新型手性氨基醇的合成及其对布洛芬对映异构体的手性识别

5-叔丁基-2-二甲氨基苯甲醛与L-苯甘氨酸经酯化、格氏反应途径的产物二齿手性氨基醇经缩合、还原反应,得到新型三齿手性氨基醇(2S)-2-(5-叔丁基-2-二甲氨基)苯甲氨基-1,1,2-三苯基乙醇,运用1H NMR考察了该新型三齿手性氨基醇作为主体对客体布洛芬消旋体的手性识别能力。     

L-苯甘氨酸衍生物新型三齿手性氨基醇的合成

对叔丁基苯胺经二甲基化、甲酰化得到5-叔丁基-2-二甲氨基苯甲醛;L-苯甘氨酸经LiAlH4直接还原,得到的二齿手性氨基醇与上述醛经缩合、还原,得到新型三齿手性氨基醇(2S)-2-[(5-叔丁基-2-二甲氨基)苯基]甲氨基-2-苯基乙醇。用红外光谱(IR)、质谱(MS)和核磁共振氢谱(1H-NMR)等对产物进行了结构表征。     

L-亮氨酸衍生物手性氨基醇的合成及其对布洛芬和扁桃酸对映异构体的手性识别

对甲基苯胺经甲基化、甲酰化得到5,N,N-三甲基-2-氨基苯甲醛;对L-亮氨酸经酯化、格氏反应得到二齿手性氨基醇.二齿手性氨基醇与上述醛经缩合、还原反应,得到三齿手性氨基醇.产物结构经IR,MS和1H NMR等进行了表征;通过改变主客体的浓度及手性羧酸的纯度,运用1H NMR分别考察了主体二齿手性氨基醇、三齿手性氨基醇对客体布洛芬和扁桃酸对映异构体的手性识别能力.结果表明:当主客体物质的量之比为1:1时,三齿手性氨基醇对布洛芬消旋体的a位甲基质子及扁桃酸消旋体的a位质子分别产生11.2和9.2 Hz的化学位移差值.     

新型多齿手性氨基醇的合成和结构表征

以L-苯甘氨酸和N,N-二甲基苯胺为原料,合成了2种新型多齿手性氨基醇S-1,1,2-三苯基-2-[(2-二甲氨基-5-溴-1-苯基)甲氨基]-1-乙醇和S-2-苯基-2-[(2-二甲氨基-5-溴-1-苯基)甲氨基]-1-乙醇;利用红外光谱仪、核磁共振谱仪及质谱仪表征了合成产物的结构.     

含平面手性和中心手性双手性因素化合物的合成及应用

[2,2]对二环苯经甲酰化、缩合、拆分得到（Rp）-4-甲酰基[2,2]对二环苯,再与L-亮氨酸的衍生物二齿手性氨基醇经缩合、还原得到由平面手性和中心手性因素构建的化合物（Rp,S）-1,1-二苯基-2-{[2,2]对二环苯基-甲氨基}-4-甲基戊醇.产物结构经IR、MS和1H NMR等进行了表征.用1H NMR考察了其作为主体对客体手性羧酸衍生物消旋体的手性识别能力.     

手性氨基醇的合成及其在二乙基锌与芳香醛的不对称加成反应中的应用

以天然氨基酸为手性源,合成了3个新的三齿手性氨基醇配体(1a～1c),其结构经1H NMR, IR和元素分析表征.将1用于催化二乙基锌与芳香醛的不对称加成反应,得到(R)-二级醇,产率96.7%, e.e.74.3%.     

