Aldol cyclohexanone

MCPBA, DMF, —63°, 100% yield.Hydrazones of aldols are cleaved without elimination under these conditions. " An axial a-methyl group on a cyclohexanone does not epimerize under these conditions. ... 

The reaction of a cyclic ketone—e.g. cyclohexanone 1—with methyl vinyl ketone 2 resulting in a ring closure to yield a bicyclic a ,/3-unsaturated ketone 4, is called the Robinson annulation This reaction has found wide application in the synthesis of terpenes, and especially of steroids. Mechanistically the Robinson annulation consists of two consecutive reactions, a Michael addition followed by an Aldol reaction. Initially, upon treatment with a base, the cyclic ketone 1 is deprotonated to give an enolate, which undergoes a conjugate addition to the methyl vinyl ketone, i.e. a Michael addition, to give a 1,5-diketone 3 ... 

Aldol condensation of the methoxymethyl ether of m-methoxybenzaldehyde (83) with cyclohexanone affords the conjugated ketone 84. Michael addition of dimethyl amine leads to the ami noketone Reduction of the ketone... 

The Stork enamine reaction and the intramolecular aldol reaction can be carried out in sequence to allow the synthesis of cyclohexenones. For example, reaction of the pyrrolidine enamine of cyclohexanone with 3-buten-2-one. followed by enamine hydrolysis and base treatment, yields the product indicated. Write each step, and show the mechanism of each. 

When an enolate is forced to take the E configuration, e.g, the enolate derived from cyclohexanone, predominant formation of the anti-aldol might be expected. Surprisingly, early experiments gave more or less stereorandom results in that the reaction with benzaldehyde gave a ratio of. vvtt/ant/ -aldols of 48 521B 23, Contrarily, recent investigations24 reveal a substantial anti selectivity (16 84), which is lowered in a dramatic manner (50 50) by the presence of lithium salts. Thus, the low stereoselectivity in the early experiments may be attributed to impurities of lithium salts or lithium hydroxide. 

The E-boron enolate from cyclohexanone shows a preference for the anti aldol product. The ratio depends on the boron alkyl groups and is modest (2 1) with di-n-butylboron but greater than 20 1 for cyclopentyl- -hexylboron.16... 

A DFT study found a corresponding TS to be the lowest energy.167 This study also points to the importance of the solvent, DMSO, in stabilizing the charge buildup that occurs. A further computational study analyzed the stereoselectivity of the proline-catalyzed aldol addition reactions of cyclohexanone with acetaldehyde, isobu-tyraldehyde, and benzaldehyde on the basis of a similar TS.168 Another study, which explored the role of proline in intramolecular aldol reactions, is discussed in the next section.169... 

Figure 2.P25 shows the calculated [B3LYP/6-31G(4,/f)] reaction energy profile for the aldol addition of benzaldehyde and cyclohexanone catalyzed by alanine. The best TSs leading to (S,R) (R,S) (S,S) and (R,R) products are given. What factors favor the observed (R,S) product ... 

Fig. 2.P25. Top Reaction energy profile for alanine-catalyzed aldol reaction of benzaldehyde and cyclohexanone. Bottom Diastereomeric transition structures. Reproduced from Angew. Chem. Int. Ed. Engl., 44, 7028 (2005), by permission of Wiley-VCH...

Classical Aldol. Aldol reaction is an important reaction for creating carbon-carbon bonds. The condensation reactions of active methylene compounds such as acetophenone or cyclohexanone with aryl aldehydes under basic or acidic conditions gave good yields of aldols along with the dehydration compounds in water.237 The presence of surfactants led mainly to the dehydration reactions. The most common solvents for aldol reactions are ethanol, aqueous ethanol, and water.238 The two-phase system, aqueous sodium hydroxide-ether, has been found to be excellent for the condensation reactions of reactive aliphatic aldehydes.239... 

The stereoselective intramolecular Henry reactions have been reported by Seebach. The Michael addition of doubly deprotonated acetyl acetaldehyde to l-methylenedioxyphenyl-2-nitroethene followed by subsequent intramolecular nitro-aldol cyclization leads to the diastereomerically pure cyclohexanone derivative, where the nitro and OH groups are cis as shown in Eq. 3.73.114 This reaction is applied to the synthesis of l-desoxy-2-lycorinone as shown in Eq. 3.74.115... 

Ono and coworkers have extended the radical elimination of v/c-dinitro compounds to P-nitro sulfones151 and P-nitro sulfides.138,152 As P-nitro sulfides are readily prepared by the Michael addition of thiols to nitroalkenes, radical elimination of P-nitrosulfides provides a useful method for olefin synthesis. For example, cyclohexanone is converted into allyl alcohol by the reaction shown in Eq. 7.110. Treatment of cyclohexanone with a mixture of nitromethane, PhSH, 35%-HCHO, TMG (0.1 equiv) in acetonitrile gives ahydroxymethylated-P-nitro sulfide in 68% yield, which is converted into the corresponding allyl alcohol in 86% yield by the reaction with Bu3SnH.138 Nitro-aldol and the Michael addition reactions take place sequentially to give the required P-nitro sulfides in one pot. 

