手性胶束中的有机反应(Ⅴ)——手性胶束中查耳酮的不对称环氧化

本文报道查耳酮用H₂O₂在手性表面活性剂N,N-二甲基-N-十二烷基麻黄素澳化铵(1a)及N,N-二甲基-N-十六烷基麻黄素溴化铵(1b)形成的手性胶柬水溶液中的不对称环氧化反应,得到相应的手性α,β-环氧酮,对映体过量为5～8%.     

烯丙醇不对称环氧化新方法

一个新的金属催化的烯丙醇不对称环氧化(asymmetric epoxidation A.E)似比以前所有烯丙醇不对称环氧化方法为好。这个比较简单的新方法引人注意的一个方面是对映选择性非常之高而且所需试剂(+)-或(-)-酒石酸二酯,四异丙氧钛和叔丁基过氧化氢都容易得到。自从 1980年 Sharpless等发现这个方法以     

昆虫信息素的结构鉴定与合成XX.应用不对称环氧化中的动力学拆分从消旋体合成光学活性的午毒蛾性信息素

(±-烯丙醇(2),经过不对称环氧化反应中的动力学拆分得到手性环氧醇3,e.e.92%.3经过5步反应得(7R,8S)-午毒娥性信息素(1a),总得率从3算起为60%。     

昆虫信息素的结构鉴定与合成 ⅩⅩ.应用不对称环氧化中的动力学拆分从消旋体合成光学活性的午毒蛾性信息素

(±)-烯丙醇(2),经过不对称环氧化反应中的动力学拆分得到手性环氧醇3,e.e.92％。3经过5步反应得(7R,8S)-午毒蛾性信息素(1a),总得率从3算起为60％。     

不对称烯丙基化反应合成含有三苯胺核心单元的荧光非天然氨基酸衍生物

报道了一种钯催化噁唑酮和烯丙醇的不对称烯丙基化反应合成相应的三苯胺核心非天然氨基酸化合物的方法.反应收率高达95%,对映选择性过量值最高为97%ee.该反应操作简单,条件温和,原子经济性好,水为唯一副产物.     

手性的H‘4-NOBIN衍生物在不对称加成和取代反应中的应用

以手性 H’4-NOBIN为原料合成了新型手性氨基酚2和N,P配体5, 并将化合物2应用于催化二乙基锌对醛的不对称加成反应, 产率达90%, 对映体过量最高为45.9% ee. 化合物5用于钯催化的1,3-二苯基-2-烯丙基乙酸酯的不对称烯丙基烷基化反应, 产率为89%, 对映体过量最高为81.6% ee. 结果表明氨基酚2手性诱导作用弱于未氢化的NOBIN, 但却高于其八氢衍生物, 而N,P配体5给出相反的结果.     

几种外消旋环氧化合物的水解动力学拆分

2 羟基 3 叔丁基 5 甲基苯甲醛 (5 )与 (S ,S) 1 ,2 二苯基乙二胺 ((S,S) 1 1 )缩合 ,得手性Salen 1 2 ,再与Co(OAc) 2 ·4H2 O反应得钴络合物 1 3 ,后者经氧化制得Salen型手性催化剂 (S ,S) 2。几种外消旋环氧化合物用 (S ,S) 2催化水解进行动力学拆分 ,同时得到光学活性环氧化合物和二醇 ,对映体过量最高达 61 6%。根据分子力学对催化剂构象优化的结果讨论了催化剂结构对其催化效率和选择性的影响     

双乙烯基甲醇的不对称环氧化合成午毒蛾性信息素

双乙烯基甲醇2经过Sharpless不对称环氧化反应合成到高光学纯的午毒蛾Porthetria dispar性信息素(7R,8S)-1a,对映体过量大于99％,总产率达43.9％。     

四氟乙烯齐聚体的反应 Ⅱ.四氟乙烯五聚体和烯丙醇的反应及反应产物的转化

全氟(3,4-二甲基-4-乙基己烯-[2])(1)虽早已合成,但有关它的反应至今报道不多。本文报道化合物1和烯丙醇在不同条件下的亲核取代反应和2-(1′-烯丙氧基四氟乙基)-全氟(3-甲基-3-乙基戊烯-[1])(2)的化学转化。1和烯丙醇的反应随溶剂和碱的变化而得到不同的产物。1和烯丙醇钠在FC-113中,于-40℃左右反应可得到2。若1与过量烯丙醇、三乙胺在35°～40℃反应40min,则得到2-烯丙氧基-全氟(3,4-二甲基-4-乙基已烯-[2])(3),但产率很低,绝大部分回收原料,并获得3-三氟甲基-3-五氟乙基-2,2-二氢五氟戊酸烯丙酯(5a)。若1与烯丙醇、碳酸钾在丙酮中于50～60℃反应,则主要产物为4和5a。以上化合物的结构均经~1HNMR,~(19)FNMR,IR和元素分析等证明。     

