新型吡咯类衍生物的合成

2,5-己二酮和胺(氨基硫脲、硫脲、苯胺、氨基酸)经过Paal-Knorr反应合成6个2,5-二甲基-N-取代吡咯衍生物;分别以新合成的N-吡咯甘氨酸、N-苯基吡咯化合物为原料,进行酯化反应和Mannich,Friedel-Craft反应,合成3个N-(2,5-二甲基吡咯)甘氨酸酯类化合物和2个N-苯基-2,5-二甲基吡咯衍生物.所有化合物都通过IR,1HNMR,13CNMR,HRMS波谱方法对其结构进行了确证.     

N-甲基-2-(3,4-二羟基苯基)[60]富勒烯吡咯烷衍生物的合成

在N2气保护下,由1,3-偶极环加成反应合成了含2个羟基的C60吡咯烷衍生物:N-甲基-2-(3,4-二羟基苯基)[60]富勒烯吡咯烷. 用UV-Vis、FT-IR、1H NMR、MS等测试技术表征了产物的结构,通过单因素方法,探讨了反应条件对产物产率的影响. 最佳反应条件为:n(C60)∶ n(N-甲基甘氨酸)∶ n(3,4-二羟基苯甲醛)=1∶ 2∶ 5,温度为95 ℃,反应时间为28 h,产率可达66%(以消耗的C60计).     

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。     

N,N-二取代甘氨酸酯的合成及其经皮促渗活性

合成了4个新的N,N-二取代甘氨酸酯,其结构经^1HNMR谱、IR谱、MS-ESI谱和元素分析确证。在改良的Franz扩散池上,用离体裸鼠皮作生物膜,扑热息痛或消炎痛作药物模型进行经皮促渗活性对比试验。结果显示：N,N-二甲基甘氨酸-（E）-3,7-二甲基-2,6-辛二烯酯（2a）具有出色的促透活性,含2．5％的2a促进扑热息痛、消炎痛经皮渗透的效果分别是Azone的2．1和2．6倍,且时滞缩短,超过DDAA的经皮促渗活性;而N,N-二甲基甘氨酸-6-戊氧基-1-己酯（2b）的经皮促渗活性接近Azone,且时滞更短。     

气相色谱-质谱法分析乳腺癌患者血清中的代谢物

建立了气相色谱-质谱法分析乳腺癌患者血清中代谢物的分析方法。分别收集乳腺癌患者、一般疾病者和健康对照组血清,样本用甲醇∶乙腈∶丙酮=1∶1∶1(V/V)提取,硅烷化试剂N,O-双甲氧基三氟乙酰胺+1%三甲基氯硅烷(BSTFA+1%TMCS)衍生后,采用气相色谱-质谱法分析其中的氨基酸、脂类和糖类的代谢谱,并用主成分分析(PCA)和随机森林(RF)算法对实验结果进行分析。结果表明,三组实验数据被成功分类,并发现磷酸、N-巴豆酰基甘氨酸、2,4-二羟基丁酸、棕榈酸、N-苯基甘氨酸和N-1-己酰甘氨酸等组分在乳腺癌组和健康对照组中的差异较为显著。     

新型含胍基和季铵基团壳聚糖衍生物的合成

N,N-二甲基-1,3-丙二胺与单氰胺经亲核加成反应制得中间体N,N-二甲基-N′-胍基-1,3-丙二胺（2）; 以壳聚糖为起始原料,依次与氯乙酸、环氧氯丙烷经取代反应制得N-（1-羟基-3-氯丙基）-羧甲基壳聚糖（4）; 4与2经季铵化反应合成了一系列含有胍基和季胺基团的羧甲基壳聚糖衍生物（5）,其结构经¹H NMR, IR和元素分析表征。研究了反应配比［γ=m（2）∶m（4）］和反应时间对5取代度的影响,结果表明,当γ为3∶1,反应时间为10 h时,取代度最高(73%)。     

N-甲基-2-(4-取代哌嗪)-N-[3-(萘氧基)-3-(2-噻吩基)丙基]乙酰胺衍生物的设计与合成

以N-甲基-3-(1-萘氧基)-3-(2-噻吩基)-丙胺(度洛西汀)为原料,通过N-酰氯化反应和N-烷基化反应,合成了5个新型的N-甲基-2-(4-取代哌嗪)-N-[3-(萘氧基)-3-(2-噻吩基)丙基]酰胺衍生物,其结构经1H NMR,IR和MS表征。     

通过氧杂Pictet-Spengler反应从1-烷(苯)氧基-3-(3,4-亚甲基二氧)苯基-2-丙醇合成异色满衍生物

通过氧杂Pictet-Spengler反应从1-烷氧基-3-(3,4-亚甲基二氧)苯基-2-丙醇及1-苯氧基-3-(3,4-亚甲基二氧)苯基-2-丙醇合成一系列异色满衍生物,即3-烷(苯)氧基-1-苯基-6,7-亚甲基二氧异色满和3-烷(苯)氧基-1,1-二甲基-6,7-亚甲基二氧异色满,收率为50%～90%.     

