苯甲酮不对称还原反应的理论研究

本文用AM1分子轨道方法研究了1,3,2-噁唑硼烷对苯甲酮的不对称催化还原.反应经历了噁唑硼烷-硼烷配合物的形成及其与苯甲酮的结合、氢转移及脱去噁唑硼烷形成手性产物二级醇-硼烷配合物四步过程.获得了各步的反应热、速度控制步骤的过渡态结构和位能曲线及其相应的反应活化能,计算发现反应机理中的第3步氢转移产物有四员环结构特征.     

手性噁唑硼烷结构与还原苯基乙基甲酮的对映选择性研究~≠

本文以苯基乙基甲酮为还原底物,研究了原地(in situ)制备的在3、4、5位具有不同取代基的手性1,3,2-(口恶)唑硼烷催化剂的结构与不对称催化效应关系。研究结果表明,在不对称催化硼烷还原反应中(CBS方法),产物的构型和对映选择性主要受手性(口恶)唑硼烷的4位取代基控制。     

手性氨基醇催化的前手性芳酮的不对称还原反应

首次以天然D-樟脑的衍生物为原料, 合成了两个新型龙脑基氨基醇配体, 研究了它们与硼烷原位制备成手性噁唑硼烷后, 在不对称催化氢化还原前手性芳酮中的性能, 得到的手性仲醇的对映体过量(ee)值最高可达96%, 还考察了反应温度、时间、溶剂等因素对苯乙酮的不对称氢化还原的化学产率和光学收率的影响.     

亚胺不对称催化还原的量子化学研究

对手性噁唑硼烷催化亚胺不对称还原反应进行了量子化学研究. 对反应中间体和过渡态进行了B3LYP/6-31G(d)全优化. 噁唑硼烷对亚胺还原的催化作用是显著的. 还原反应经历了催化剂-硼烷加合物、催化剂-硼烷-亚胺加合物、催化剂-氨基硼烷加合物的生成, 以及催化剂-氨基硼烷加合物的离解并再生催化剂等过程. 还原反应的速度控制步骤是噁唑硼烷-氨基硼烷加合物的离解. 理论预测的还原产物是与实验吻合的R-手性胺.     

手性恶唑硼烷结构与还原苯基乙基甲酮的对映选择性研究

本文以苯基乙基甲酮为还原底物, 研究了原地(in situ)制备的在3、4、5位具有不同取代基的手性1,3,2-恶唑硼烷催化剂的结构与不对称催化效应关系。研究结果表明, 在不对称催化硼烷还原反应中(CBS方法)、产物的构型和对映选择性主要受手性恶唑硼烷的4位取代基控制。     

手性噁唑硼烷的研究进展及其应用

手性噁唑硼烷是不对称合成的重要催化剂, 它可以高产率、高立体选择性地催化酮、内消旋酰亚胺以及亚胺的不对称还原, 催化立体选择性Diels-Alder反应、不对称Mukaiyama缩合反应等重要有机化学反应. 概述了近十年来手性噁唑硼烷在不对称合成中的研究进展以及在合成VB₁₂等多种天然及非天然活性化合物中的应用.     

噁唑硼烷催化芳醛不对称炔基化反应的量化研究

对手性噁唑硼烷催化芳醛不对称炔基化还原反应的机理进行了量子化学半经验方法研究.研究表明,该反应是放热的，炔基转移是反应的控制步骤，炔基转移的过渡态具有扭曲的椅式结构，还原的主要产物是R-手性醇.     

