Ester enolate Ireland-Claisen rearrangement

Previously, Ireland-Claisen ester-enolate rearrangement of the corresponding a-propionyloxy-allylsilane led to model system 5.44 Therefore, elaboration to 4 via rearrangement of 15 was pursued. To complete our retrosynthetic analysis, a plausible route to 15 was devised, involving straightforward homologation of 2P,3a-disubstituted cyclohexanone 17 to cyclohexene-carboxaldehyde 16, which in turn undergoes silylanion addition and subsequent acylation (Eq. 8). 

The Claisen rearrangement, Cope rearrangement, and associated variants are powerful tools that can be used to create a number of new chiral centers in an expeditious manner, but the use of heavy metals, such as mercury, should be avoided. Of these reactions, the Ireland-Claisen ester enolate reaction provides the most versatile synthetic pathway with minimal scale up problems. 

The Johnson Ortho Ester Rearrangement 7.22.8 The Ireland Silyl Ester Enolate Rearrangement 722.9 Charge-accelerated Claisen Rearrangements 7.22.10 Cat ysis of Claisen Rearrangements 722.11 Competitive Rearrangements... 

This method was further improved when it was found that readily available allyl esters of the general formula 493 could also be involved in Claisen rearrangements via intermediate formation of ketene derivatives such as lithium enolates 494 or trimethylsilyl ketene acetals 495 (the Ireland-Claisen variant" ). Moreover, rearrangement of these substrates into unsaturated acids 496 occurred easily at room temperature or below. This was in striking contrast to all previous versions of the Claisen rearrangement, which required heating at elevated temperatures (140-160 °C). The Ireland (silyl ketene acetal) variant of... 

Since its introduction in 1972, the Ireland silyl ester enolate variant of the Claisen rearrangement has become increasingly popular in organic synthesis. Areas of successful applications include the polyether... 

In the total synthesis of the esterase inhibitor ( )-ebelactone A, Paterson and Hulme applied an aldol-Claisen strategy for a relay of 1,2-syn into 1,5-syn relative stereochemistry (Scheme 25). - i3,ii4 critical Ireland ester enolate rearrangement could be performed without protecting the C9 ketone to give ester (137) in 74% overall yield. ... 

A more efficient synthesis of ( )-74 was achieved by employing Ireland s ester enolate Claisen rearrangement, as shown in Figure 4.6.23 Ester A was converted to its lithio-enolate in THF/HMPA, which... 

Ester Enolate Rearrangements (Ireland-Claisen Rearrangement)... 

CHCI3, reflux (Ireland ester enolate Claisen rearrangement)... 

The synthesis in Scheme 13.44 is also based on a carbohydrate-derived starting material. It controlled the stereochemistry at C(2) by means of the stereoselectivity of the Ireland-Claisen rearrangement in Step A (see Section 6.4.2.3). The ester enolate was formed under conditions in which the T -enolate is expected to predominate. Heating the resulting silyl enol ether gave a 9 1 preference for the expected stereoisomer. The... 

Further variations of the Claisen rearrangement protocol were also utilized for the synthesis of allenic amino acid derivatives. Whereas the Ireland-Claisen rearrangement led to unsatisfactory results [133b], a number of variously substituted a-allenic a-amino acids were prepared by Kazmaier [135] by chelate-controlled Claisen rearrangement of ester enolates (Scheme 18.47). For example, deprotonation of the propargylic ester 147 with 2 equiv. of lithium diisopropylamide and transmetallation with zinc chloride furnished the chelate complex 148, which underwent a highly syn-stereoselective rearrangement to the amino acid derivative 149. 

Selective protection of the primary alcohol gave 138 (P=TBDMS), which was then esterified with ( )-3-hexenoic acid to produce the key intermediate 139 for cyclization. Ireland ester-enolate Claisen rearrangement and hydrolysis produced a protected hydroxyacid, which, after reduction of the acid and deprotection of the alcohol, yielded meso diol 128 more quickly and efficiently than in the previous synthesis. The meso diol was then converted to the racemate of the lactol pheromone 130 as previously described. 

Rearrangement of allyl trimethylsilyl ketene acetal, prepared by reaction of allylic ester enolates with trimethylsilyl chloride, to yield Y,5-unsaturated carboxylic a-cids. The Ireland-Claisen rearrangement seems to be advantageous to the other variants of the Claisen rearrangement in terms of E/Z geometry control and mild conditions. 

Ireland-Claisen rearrangement as an alternative approach to the syn isomer with a high degree of diastereoselectivity was also examined. This reaction might be similar to the system of ester-enolate [2,3]-Wittig shift in the case of OR (R=protective group). 

To avoid the formation of ketenes by alkoxide elimination, ester enolates are often prepared at low temperatures. If unreactive alkyl halides are used, the addition of BU4NI to the reaction mixture can be beneficial [134]. Examples of the radical-mediated a-alkylation of support-bound a-haloesters are given in Table 5.4. Further methods for C-alkylating esters on insoluble supports include the Ireland-Claisen rearrangement of O-allyl ketene acetals (Entry 6, Table 13.16). Malonic esters and similar strongly C,H-acidic compounds have been C-alkylated with Merrifield resin [237,238]. 

Silylene transfer to a -unsaturated esters produces oxasilacyclopentenes and provides a new method for regio- and stereo-selective formation of enolate that can undergo facile and selective Ireland-Claisen rearrangements and aldol addition reactions to provide products with multiple contiguous stereocenters and quaternary carbon centers (Scheme 37). 

As shown earlier (Figure 13.22), silyl ketene acetals can be prepared at -78 °C by the reaction of ester enolates with chlorosilanes. O-Allyl-O-silyl ketene acetals (A in Figure 14.48) are formed in this reaction if one employs allyl esters. Silyl ketene acetals of type A undergo [3,3]-rearrangements rapidly upon warming to room temperature. This variation of the Claisen rearrangement is referred to as the Ireland-Claisen rearrangement. 

Figure 14.51 shows four Ireland-Claisen rearrangements that exhibit simple diastereose-lectivity (see Section 11.1.3 for a definition of the term). The substrates are two cis, trans-iso-meric propionic acid esters. The propionic acid esters in Figure 14.51 are derived from achiral allyl alcohols. This is different from the situation in Figure 14.50. However, these esters contain a stereogenic C=C double bond. Both the esters in Figure 14.51 can be converted into their 7 "-enolates with LDA inpureTHF (cf. Figure 13.16). Silylation affords the two T -con-figured O-allyl-O-silyl ketene acetals A and D, respectively. Alternatively, the two esters of Figure 14.51 can be converted into their Z -enolates with LDA in a mixture of THF and DMPU (cf. Figure 13.17). Treatment with rert-BuMe,SiCl then leads to the Z-isomers B and C of the O-allyl-O-silyl ketene acetals A and D, respectively.

H.-J. Altenbach, Ester Enolate Claisen Rearrangements , in Organic Synthesis Highlights (J. Mulzer, H.-J. Altenbach, M. Braun, K. Krohn, H.-U. ReiBig, Eds.), VCH, Weinheim, New York, 1991, 116-118. S. Pereira, M. Srebnik, The Ireland-Claisen Rearrangement, AldrichimicaActa 1993, 26, 17-29. 

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