N-(2-吡咯甲基)-1-苯基乙亚胺·二甲基铝的合成、结构及其催化丙交酯的活性（英文）

通过席夫碱配体N-(2-吡咯甲基)-1-苯基乙亚胺与三乙基铝按物质的量之比为1∶1在无氧无水的条件下反应,合成了席夫碱铝的有机金属化合物N-(2-吡咯甲基)-1-苯基乙亚胺·二甲基铝。其结构分别用核磁氢谱、碳谱,元素分析和X射线单晶衍射技术进行了表征。铝化合物在催化外消旋丙交酯开环聚合反应中表现出了中等的活性并得到了以等规聚合为主的高聚物。     

吡唑啉衍生物与溶剂相互作用的研究

通过对一类吡唑啉衍生物（1-苯基-3-（N，N-二甲基氨基苯乙烯）-5-（4-N，N-二甲基氨基苯基）-2-吡唑啉）在不同溶剂中的光谱行为，研究了该衍生物和溶剂分子间的一般相互作用和特殊相互作用．发现利用吡唑啉溶液的荧光猝灭现象能对其和溶剂分子间不同相互作用问题提供有价值的信息．     

Spectra and structure of binary azeotropes V-acetone-cyclopentane

Acetone and cyclopentane make a minimum boiling homogeneous binary azeotrope with mole ratio 2:3. Some characteristic vibrational modes, as well as (1)H NMR signals change due to the azeotrope formation. The extend of interaction of these molecules causes significant changes on some vibrational modes involved and (1)H NMR signals show some changes on their position. In this work the FTIR and (1)H NMR spectra of pure acetone, pure cyclopentane and corresponding azeotrope were recorded, mutual influences resulting from azeotrope formation have been analyzed, and spectral changes has been discussed. The unit-structure of cluster have been deduced, based on mole ratio, boiling point depression of constituents, and comparison between the spectra obtained by FTIR and (1)H NMR techniques.     

Spectra and structure of binary azeotropes IV. Acetone-cyclohexane

Acetone and cyclohexane make a binary azeotrope with mole ratio 3:1. Some characteristic vibrational modes of acetone and cyclohexane change due to the azeotrope formation. The extend of interaction of these molecules causes significant changes on vibrational modes involved, and (1)H NMR signals show some changes on their position. FTIR and (1)H NMR spectra of pure substances and corresponding azeotrope were recorded, mutual influences resulting from azeotrope formation have been analyzed, spectral changes have been discussed. The unit-structure of cluster were deduced based on mole ratio, boiling point depression of constituents and comparison between spectra obtained by FTIR and (1)H NMR techniques.     

Ionic liquids in separations of azeotropic systems – A review

Efforts to make existing separation methods more efficient and eco-friendly may get a boost from the use of a relatively new class of compounds known as ionic liquids (ILs). The separation of azeotropic mixtures has conventionally been one of the most challenging tasks in industrial processes due to the fact that their separation by simple distillation is basically impossible.This paper provides a critical review of methods using ILs as azeotrope breakers. Three separation processes were addressed: liquid–liquid extraction, extractive distillation, and supported liquid membranes. We examine the azeotrope breaking potential of ILs and compare their performance to that of conventional solvents. A systematic analysis of the influence of the structure of ILs on their azeotrope breaking capacity contributes to the establishment of guidelines for selecting the most suitable ILs for the separation of specific azeotropic mixtures.     

Preparation of polymer-supported Ru-TsDPEN catalysts and use for enantioselective synthesis of (S)-fluoxetine

Polymer-supported chiral ligands 9 and 17 were prepared based on Noyori's (1S,2S)- or (1R,2R)-N-(p-tolylsulfonyl)-1,2-diphenylethylenediamine. The combination with [RuCl2(p-cymene)]2 has been shown to exhibit high activities and enantioselectivities for heterogeneous asymmetric transfer hydrogenation of aromatic ketones (19a-c) with formic acid-triethylamine azeotrope as the hydrogen donor, whereby affording the respective optically active alcohols 20a-c, the key precursors of chiral fluoxetine. As exemplified by ligand 17 for substrate 19c, the catalysts can be recovered and reused in three consecutive runs with no significant decline in enantioselectivity. The procedure avoids the plausible contamination of fluoxetine by the toxic transition metal species.     

