronic acid esters and beta-D-glucopyranoside derivatives and the rates are dependent on the structure of the aglycon. Moreover, the rates of anomerisation of beta-D-glucopyranuronic acid derivatives can be qualitatively correlated with rates of hydrolysis of beta-D-glucopyranosiduronic acids. Mechanistic possibilities for the reactions are considered.     

Synthesis and Some Properties of 1,2-Dinitroguanidine

1,2-Dinitroguanidine is a product of nitroguanidine nitration with nitric acid and its mixtures with sulfuric acid and oleum. It is a diacid (pK _a 1.11, 11.5) and at the same time a weak base undergoing protonation at the nitrogen of the amino group (pK _BH+ -5.81). The decomposition kinetics of 1,2-dinitroguanidine was studied by spectrophotometric method both in acid and alkaline media, and the mechanism of the process was assumed. In the media of high acidity (H_o > -8) the 1,2-dinitroguanidine suffers reversible denitration into nitroguanidine. At lower acidity its conjugate acid or molecular form undergoes hydrolysis yielding nitrourea. Monoanion of 1,2-dinitroguanidine in a weak acid or in an alkali is hydrolyzed into N,N'-dinitrourea. The reaction of 1,2-dinitroguanidine with alkali in alcohol provides its salts, with nitrogen-containing bases form both salts and derivatives of 2-nitroguanidine. The treatment of 1,2-dinitroguanidine with haloalkanes results in its N-alkylated products.     

Synthesis of 1,2-di-(4-pyridyl)ethylenediamine and related compounds

Hydrolysis of N,N'-diacyl-1,2-di(4-pyridyl)ethylenediamines 1 in aqueous sulfuric acid gave the corresponding imidazolines 3. 1,2-Di-(4-pyridyl)ethylenediamine 2 was prepared in 61 % yield by treating N,N'-di-t-butyl-oxycarbonyl-1,2-di(4-pyridyl)ethylenediamine 4 with trifluoroacetic acid or in 94% yield by the hydrolysis under basic conditions of N,N'-diphthaloylglycyl-1,2-di(4-pyridy)ethylenediamine 13.     

HYDROGEN BONDING AND PHOTOTAUTOMERISM OF 3-METHYLLUMICHROME

The spectral changes of 3-methyllumichrome in 1,2-dichloroethane upon addition of hex-afluoroisopropanol, trifluoroacetic acid and acetic acid as hydrogen donor agents, have been defined. In the presence of 0.8 M hexafluoroisopropanol, the absorption and fluorescence emission spectra of 3-methyllumichrome in 1,2-dichloroethane acquire features nearly identical to those observed in aqueous solution. Therefore, hexafluoroisopropanol can be considered as a model compound for studies on hydrogen bonding of alloxazine derivatives in nonpolar media. The observed spectral changes upon addition of trifluoroacetic acid are caused mainly by protonation. The presence of hydrogen bonded and protonated forms of 3-methyllumichrome has been checked by means of excitation spectra. The addition of acetic acid causes minor hydrogen bonding effects but gives rise to the phototautomery with an efficiency of one order of magnitude higher in 1,2-dichloroethane than previously observed in methanol or dioxane. The isoalloxazinic emission band appears at about 495 nm and shifts bathochromically to 540 nm upon increasing acetic acid concentration, probably due to the opening of the primary cyclic structure between 3-methyllumichrome and acetic acid. The fluorescence emission spectra can be resolved using lognormal approximation into three bands, one ascribed to the alloxazinic form (maximum at about 440 nm) and the others to isoalloxazinic species (maxima at about 495 and 540 nm). The excitation spectra confirm the presence of two excited alloxazinic forms, one solvated by 1,2-dichloroethane with emission at 435 nm and T ˜1 ns, and the second bonded with acetic acid, bathochromically shifted with T ˜5 ns and able to phototautomerize. The sum of excitation spectra of both forms in suitable proportion reconstructs the absorption spectra of 3-methyllumichrome in 1,2-dichloroethane and acetic acid.     

PHOTODEGRADATION AND in vitro PHOTOTOXICITY OF FENOFIBRATE, A PHOTOSENSITIZING ANTI-HYPEIUIPOPROTEINEMIC DRUG

The phototoxic anti-hyperlipoproteinemic drug fenofibrate was found to be photolabile under aerobic and anaerobic conditions. Irradiation under argon of a methanol solution of this drug produced the photoproducts isopropyl 4-(1-[4-chlorophenyl]-1,2-dihydroxy)ethylphenoxyisobutyrate, 1,2- bis (4-chlorophenyl)-1,2- bis (4-[isopro-poxycarbonylisopropoxy]phenyl)ethane-1,2-diol and 4-(4-chlorobenzoyl)phenol, while under oxygen the photoproducts were 4-chloroperbenzoic acid, methyl 4-chlorobenzoate, 4-chlorobenzoic acid and singlet oxygen, as evidenced by trapping with 2,5-dimethylfuran. These results can be rationalized through hydrogen abstraction by excited fenofibrate, to afford a free radical as key intermediate. Biologically active antioxidants such as glutathione and cysteine efficiently reduced 4-chloroperbenzoic acid to 4-chlorobenzoic acid. The involvement of an electron transfer mechanism is suggested by detection (UV-vis spectrophotometry) of the radical cation TMP⁺ during the oxidation of tetramethylphenylenediamine (TMP) with 4-chloroperbenzoic acid. Fenofibrate was phototoxic in vitro when examined by the photohemolysis test, both under oxygen and argon atmosphere, although the photohemolysis rate was markedly lower under anaerobic conditions. The photoproducts 4-(1-[4-chlorophenyl]-1,2-dihy-droxy)ethylphenoxyisobutyrate and 4-chloroperbenzoic acid induced hemolysis in the dark however, this effect was quantitatively less important than photohemolysis by fenofibrate. On the other hand, fenofibrate photosensitized peroxidation of linoleic acid, monitored by the UV detection of dienic hydroperoxides. Based on the inhibition of this process upon addition of butylated hydroxyanisole, a radical chain (type I) mechanism appears to operate. In summary, fenofibrate is phototoxic in vitro . This behavior can be explained through the involvement of free radicals, singlet oxygen and stable photoproducts.