杂双金属复合物ZABDP催化芳香酮与芳香醛的直接不对称Aldol反应

合成了新型的手性铝/锌杂双金属复合物(R,S,S)-3,3'-二[(N-二苯基脯氨醇)甲基]-2,2'-二羟基-1,1'-联萘酚铝/锌复合物(ZABDP).在催化芳香酮与芳香醛的羟醛缩合(Aldol)反应中,该复合物中的铝作为路易斯酸活化醛,锌的烷氧化物作为Br?nsted碱,使苯乙酮形成活性锌的烯醇化物,2种金属的应用使得芳香醛与芳香酮的直接不对称Aldol反应顺利进行,反应的对映选择性最高达90%,产率最高达99%.     

手性螺环双膦氧化物催化的不对称还原-Aldol反应(英文)

以螺环膦氧化合物为催化剂及三氯硅氢为还原剂,发展了手性Lewis碱催化的烯酮与醛的不对称还原-Aldol反应.该类催化剂在查耳酮以及类似物与各种醛的不对称还原-Aldol反应中表现出较高的反应活性和良好的立体选择性,以较好的产率(45%-88%)、中等到优秀的非对映选择性(8:92-100:0)以及最高达95%的ee值得到相应的还原Aldol产物.     

手性三齿席夫碱金属络合物催化的不对称反应*

各种手性三齿席夫碱与金属（钛, 铬, 钒, 铁, 铜, 铝）形成的络合物,在催化醛的硅腈化、Diels-Alder、Aldol、杂ene、硫化物的氧化等不对称反应中具有良好的催化活性和对映选择性;其中一些催化体系已成功的应用于天然产物的全合成中,该研究取得了系统性的研究成果。本文综述了手性三齿席夫碱金属络合物在不对称催化反应中的研究进展,同时,探讨了催化剂结构和反应条件对其催化活性和对映选择性的影响。     

4-磺酰胺-L-脯氨酸衍生物的合成及其水相中不对称催化Aldol反应的性能（英文）

以4-羟基-L-脯氨酸为原料合成了4-对甲基苯磺酰胺-L-脯氨酸催化剂1a-b,通过IR,1~H NMR和HR MS对其结构进行了表征,并考察了其水相中对不对称Aldol反应的催化性能.结果表明两种催化剂在水相中均能很好的催化Aldol反应,仅用5mol%的催化剂即可得到很好的催化效果,产率高达93%,非对映选择性高达94∶6,而对映选择性高达99%.     

一个新的Cu(II)-二胺配合物催化的Henry反应

研究了L-脯氨酸制得的C2-对称二胺,与醋酸铜形成新的配合物,催化各种醛与硝基烷烃间的Henry反应。 考察了反应温度、溶剂和催化剂用量对收率和反应速率的影响。 研究结果表明,在室温下,以乙醇作为反应溶剂时,摩尔分数10%的二胺醋酸铜配合物能够有效地催化醛与硝基甲烷反应,生成相应的β-硝基醇,收率为60%~92%。 醛与硝基乙烷的Henry反应产物具有非对映立体选择性。 芳香醛参与Henry反应产物的非对映选择性高达24∶1,但脂肪醛为底物时,此催化剂对Henry反应的非对映选择性不明显。     

2-氨基-3-羟基环戊烯-1-腈衍生物的合成和晶体结构

用低价钛试剂(TiCl~4-Zn)与α,α-(4-氯苯基)(二氰甲基)甲基苯基酮反应合成了非对映消旋体(3R,5S;3S,5R)和(3R,5R;3S,5S)2-氨基-3-羟基-3-苯基-5-对氯苯基环戊烯-1-腈。并用X射线衍射分析确定了这两个非对映异构体的构型。     

有机碲氧化物催化合成α,β-不饱和腈,腈酯和腈酰胺

本文报道了应用双对-甲氧苯基氧化碲(BMPTO)催化合成α,β-不饱和腈,腈酯和腈酰胺的简便方法。收率73～97％。反应具有较好的立体选择性,所有产物经熔点、IR、~1H NMR证实为E-型异构体。     

氰化钠和醛及苦杏仁粗酶一锅法合成手性氰醇

直接使用固体氰化钠代替易挥发的HCN为氰源,用来源于苦杏仁的(R)-醇腈酶粗酶催化和醛的反应,并加入足量的HOAc来抑制非酶促反应和手性氰醇产物的外消旋化,一锅法合成了手性氰醇.考察了酸、(R)-醇腈酶粗酶、水、氰化钠和反应温度等因素对反应的影响.大部分反应底物的产物的产率及ee值都大于95%.该方法简单、安全、低成本、高对映选择性和收率,具有很好的应用价值.     

