A tandem non-aldol aldol Mukaiyama aldol reaction

[reaction: see text] A new one-pot tandem aldol process is described in which a secondary epoxy silyl ether is converted into the 1,5-bis-silyloxy-3-alkanone in good yield. Thus, treatment of the epoxy silyl ether 8 with TBSOTf and base affords the silyl enol ether 9 via non-aldol aldol rearrangement and addition of benzaldehyde and TBSOTf gives the ketone 10 with 4:1 syn selectivity. The diastereoselectivity changes to an anti preference for most aldehydes. This anti selectivity overwhelms the normal Felkin-Ahn preference; namely, the 1,5-anti isomer predominates even when it is anti-Felkin-Ahn.     

Review of the aldol reaction

Aldol condensation is an important synthetic method widely used in organic synthesis. Development of catalytic methods that avoids the production of stoichiometric by-products while maintaining high levels of control available from stoichiometric processes provides an atom-economical alternative for these important transformations. Indeed, numerous catalysts for the aldol reaction have been reported in recent years, including enzymes, catalytic antibodies, organometals, organocatalysts, and small molecules. The direct aldol reaction is the most important reaction employed by synthetic chemists and is common in nature. Recently, various Lewis acids have been examined as catalysts for aldol reactions, but aldol condensation in a micellar medium has not been studied in detail so far. Because of stronger environmental concerns, organic reactions in green media, especially in water, have attracted more attention. It is believed that micelles act as nano reactors to enhance the reaction rates and give very good to excellent yields of end products.     

A ribozyme for the aldol reaction

Directed in vitro evolution can create RNA catalysts for a variety of organic reactions, supporting the "RNA world" hypothesis, which proposes that metabolic transformations in early life were catalyzed by RNA molecules rather than proteins. Among the most fundamental carbon-carbon bond-forming reactions in nature is the aldol reaction, mainly catalyzed by aldolases that utilize either an enamine mechanism (class I) or a Zn(2+) cofactor (class II). We report on isolation of a Zn(2+)-dependent ribozyme that catalyzes an aldol reaction at its own modified 5' end with a 4300-fold rate enhancement over the uncatalyzed background reaction. The ribozyme can also act as an intermolecular catalyst that transfers a biotinylated benzaldehyde derivative to the aldol donor substrate, coupled to an external hexameric RNA oligonucleotide, supporting the existence of RNA-originated biosynthetic pathways for metabolic sugar precursors and other biomolecules.     

Substrate-controlled stereoselectivity in the Yamamoto aldol reaction

The Yamamoto aldol reaction is a vinylogous aldol reaction that relies on bulky aluminium-based Lewis acids. These activate both the aldehyde as well as become part of the enolate moiety. The report discloses the first detailed study on the substrate-controlled Yamamoto aldol reaction in which 2,3-syn and 2,3-anti disubstituted aldehydes serve as the stereodirecting elements. The "size" of the substituent in the β-position strongly determines the facial selectivity of enolate addition to the aldehyde. Large substituents favour formation of 1,3-syn diols while slim alkynyl groups preferentially lead to 1,3-anti products.     

Boron-mediated aldol reaction of carboxylic esters: complementary anti- and syn-selective asymmetric aldol reactions

The boron-mediated aldol reaction of carboxylic esters is described in detail. Contrary to the general belief that carboxylic esters are inert under the condition of the boron enolate formation, propionate esters are enolized with certain combinations of a boron triflate and an amine. More importantly, the stereochemical course of the aldol reaction can be controlled by the judicious selection of the enolization reagents. Treatment of propionate esters with c-Hex2BOTf and triethylamine produces anti-aldol products, and that with Bu2BOTf and diisopropylethylamine gives syn-aldol products selectively after reaction with aldehydes. Complementary anti- and syn-selective asymmetric aldol reactions with structurally related, readily available chiral norephedrine-derived propionate esters are developed.     

Stereoselective chloroacetate aldol reactions: syntheses of acetate aldol equivalents and darzens glycidic esters

Aldol reaction of the Ti-enolate derived from cis-1-tosylamido-2-indanyl chloroacetate with representative aldehydes proceeded in excellent yield and high diastereoselectivities. Removal of chlorine provided alternative access to highly diastereoselective acetate aldol equivalents or the corresponding glycidic ester condensation products. [reaction: see text]     

A solution to the cyclic aldol problem

[formula: see text] A protocol for achieving stereoselective aldol reactions with cyclic ketones is presented. In terms of yield, the process is particularly effective when a quaternary center at the alpha-carbon of the beta-hydroxy ketone product is created. The stereochemical outcome, anti or syn, is achieved by the Lewis acid-mediated ring expansion of stereochemically homogeneous epoxides in a reaction related to the pinacol rearrangement.     

Stereoselective aldol condensation of 3,4-dihydro-3-oxo-2H-1,4-benzothiazines: X-ray determination of the aldol stereostructure

3,4-Dihydro-2-methyl-3-oxo-2$\text{H}$-1,4-benzothiazines (1) give erythro-stereoselective aldol condensation. The stereochemistry was determined by single crystal X-ray diffraction. The aldol condensation takes place under kinetic control. The reasons for the observed stereoselectivity are discussed.     