双手性噁唑硼烷体系催化还原反应的研究

第一次成功设计、合成了新型的双手性噁唑硼烷还原体系，并将其应用于前手性酮的不对称还原。实验结果表明，双手性噁唑硼烷体系在手性相匹配的情况下，对前手性酮还原的对映选择性明显地优于单手性的噁唑硼烷的还原体系。     

噁唑硼烷催化前手性酮肟醚不对称还原反应的密度泛函研究

对噁唑硼烷催化前手性酮肟醚不对称还原反应进行了密度泛函理论(DFT)研究. 在B3LYP/6-31G(d)水平下对反应主要中间体和过渡态结构进行了完全优化, 并通过振动分析确认了过渡态. 结果表明, 该不对称还原反应的手性控制步骤是氢从BH3向酮肟醚羰基碳和肟基碳的转移, 还原产物的手性由这两步反应所决定. 在所有的反应途径中, 第一个氢的转移都是通过一个六元环的过渡态完成, 而第二个氢的转移则是通过一个五元环或四元环的过渡态完成.     

噁唑硼烷催化前手性酮不对称还原反应机理的量子化学研究

对手性噁唑硼烷催化3,3-二甲基丁酮-2不对称还原反应机理进行了从头算研究.结果表明,该不对称还原反应是放热的.反应经历了催化剂-硼烷加合物、催化剂-硼烷-酮加合物、含B-O-B-N四元环的催化剂-烷氧基硼烷加合物的生成,以及催化剂-烷氧基硼烷加合物的离解并再生催化剂等过程.在催化剂-硼烷-酮加合物经氢转移而生成催化剂-烷氧基硼烷加合物的过程中,氢转移与B-O-B-N四元环的形成是协同进行的.氢转移是还原反应的控制步骤.氢转移过渡态具有扭曲的椅式结构,所决定的还原产物是与实验相吻合的R手性醇.     

新型手性膦噁唑啉铱络合物的合成及其在氢化反应中的应用

在鹰爪碱诱导下,2-氯甲基-4,4-二甲基噁唑啉与叔丁基苯基膦硼烷经络合反应,以43%的收率合成了光学纯度大于99%,手性中心在P上的新型手性噁唑啉氮膦配体(3); 3和铱配合物(［Ir(cod)Cl］₂)经络合反应以55%的收率制得两个新型手性膦噁唑啉铱络合物催化剂(1和2),其结构经¹H NMR, ¹³C NMR, ³¹P NMR和元素分析表征。考察了1和2对烯烃的不对称氢化反应的催化性能。结果表明：1具有较好的催化能力,收率＞92%,但催化剂的手性诱导能力较差(ee≤36%)。     

Simple and practical routes to enantiomerically pure 5-(trialkylsilyl)-2-cyclohexenones

[reaction: see text] Enantiomerically pure chiral 5-silylated 2-cyclohexenones are easily prepared in high yield using as a key step kinetic resolution with a commercially available lipase. Fully active enzyme can be recovered very efficiently for reuse. The synthetic steps are outlined in Schemes 1 and 3. Enantiomerically pure 2-cyclohexenones such as 1 and 2 are versatile intermediates for the synthesis of a multitude of chiral targets by means of a variety of diastereoselective reactions such as those illustrated in Scheme 2.     

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.     

Palladium-Catalyzed Cascade sp2 C−H Functionalization/Intramolecular Asymmetric Allylation: From Aryl Ureas and 1,3-Dienes to Chiral Indolines

A chiral Pd^II-catalyzed cascade sp² C−H functionalization/intramolecular asymmetric allylation reaction is reported. A new chiral sulfoxide–oxazoline (SOX) ligand bearing single chiral center on the sulfur was identified as the optimal ligand for the reaction, being efficient both in the C−H cleavage step and the stereocontrol of the allylation step. The broad scope of this method with respect to aryl ureas and 1,3-dienes enables the rapid construction of valuable chiral indoline derivatives with high yields and enantioselectivities (up to 99 % yield, up to 95:5 e.r.).     