不具C2对称轴的Co（Ⅲ）（Salen)催化的末端环氧化合物的水解拆分

用（S）-3-甲基-1，2-丁二胺或（R）-1，2-丙二胺为原料与2-羟基-5-甲-3- 叔丁基苯甲醛缩合，得到不具C2对称轴的手性Salen, 与Co(Ⅱ）络各并氧化后得到 4a或4b.4a和4b成功地应用于外消旋末端环氧化合物的水解拆分，取得了较好的产 率，但产物的对映体过量值较低。     

Chirality transfer in Au-catalyzed cyclization reactions of monoallylic diols: selective access to specific enantiomers based on olefin geometry

The gold(I)-catalyzed cyclization of monoallylic diols to form tetrahydropyrans is shown to be highly stereoselective when chiral allylic alcohols are employed. Substrates that differ only in olefin geometry provide enantiomeric products from formal S(N)2' reactions in high yields with excellent chirality transfer. The allylic alcohol stereochemistry also efficiently controls the facial selectivity when the substrates include additional stereocenters.     

Catalytic asymmetric cyclopropanation of allylic alcohols with titanium-TADDOLate: scope of the cyclopropanation reaction.

A substoichiometric amount of titanium-TADDOLate complex was effective at catalyzing the cyclopropanation reaction of allylic alcohols in the presence 1 equiv of bis(iodomethyl)zinc. After initial optimization of the catalyst structure, excellent yields and enantiomeric ratios were obtained for 3-aryl- or 3-heteroaryl-substituted allylic alcohols (up to 97:3). Alkyl-substituted allylic alcohols gave modest yields and enantiomeric ratios (up to 87:13) but these compare favorably with those observed with other substoichiometric chiral ligands. The full synthetic scope of the reaction is presented in this paper.     

Synthesis of l-cyclopentenyl nucleosides using ring-closing metathesis and palladium-mediated allylic alkylation methodologies

The enantiomeric synthesis of l-cyclopentenyl nucleosides is described. The key intermediate (+)-cyclopentenyl alcohol (8) was prepared from methyl-α-d-galactopyranoside 1 using a ring closing metathesis reaction. Transformation of the allylic alcohol 8 into the allylic acetate (9) or carbonate (10), allows their coupling with purine and pyrimidine bases under Pd(0)-catalyzed Tsuji-Trost allylic alkylation's to yield 12a-c. The Pd catalyzed reaction was found to require the use of AlEt₃.     

Rhodium-catalyzed asymmetric allylic substitution with boronic acid nucleophiles

An enantio-, regio-, and diastereoselective rhodium(I)-catalyzed desymmetrization of a meso-cyclic allylic dicarbonate with organoboronic acid nucleophiles is described. The rhodium(I) catalyst formed in situ from [Rh(cod)OH]2 and Xyl-P-PHOS allowed the S(N)2' allylic substitution product to be obtained with a range of arylboronic acids in enantiomeric excesses of up to 92% with regioselectivities of up to >20:1.     

Biocatalytic and chemocatalytic approaches to the highly stereoselective 1,2-reduction of an α,β-unsaturated ketone

Two methods are reported for synthesizing a chiral allylic alcohol from the corresponding racemic α,β-unsaturated ketone. Transition metal-based transfer hydrogenation provides the desired allylic alcohol in high enantiomeric purity but low diastereomeric excess. In contrast, an enzymatic dynamic kinetic reduction proceeds with high diastereoselectivity and enantioselectivity.     

Synthesis of 2,6-trans-disubstituted 5,6-dihydropyrans from (Z)-1,5-syn-endiols

Certain (Z)-1,5-syn-diols 2 may be converted into 2,6-trans-5,6-dihydropyrans by using phosphonium salt 4 or phosphorane 5 as dehydrating agents. A more general four step procedure converts the (Z)-1,5-syn-endiols into enantiomeric dihydropyrans ent-3 via regioselective silylation of the allylic alcohol unit followed by mesylate formation and base-promoted nucleophilic displacement.     