腈类Aldol反应的发展与应用

芳香腈与醛的Aldol反应已被证明是一种合成各种反式β-羟基腈的有效途径。该反应的反式非对映立体选择性可用过渡态模型中的非成键立体相互作用来解释, 并得到了^6Li, ^1^5N和^1^3C NMR波谱数据的证实。本报告通过变醛和芳香腈试剂的电子结构, 调查了电子效应在决定该Aldol反应非对映立体选择中的作用。其次, 脂肪腈反应的初步研究结果也有论及。最后, 本文介绍了由β-羟基腈向各种纯非对映异构体, 多功能性的开环和杂环γ-氨基醇衍生物的转化反应。     

Reversibility in the boron-mediated ketone-ketone aldol reaction

The boron-mediated ketone-ketone aldol reaction is demonstrated, through 1H NMR studies, to be reversible, in contrast to the strictly irreversible aldol reactions of boron enolates with aldehydes.     

The boron-mediated ketone-ketone aldol reaction

The first examples of the directed, boron-mediated aldol reaction between different ketones are presented. Transformation of a variety of ketones to their corresponding boron enolates with Chx₂BCl/Et₃N, followed by reaction with acceptor ketones in diethyl ether, and oxidation of the resultant boron aldolate (H₂O₂, MeOH/pH 7 buffer), provided the aldol addition products. The reaction was most facile when cyclic ketones were used, with the highest yields obtained for the reaction of boron enolates with cyclohexanone as the acceptor.     

Enantioselectivity in the boron aldol reactions of methyl ketones

DFT computed transition states quantitatively explain the surprising stereochemical outcome of unsubstituted enolborinates in diastereoselective and enantioselective boron aldol reactions.     

Acid catalyzed aldol condensation in the gas phase

The gas phase reaction of acetaldehyde with a Brønsted acid in a chemical ionization source yields protonated crotonaldehyde, as shown by its collisional activation mass spectrum. This is thus analogous to the well known aldol condensation in solution, in which the initial aldol adduct loses water to yield crotonaldehyde. The possibility of a common mechanism for the gas phase and solution reactions is discussed.     

Oxazaborolidinone-promoted vinylogous Mukaiyama aldol reactions

delta-Hydroxy-alpha,beta-unsaturated carbonyl compounds were prepared in one step via the vinylogous Mukaiyama aldol reactions with O,O-silyl ketene acetals. Isopropyl alcohol as additive and tryptophane-based B-phenyloxazaborolidinone were required for obtaining the gamma-alkylated product in high enantioselectivities.     

Stereo- and regio-controlled aldol synthesis

Treatment of (Z)-trimethylsilyl enol ethers with dibutylboryl trifluoromethanesulfonate followed by removal of trimethylsilyl triflate generated and addition of aldehydes affords the corresponding erythro aldols with almost complete stereo- and regio-selectivities.     

Organocatalytic asymmetric aldol reaction in the presence of water

Water was found to be a suitable solvent for the l-prolinethioamide catalysed aldol reaction of various cyclic ketones with aromatic aldehydes. Treatment of 4-nitrobenzaldehyde with as little as 1.2 equiv. of cyclohexanone in the presence of the protonated catalyst 1-TFA, afforded aldol products in high yields (up to 97%) with high diastereo- and enantioselectivity (up to >5 : 95 dr and 98% ee). The use of a high excess of ketone was avoided by conducting the aldol addition in the presence of water. Furthermore, different 'salting-out' and 'salting-in' salts were investigated and it was proven that the rate of acceleration and the stereochemical outcome of the reaction are affected by hydrophobic aggregation. Scope and limitation studies revealed that electron deficient aldehydes afforded aldol products with high stereoselectivity in the presence of 1-Cl(2)CHCO(2)H. It was shown that various cyclic ketones, under the conditions found, gave aldol products with fair yields, even if they are used in substoichiometric amounts (1.2 to 2.0 equiv.).     

Modern aldol methods for the total synthesis of polyketides

The aldol reaction is one of the most important methods for the stereoselective construction of polyketide natural products, not only for nature but also for synthetic chemistry. The tremendous development in the field of aldol additions during the last 30 years has led to more and more total syntheses of complicated natural products. This Review illustrates by means of selected syntheses of natural products the new variants of the aldol addition. This includes aldol additions with various metal enolates, as well as metal-complex-catalyzed, organocatalytic, and biocatalytic methods.     

Current progress in the asymmetric aldol addition reaction

Control of stereochemistry during aldol addition reactions has attracted considerable interest over the years as the aldol reaction is one of the most fundamental tools for the construction of new carbon-carbon bonds. Several strategies have been implemented whereby eventually any single possible stereoisomeric aldol product can be accessed by choosing the appropriate procedure. With earlier methods, stoichiometric quantities of chiral reagents were required for efficient asymmetric induction, with the auxiliary most often attached covalently to the substrate carbonyl. Lewis acid catalyzed addition reactions of silyl enolates to aldehydes (Mukaiyama reaction) later opened the way for catalytic asymmetric induction. In the last few years, both chiral metal complexes and small chiral organic molecules have been found to catalyse the direct aldol addition of unmodified ketones to aldehydes with relatively high chemical and stereochemical efficiency. These techniques along with the more recent developments in the area are discussed in this tutorial review.