手性氨基二醇的合成及其在二乙基锌对醛不对称加成反应中的应用

手性配体催化的烷基锌试剂对醛的不对称加成反应是合成光学活性二级醇的重要方法 [1] ,1 0多年来 ,人们对其进行了深入的研究 ,并取得了很大进展 .其中大部分工作是设计如β-氨基醇等新的手性配体 .此外 ,文献 [2～ 6]还报道了氨基二醇在这类反应中具有手性诱导效果 .为进一步研究手性配体催化的二乙基锌对醛的不对称加成反应 ,我们合成了新的手性氨基二醇配体 ,并将其用于该反应中 .1　结果与讨论1 .1　手性配体的合成　以 L -脯氨酸甲酯盐酸盐 ( 5 )为原料 ,与溴代乙酸乙酯反应生成 ( L ) - N - ( 2 -乙酰乙氧基 )脯氨酸甲酯 ( 6)反应 ,…     

R-兰索拉唑的合成新方法

2-氯甲基-3-甲基-4-（2,2,2-三氟乙氧基）吡啶盐酸盐和2-巯基苯并咪唑经缩合反应得到兰索拉唑硫醚;以L-亮氨酸经结构修饰得到的二齿手性氨基醇为催化剂、叔丁基过氧化氢为氧化剂,不对称氧化兰索拉唑硫醚得到R-兰索拉唑粗品。经分离纯化得到产物,e.e.值99.5%,两步反应总收率43.3%。产物经IR、MS、^1H-NMR、手性HPLC确证。     

合成盐酸氨溴索的新方法

以邻氨基苯甲酸甲酯（1）为起始原料,与溴素发生溴化反应制得2-氨基-3,5-二溴苯甲酸甲酯（2）。2经红铝试剂还原制得2-氨基-3,5-二溴苯甲醛（3）; 3经还原胺化制得氨溴索（4）; 4盐酸化得到盐酸氨溴索（5）,总收率60.8%,其结构经¹H NMR确证。     

基于D-葡糖胺的手性β-氨基醇的合成

手性氨基醇作为催化剂广泛应用于多种不对称合成反应中。以D-葡糖胺为原料设计合成一系列新型手性β-氨基醇。D-葡糖胺首先与氯甲酸甲酯缩合,再先后经过甲基化、苄叉保护、碱性水解反应,得4,6-O-苄叉基-2-脱氧-2-氨基-α-D-吡喃葡萄糖甲苷,进一步将其通过N-烃化反应或N-磺酰化反应合成得手性β-氨基醇。产物结构经1H NMR,13C NMR和MS表征确证。     

The first enantioselective synthesis of (S)-5-bromo-3-(1-methyl-2-pyrrolidinyl)pyridine: a key intermediate for the preparation of SIB-1508Y

The first enantioselective synthesis of (S)-5-bromo-3-(1-methyl-2-pyrrolidinyl)pyridine is described via intramolecular hydroboration–cycloalkylation of an azido-olefin intermediate. The chiral homoallylic alcohol was efficiently synthesized by enantioselective reduction of the corresponding ketone using (+)-diisopinocamphenylchloroborane as the key reaction. The total synthesis of (S)-SIB-1508Y was achieved with an enantiomeric excess (e.e.) of 94% in ten steps and in 18% overall yield from the commercially available 5-bromo-3-pyridinecarboxylic acid.     

氨基醇砌块用于螺/环丙环类手性化合物的合成

手性氨基醇砌块3与5-(l-孟氧基)-3-溴-2(5H)-呋喃酮手性合成子4通过串联的不对称双Michael加成/分子内亲核取代反应,得到了具有四个新的手性中心的氨基醇手性砌块/螺环/环丙烷类化合物7(44%～57%,de≥98%)。通过元素分析,[α]^20~D,UV,IR,^1HNMR,^13CNMR,MS确认了它们的化学结构。本工作可以为含有某些活性官能团的多手性中心的复杂结构化合物提供新的合成策略。     

高分子(纤维)负载手性氨基醇的合成及其催化二乙基锌对苯甲醛的不对称加成

合成了一种高分子纤维负载手性氨基醇催化剂, 并将该高分子纤维负载手性氨基醇用于催化二乙基锌对苯甲醛的对映选择性加成反应, 发现高分子纤维负载的手性氨基醇比树脂负载手性氨基醇的催化效果要好, 所得产物化学收率提高34%, 光学收率提高近9%. 该高分子纤维负载手性氨基醇可重复使用5次以上. 用比较纤维催化剂在催化反应前后的SEM照片方法, 证实了重复使用时催化效率下降的原因是有部分催化剂流失.     