反式2,3-二芳基取代-1-氨基环丙烷羧酸的合成及其结构研究

芳香醛与马尿酸在Erlenmeyer反应条件下缩合得到(Z)-2-苯基4芳亚甲基-5(4H)-噁唑酮,然后在室温下与芳基重氮甲烷通过非对映高立体选择性1,3-偶极环加成反应得到螺环化合物,再经醇解开环、水解去保护合成出反式2,3-二芳基-1-氨基取代环丙烷羧酸．通过元素分析,IR,^1H NMR,^13C NMR,MS和X射线晶体测定,确认了它们的化学结构和立体构型．实验结果表明,通过选择适当的芳香醛和芳基重氮甲烷,可以得到不同立体构型的反式2,3-二芳基取代-1-氨基环丙烷羧酸．     

β-乙酰氨基环戊烯腈的不对称催化氢化

利用不对称催化氢化法制备β乙酰氨基环戊腈,并考察了配体、催化剂前体、溶剂、温度、压力以及时间对反应活性和对映选择性的影响.实验结果表明,在优化条件下,[ Rh( COD)-DuanPhos] BF4催化不对称氢化β-乙酰氨基环戊烯腈的转化率为61％,对映体的ee值为60％.     

One-pot synthesis of α-alkylated nitriles with carbonyl compounds through consecutive aldol reaction/hydrogenation using a hydrotalcite-supported palladium nanoparticle as a multifunctional heterogeneous catalyst

α-Alkylation of various nitriles with carbonyl compounds successfully proceeded using a hydrotalcite-supported palladium nanoparticle as a multifunctional catalyst. The alkylated nitriles were formed through aldol reaction at base sites on the hydrotalcite surface followed by hydrogenation by molecular hydrogen on the palladium nanoparticle.     

Tandem reactions of 1,2-allenic ketones leading to substituted benzenes and α,β-unsaturated nitriles

One-pot double Michael addition/intramolecular aldol reaction/decarboxylation of 1,2-allenic ketones with cyanoacetate offers an efficient and convenient approach to highly functionalized benzenes. With 2-substituted cyanoacetates, the reaction proceeds via a different tandem process to afford α,β-unsaturated nitriles effectively.     

Reconstructed hydrotalcite as a highly active heterogeneous base catalyst for carbon-carbon bond formations in the presence of water

The aldol reaction of carbonyl compounds is efficiently catalyzed by reconstructed hydrotalcites, obtained by treating the Mg-Al mixed oxide with water, as solid base catalysts in the presence of water. The catalysis of the reconstructed hydrotalcites is attributable to the surface base sites, created during the organization of the layered structure, with uniformly distributed strength. Furthermore, the reconstructed hydrotalcites provide a unique acid-base bifunctional surface capable of promoting the Knoevenagel and Michael reactions of nitriles with carbonyl compounds.     

Rhodium-catalyzed reductive aldol reactions using aldehydes as the stoichiometric reductants

Chelated acyl rhodium hydrides, generated from the addition of [Rh(dppe)]ClO4 to beta-sulfide-substituted aldehydes, can function as the stoichiometric reductants in reductive aldol processes. Unsaturated nitriles, esters, and ketones can be used as enolate equivalents, and a variety of simple alpha- and beta-substituted aldehydes can be employed. The use of a second, more electrophilic, aldehyde allows three-component reactions to be performed.     

Enantioselective construction of quaternary stereogenic carbons by the Lewis base catalyzed additions of silyl ketene imines to aldehydes

Silyl ketene imines derived from a variety of alpha-branched nitriles have been developed as highly useful reagents for the construction of quaternary stereogenic centers via the aldol addition reaction. In the presence of SiCl4 and the catalytic action of chiral phosphoramide (R,R)-5, silyl ketene imines undergo extremely rapid and high yielding addition to a wide variety of aromatic aldehydes with excellent diastereo- and enantioselectivity. Of particular note is the high yields and selectivities obtained from electron-rich, electron-poor, and hindered aldehydes. The nitrile function serves as a useful precursor for further synthetic manipulation.     