For example, large rate enhancements have been reported in the synthesis of chal-cones by crossed-aldol condensations in open vessels, suggesting the participation of specific MW effects [41]. The chalcone 24 was synthesized from cyclohexanone and benzaldehyde in ethanol, in the presence of a catalytic amount of sodium hydroxide (Scheme 4.13), in a MW oven in 90% yield in only 1 min. 

In a frequently cited investigation, House studied the condensations of a variety of metal enolates with aldehydes under conditions of thermodynamic control (14). In the cyclohexanone enolate-benzaldehyde condensation (eq. [5]), it was observed that the zinc enolate (14°C, 5 min) afforded a 5 1 ratio of aldol adducts 5T and... 

A large number of studies have addressed the condensation of cyclic ketones with both aliphatic and aromatic aldehydes under conditions that reflect both thermodynamic (cf. Table 2) and kinetic control of stereochemistry. The data for cyclohexanone enolates are summarized in Table 8. Except for the boryl enolates cited (6), the outcome of the kinetic aldol process for these enolates... 

Kinetic Aldol Condensations of Cyclohexanone Enolates with Aromatic Aldehydes (eq. [18])... 

The interplay between solvent polarity and boron ligand structure in the enhancement of aldol stereoselection has been examined in several systems (6). The representative trends that have been noted for the boryl enolates derived from both cyclohexanone and tert-butyl thiopropionate (eqs. [49] and [50]) are summarized in Table 21. 

The first asymmetric procedure consists of the addition of R2Zn to a mixture of aldehyde and enone in the presence of the chiral copper catalyst (Scheme 7.14) [38, 52]. For instance, the tandem addition of Me2Zn and propanal to 2-cyclohexenone in the presence of 1.2 mol% chiral catalyst (S, R, R)-1S gave, after oxidation of the alcohol 51, the diketone 52 in 81% yield and with an ee of 97%. The formation of erythro and threo isomers is due to poor stereocontrol in the aldol step. A variety of trans-2,3-disubstituted cyclohexanones are obtained in this regioselective and enantioselective three-component organozinc reagent coupling. 

The method involves a regioselective, trans-diastereoselective, and enantioselective three-component coupling, as shown in Scheme 7.26. In this case, the zinc enolate resulting from the 1,4-addition is trapped in a palladium-catalyzed allyla-tion [64] to afford trans-2,3-disubstituted cyclohexanone 96. Subsequent palladium-catalyzed Wacker oxidation [82] yields the methylketone 97, which in the presence of t-BuOK undergoes an aldol cyclization. This catalytic sequence provides the 5,6-(98) and 5,7- (99) annulated structures with ees of 96%. 

Michael addition of cyclohexanones to methyl vinyl ketone followed by intramolecular aldol condensation to afford six-membered a,(3-unsaturated ketones. 

In a similar manner, a new strategy to access the fumagilol skeleton was reported. RCM of diene 29, which was synthesized by the Evans aldol reaction, was carried out using Ic in the presence of Ti(0 Pr)4 to give a key cyclohexanone intermediate 30 [Eq. (6.22)]. This compound was readily converted to fumagilol " ... 

Typical starting materials, catalysts, and products of the enamine-catalyzed aldol reaction are summarized in Scheme 17. In proline-catalyzed aldol reactions, enantioselectivities are good to excellent with selected cyclic ketones, such as cyclohexanone and 4-thianone, but generally lower with acetone. Hindered aldehyde acceptors, such as isobutyraldehyde and pivalaldehyde, afford high enantioselectivities even with acetone. In general, the reactions are anti selective, but there are aheady a number of examples of syn selective enamine aldol processes [200, 201] (Schemes 17 and 18, see below). However, syn selective aldol reactions are still rare, especially with cychc ketones. 

Application of this work to a domino process using 51 involves Michael addition of P-ketoesters [91], p-diketones or P-ketosulfones [92] to a,P-unsaturated ketones followed by an intramolecular aldol reaction provides highly functionalised cyclohexanone building blocks with up to four contiguous chiral centres. Gryko has also reported examples of this domino Michael/intramolecular aldol reaction in the coupling of 1,3-diketones and methyl vinyl ketone using L-proUne as catalyst [93],... 

Using diarylprolinol ether 55 in conjunction with an additional base, a domino Michael/aldol/intramolecular Sj 2 process has been developed that led to highly functionalised epoxy cyclohexanones 110, with excellent control of three of the chiral centres generated (Scheme 42) [169]. Despite the apparent complexity, these reactions proceed at room temperature in less than 24 h and the products contain significant potential for a host of further transformations. 

After the initially performed aldol condensations and the process optimisation, the scope of the reaction was further extended to an enantiomeric Mannich reaction. The authors started from A-PMP-protected ot-imino ethyl glyoxylate and cyclohexanone in the presence of 5% catalyst loading. In 10 min at 60°C, the conversions were complete and the p-aminoketone was obtained in 91% yield and >95% ee after purification on column. 

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