Enantioselective decarboxylation of beta-keto esters with Pd/amino alcohol systems: successive metal catalysis and organocatalysis

The kinetics and mechanisms of one-pot cascade reactions of racemic beta-keto esters to give chiral ketones in the presence of Pd/C-chiral amino alcohol catalyst systems were studied. Transformation of 2-methyl-1-tetralone-2-carboxylic acid benzyl ester (1) into 2-methyl-1-tetralone (4) in the presence of Pd/C and cinchona alkaloids or ephedrine was chosen as a model reaction. After the first reaction step, the Pd-catalysed debenzylation of 1 to afford the corresponding beta-keto acid (2), there are two possible reaction routes that may be catalysed by the chiral amino alcohol in solution or by Pd(0) sites on the metal surface in cooperation with the adsorbed amino alcohol. The reaction intermediate 2 was synthesized, and the kinetics of decarboxylation were followed by NMR, UV and IR spectroscopy. The studies revealed that the role of Pd is to trigger the reaction series by deprotection of 1. The subsequent dominant reaction route from the racemic beta-keto acid 2 to the chiral ketone 4 is catalysed by the chiral amino alcohol in the liquid phase. It is shown that kinetic resolution of the diastereomeric salt of rac-2 and the chiral amino alcohol plays a key role in the enantioselection. High enantioselectivity necessitates an amino alcohol/rac-2 ratio of at least 2. A high ratio favours the formation of 1:1 amino alcohol/acid diastereomeric complexes, and the second amino alcohol molecule may be responsible for the enantioselective protonation of 2 in the diastereomeric complex.     

(R)‐N,N,N‐Trimethyl‐2‐Aminobutanol‐Bis(Trifluoromethane‐Sulfon)Imidate Chiral Ionic Liquid Used as Chiral Selector in HPCE,HPLC, and CGC

Abstract

In this work, the (R)‐N,N,N‐trimethyl‐2‐aminobutanol‐bis(trifluoromethanesulfon)imidate chiral ionic liquid was first used in chromatography and exhibited a excellent chiral recognition ability in high performance capillary electrophoresis (HPCE), high performance liquid chromatography (HPLC), and capillary gas chromatography (CGC), which also showed for the first time that chrial ionic liquid was an effective chiral selector in HPCE and HPLC. The compounds that have been separated using this chiral ionic liquid at least included alcohol, amine, acid, and amino acid, et al. enantiomers. As the chiral ionic liquid can be easily synthesized from relatively inexpensive materials, it should have a great potentiality for chiral separation in chromatographic science.     

Circularly Polarized Luminescence of Aluminum Complexes for Chiral Sensing of Amino Acid and Amino Alcohol

Determination of the absolute configuration (AC) of chiral molecules is a key issue in many fields related to chirality such as drug development, the asymmetric reaction screening, and the structure determination of natural compounds. Although various methods, such as X‐ray crystallography and NMR spectroscopy, are used to determine the AC, a simple and cheap alternative method is always anticipated. So far, electronic circular dichroism (ECD) spectroscopy has been widely used to ascertain the AC and enantiomeric excess (ee) values by applying appropriate organic probes. Here, circularly polarized luminescence (CPL) spectroscopy was applied to determine the AC and ee values of a series of amino acid and amino alcohol. The measurements were conducted by mixing the amino acids or amino alcohols with an achiral 1‐hydroxy‐2‐naphthaldehyde. Upon in situ formation of the Schiff base complexes, the system showed emission enhancement and CPL in the presence of Al³⁺, whose intensity and sign can be used to assign the chiral sense of the amino acids and amino alcohols. The authenticity of the method was further compared with the established CD spectroscopy, revealing that CPL spectra of formed Al³⁺ complex were effective to determine the AC of chiral species.