Synthetic approach to analogues of the original structure of sclerophytin A

A route to analogues of the original structure of sclerophytin A is described. The beta-anomer of dideoxyribosyl nitriles 10a,b (prepared from glutamic acid) was converted into the methyl ketone 11. Addition of a silylated acetylide to 11 in diethyl ether/trimethylamine gave mainly 22a. Alkylation with methallyl halide and ozonolysis gave the ketone 24, which was then converted by hydrogenation and a second ozonolysis into the keto aldehyde 26. A two-step aldol process afforded the desired 3-pyrone 27 in good overall yield. However, several methods for the conversion of this enone 27 into the desired sclerophytin analogue 2 failed.     

New reactions of gamma-halocarbanions: simple synthesis of substituted tetrahydrofurans

The treatment of 4-chlorobutyronitrile, 3-chloropropyl phenyl sulfone, and other related compounds with a base afforded gamma-halocarbanions that undergo fast intramolecular substitution of the halogen to produce substituted cyclopropanes. We found that these short-lived carbanionic intermediates can be trapped with active external electrophilic partners, such as aldehydes, to give the aldol anions. These anions then undergo rapid intramolecular substitution of chloride to produce 2,3-disubstituted tetrahydrofurans. Under the right conditions, yields of tetrahydrofurans are excellent. Similar reactions with ketones gives 2,2,3-trisubstituted furans, but this process is usually less efficient. Ratios between the rates of intramolecular and intermolecular processes were qualitatively estimated by competitive experiments. It was shown that gamma-halo and gamma-trimethylammonium substituents substantially increase the kinetic CH acidity of alkane nitriles and sulfones.     

Environmentally friendly one-pot synthesis of alpha-alkylated nitriles using hydrotalcite-supported metal species as multifunctional solid catalysts

A ruthenium-grafted hydrotalcite (Ru/HT) and hydrotalcite-supported palladium nanoparticles (Pd(nano)/HT) are easily prepared by treating basic layered double hydroxide, hydrotalcite (HT, Mg(6)Al(2)(OH)(16)CO(3)) with aqueous RuCl(3)n H(2)O and K(2)[PdCl(4)] solutions, respectively, using surface impregnation methods. Analysis by means of X-ray diffraction, and energy-dispersive X-ray, electron paramagnetic resonance, and X-ray absorption fine structure spectroscopies proves that a monomeric Ru(IV) species is grafted onto the surface of the HT. Meanwhile, after reduction of a surface-isolated Pd(II) species, highly dispersed Pd nanoclusters with a mean diameter of about 70 A is observed on the Pd(nano)/HT surface by transmission electron microscopy analysis. These hydrotalcite-supported metal catalysts can effectively promote alpha-alkylation reactions of various nitriles with primary alcohols or carbonyl compounds through tandem reactions consisting of metal-catalyzed oxidation and reduction, and an aldol reaction promoted by the base sites of the HT. In these catalytic alpha-alkylations, homogeneous bases are unnecessary and the only by-product is water. Additionally, these catalyst systems are applicable to one-pot syntheses of glutaronitrile derivatives.     

Enantioselective Aldol Reactions Catalyzed by Chiral Phosphine Oxides

The development of enantioselective aldol reactions catalyzed by chiral phosphine oxides is described. The aldol reactions presented herein do not require the prior preparation of the masked enol ethers from carbonyl compounds as aldol donors. The reactions proceed through a trichlorosilyl enol ether intermediate, formed in situ from carbonyl compounds, which then acts as the aldol donor. Phosphine oxides activate the trichlorosilyl enol ethers to afford the aldol adducts with high stereoselectivities. This procedure was used to realize a directed cross‐aldol reaction between ketones and two types of double aldol reactions (a reaction at one/two α position(s) of a carbonyl group) with high diastereo‐ and enantioselectivities.     

Preparation of 5-substituted 1H-tetrazoles from nitriles in water.

The addition of sodium azide to nitriles to give 1H-tetrazoles is shown to proceed readily in water with zinc salts as catalysts. The scope of the reaction is quite broad; a variety of aromatic nitriles, activated and unactivated alkyl nitriles, substituted vinyl nitriles, thiocyanates, and cyanamides have all been shown to be viable substrates for this reaction.