Spectra and structure of binary azeotropes VI-benzene-methanol

Benzene and methanol make a minimum boiling point homogeneous binary azeotrope with the mole ratio 2:3. Some characteristic vibrational modes, as well as ¹H NMR signals change due to the azeotrope formation. The extend of interaction of these molecules causes significant changes on some vibrational modes involved, and ¹H NMR signals show some changes on their position. No IR, Raman, and NMR spectra have been reported for this constant boiling mixture, also there has not been any attempt to investigate the unit-structure of this azeotrope. In this work the FTIR, FT-Raman, and ¹H NMR spectra of pure benzene, pure methanol, and corresponding azeotrope were recorded, mutual influences resulting from azeotrope formation have been analyzed, and spectral changes has been discussed. The unit-structure of cluster has been deduced based on mole ratio, boiling point depression of constituents, and comparison among the spectra obtained by FTIR, FT-Raman, and ¹H NMR techniques.     

Rheological behavior of organic suspensions of fluorapatite

A fluorapatite suspension prepared in the azeotrope methyl ethyl ketone-ethyl alcohol (MEK:EtOH) in the presence of the phosphoric ester was investigated. Electrical conductivity, adsorption isotherms, and sedimentation technique showed that the amount of phosphoric ester adsorbed on the fluorapatite surface was equal to, or higher than, 1 wt%. This dispersant concentration led to a good particle packing. The rheological properties of fluorapatite suspensions were studied as a function of phosphoric ester concentration. The data obtained from the viscosity measurements and those previously collected correlated well. In the case of suspensions prepared with 60 wt% in fluorapatite, the dispersion was optimal for a phosphoric ester content of about 1.3 wt%.     

Spectra and structure of binary azeotropes I. Acetone-chloroform

Some characteristic vibrational modes of acetone and chloroform change due to the azeotrope formation. The extend of interaction of these molecules has significant effects on some vibrational modes involved, depending on unit structure in azeotrope cluster. Besides (1)H NMR signals undergo some chemical shifts, which show the effect of oncoming molecules on the target molecule. FT-IR and (1)H NMR spectra of pure substances and corresponding azeotrope were recorded, mutual influences due to azeotrope formation based on mole ratio, boiling point and spectral changes has been discussed. Unit structure of cluster deduced by investigating fundamental frequency shifts and (1)H NMR chemical shifts.     

Identification of Additives to Render Mixtures of Gasoline and the Ethanol-Water Azeotrope Hiscible

The economical production of gasohol, in terms of both energy and dollars, is dependent upon th e use of pure, water-free ethanol. Since a small amount of water will cause phase separation in the gasohol, the ethanol must be completely water free. Rather than using pure ethanol, it was proposed to use the ethanol-water azeotrope and some kind of modifier to remove the phase splitting that would occur from using the azeotrope, thus removing the burden of producing water-free ethanol.

A thermodynamic analysis of a set of mixtures containing the gasoline, ethanol azeotrope, and an additive was performed. Each system was evaluated using a computer algorithm which interfaced liquid-liquid equilibrium calculations with the UNIFAC ac tivity coefficient prediction model. The amount of each additive necessary to produce a single phase in the mixture was then determined.

Thirty six compounds were evaluated as possible additives and, of these, six were found to require less than 10% by volume added in order to produce complete miscibility in the gasoline-ethanol azeotrope mixture. All six of these additives were alcohols. Another six components were also found for which 10 to 20% by volume added was required to produce single phase behavior.     

Spectra and structure of binary azeotropes. III. Acetone-n-hexane

Acetone and n-hexane form an azeotrope with the mole ratio 2:1. As a result of this phenomenon, some characteristic vibrational modes in FT-IR and some chemical shifts in ¹H NMR spectra changes. The amount of these changes is an indication of the extension of interaction between two components and their orientation in unit structure of the cluster. FT-IR and ¹H NMR spectra of pure substances and their azeotrope were recorded and spectral changes analyzed. Based on mole ratio of constituents, boiling point depressions, spectral changes in fundamental frequencies, and chemical shifts, unit structure of the azeotrope were deduced.     

A chiral rhodium complex for rapid asymmetric transfer hydrogenation of imines with high enantioselectivity

[formula: see text] A chiral rhodium complex, (R)-Cp*RhCl[(1S,2S)-p-TsNCH(C6H5)CH(C6H5)NH2] (1a, (S,S)-Cp*RhClTsDPEN), generated from [Cp*RhCl2]2 and (1S,2S)-N-p-toluenesulfonyl-1,2-diphenylethylenediamine [(S,S)-TsDPEN], and its enantiomer 1b were found to provide superior catalysts for the rapid, high-yielding, asymmetric transfer hydrogenation of some heterocyclic imines, using an HCO2H-Et3N azeotrope as the hydrogen source.