Palladium-catalyzed stereospecific synthesis of 2,6-disubstituted tetrahydropyrans: 1,3-chirality transfer by an intramolecular oxypalladation reaction

PdCl2(CH3CN)2 (10 mol %) catalyzed reactions of non-3-ene-2,8-diols 1 and 2 gave 2,6-disubstituted tetrahydropyrans 3 and 4 in excellent yields with high diastereoselectivities (>20:1). Intramolecular cyclizations of the hydroxy nucleophile to the chiral allylic alcohol take place efficiently under mild conditions. A new stereogenic center is generated on the tetrahydropyran ring by 1,3-chirality transfer from the chiral allylic alcohol via a syn-SN2' type process. Cis tetrahydropyran 3E was formed from syn-2,8-diols 1a and 2a, and trans tetrahydropyran 4E was formed from anti-2,8-diol 1b, stereospecifically. Cis tetrahydropyran bearing a cis alkene 3Z was obtained from 2b at -40 degrees C, while 4E was formed from 2b in the presence of catalytic amount of water at -40 degrees C. The face selectivity of these cyclizations can be rationalized by taking a favorable conformation of the intermediary Pd pi-complex with allylic alcohols, escaping the allylic strain and 1,3-diaxial interactions. A stereocontrolled synthesis of optically pure 2-alkenyl-6-methyltetrahydropyran 17 was achieved efficiently in four steps from 6-silyloxy-1-heptyne 13 with an aldehyde and included asymmetric alkynylation, partial reduction of alkyne, deprotection of the silyl group, and the stereospecific cyclization.     

Concise syntheses of nonracemic gamma-fluoroalkylated allylic alcohols and amines via an enantiospecific palladium-catalyzed allylic substitution reaction

Alpha-fluoroalkylated allyl mesylates reacted with various carboxylates and amines in the presence of tetrakis(triphenylphosphine)palladium(0) catalyst to give the corresponding gamma-fluoroalkylated (E)-allylic alcohol derivatives and amines, respectively, in excellent yields. In almost all cases, no other regio- and stereoisomers were produced. Application of this palladium-catalyzed allylic substitution reaction to various nonracemic mesylates afforded chiral gamma-fluoroalkylated allylic alcohol derivatives and amines without any loss of enantiomeric excess through the reaction.     

Kinetic resolution of acyclic secondary allylic silyl ethers catalyzed by chiral ketones.

Kinetic resolution of acyclic secondary allylic silyl ethers by chiral dioxiranes generated in situ from chiral ketones (R)-1 and (R)-2 and Oxone was investigated. An efficient and catalytic method has been developed for kinetic resolution of those substrates with a CCl(3), tert-butyl, or CF(3) group at the alpha-position. In particular, high selectivities (S up to 100) were observed for kinetic resolutions of racemic alpha-trichloromethyl allylic silyl ethers 7 and 9-15 catalyzed by ketones (R)-2. Both the recovered substrates and the resulting epoxides were obtained in high enantiomeric excess. On the basis of steric and electrostatic interactions between the chiral dioxiranes and the racemic substrates, a model was proposed to rationalize the enantioselectivities and diastereoselectivities in the chiral ketone-catalyzed kinetic resolution process.     

Ene reaction of singlet oxygen,triazolinedione, and nitrosoarene with chiral deuterium-labeled allylic alcohols: the interdependence of diastereoselectivity and regioselectivity discloses mechanistic insights into the hydroxy-group directivity

The ene reaction of singlet oxygen ((1)O(2)), triazolinedione (TAD), and nitrosoarene, specifically 4-nitronitrosobenzene (ArNO), with the tetrasubstituted 1,3-allylically strained, chiral allylic alcohol 3,4-dimethylpent-3-en-2-ol (2) leads to the threo-configured ene products in high diastereoselectivity, a consequence of the hydroxy-group directivity. Hydrogen bonding favors formation of the threo-configured encounter complex threo-EC in the early stage of ene reaction. For the analogous twix deuterium-labeled allylic alcohol Z-2-d(3), a hitherto unrecognized dichotomy between (1)O(2) and the ArNO and TAD enophiles is disclosed in the regioselectivity of the tetrasubstituted alcohol: Whereas for ArNO and TAD, hydrogen bonding with the allylic hydroxy group dictates the regioselectivity (twix selectivity), for (1)O(2), the cis effect dominates (twin/trix selectivity). From the interdependence between the twix/twin regioselectivity and the threo/erythro diastereoselectivity, it has been recognized that the enophile also attacks the allylic alcohol from the erythro pi face without assistance by hydrogen bonding with the allylic hydroxy functionality.