具有生物活性的4-色满酮衍生物的合成进展

4-色满酮衍生物在自然界中广泛存在,大多数都具有生物活性。具有生物活性的4-色满酮衍生物又大多具有手性,尤其C2位置。有关它们的不对称合成引起了有机合成工作者的广泛关注。C2(手性)-4-色满酮衍生物合成的关键是C2手性中心的控制合成。本文根据4-色满酮衍生物构建方式的不同进行分类,概述了近十几年来合成C2(消旋或手性)4-色满酮衍生物的最新方法, 侧重讨论了合成立体结构专一的C2(手性)-4-色满酮的反应特点。     

Catalytic asymmetric addition of beta-keto phosphonates to an activated imine--formation of optically active functionalized phosphonate alpha-amino acid derivatives

The direct stereoselective addition of an activated imine to beta-keto phosphonates in the presence of chiral Lewis acid complexes is developed. The evaluation of different activated imines shows that an N-tosyl-alpha-imino ester adds in a diastereo- and enantioselective fashion to beta-keto phosphonates activated by especially chiral copper(II)-bisoxazoline complexes. An evaluation of Lewis acids, chiral ligands and reaction conditions, such as solvent, bases and other additives, shows that high yields, moderate diastereoselectivity and good enantioselectivity are obtained. The scope of the reaction is demonstrated for the reaction of beta-keto phosphonates and finally, the mechanism for the catalytic stereoselective step is presented.     

A practical asymmetric synthesis of trans-4,5-benzhydrindan-1-ones as a precursor of A-nor B-aromatic steroidal compounds

The enantio-controlled synthesis of trans-4,5-benzhydrindan-1-ones was achieved by means of a stereoselective [4+2] cycloaddition of o-quinodimethanes generated by a thermal cleavage of benzocyclobutene derivatives as a key step. The chiral substrates of the thermal reaction were synthesized by a diastereoselective Grignard addition to the chiral O-isopropylideneglyceroketones connected to a benzocyclobutene ring, which were simply prepared from D-mannitol as a chiral source. This approach can provide a new efficient access to A-nor B-aromatic steroidal compounds.     

One-step stereoselective synthesis and NMR chiral shift properties of a novel hexacoordinated phosphorus cation

[reaction: see text] Tropolone, binol, and PCl(5) react in CH(2)Cl(2) at reflux to generate in one step a novel C(2)-symmetric hexacoordinated phosphorus cation of configuration controlled by the binol ligand. It behaves as an efficient NMR chiral shift agent for chiral anionic phosphate and borate anions.     

Diastereoselective β-elimination. Synthesis of chiral alkoxy-allenes

Chiral-alkoxy-allenes are obtazned by reaction by chiral acetyleric acetals with Grignard reagents in the presence of catalytic amount of copper salt. The crucial step is a highly diastereoselective β-elimination reaction of the transient alkenyl organometallic species.     

Theoretical study of enantiomeric and geometric control in chiral guanidine‐catalyzed asymmetric 1,4‐addition of 5H‐oxazol‐4‐ones

Density functional theory calculations are used to study the reaction mechanism and origins of high stereoselectivity in chiral guanidine‐catalyzed asymmetric 1,4‐addition of 5H‐oxazol‐4‐ones. The reaction involves proton abstraction of 5H‐oxazol‐4‐one, C—C bond formation, and proton transfer. N1 atom of chiral guanidine exchanges its character as base and acid to activate 5H‐oxazol‐4‐one and to facilitate the product formation. The role of N2—H2 is not only H‐bond donor for 5H‐oxazol‐4‐one but also electron accepter for N1. The enantioselectivity related with rate‐limiting step 1 and Z/E selectivity determined in step 2 are primarily influenced by a five to six‐membered ring link in the backbone of chiral guanidine. The reaction proceeds along the favorable path with smaller rotations of the linked bonds. The enantioselectivity is improved with guanidine involving an electron‐deficient and bulky substituent. With methyl ether‐protected hydroxy in structure, the catalytic ability and enantioselective control of guanidine are extraordinarily low, affording the opposite enantiomer as major product. Z‐isomers are preferred in all cases. © 2013 Wiley Periodicals, Inc.