Enolate compounds asymmetric aldol reactions

The prime functional group for constructing C-C bonds may be the carbonyl group, functioning as either an electrophile (Eq. 1) or via its enolate derivative as a nucleophile (Eqs. 2 and 3). The objective of this chapter is to survey the issue of asymmetric inductions involving the reaction between enolates derived from carbonyl compounds and alkyl halide electrophiles. The addition of a nucleophile toward a carbonyl group, especially in the catalytic manner, is presented as well. Asymmetric aldol reactions and the related allylation reactions (Eq. 3) are the topics of Chapter 3. Reduction of carbonyl groups is discussed in Chapter 4. 

Compound 17 is the so-called (+)-Prelog-Djerassi lactonic acid derived via the degradation of either methymycin or narbomycin. This compound embodies important architectural features common to a series of macrolide antibiotics and has served as a focal point for the development of a variety of new stereoselective syntheses. Another preparation of compound 17 is shown in Scheme 3-7.11 Starting from 8, by treating the boron enolate with an aldehyde, 20 can be synthesized via an asymmetric aldol reaction with the expected stereochemistry at C-2 and C-2. Treating the lithium enolate of 8 with an electrophile affords 19 with the expected stereochemistry at C-5. Note that the stereochemistries in the aldol reaction and in a-alkylation are opposite each other. The combination of 19 and 20 gives the final product 17. 

Although in the recent years the stereochemical control of aldol condensations has reached a level of efficiency which allows enantioselective syntheses of very complex compounds containing many asymmetric centres, the situation is still far from what one would consider "ideal". In the first place, the requirement of a substituent at the a-position of the enolate in order to achieve good stereoselection is a limitation which, however, can be overcome by using temporary bulky groups (such as alkylthio ethers, for instance). On the other hand, the ( )-enolates, which are necessary for the preparation of 2,3-anti aldols, are not so easily prepared as the (Z)-enolates and furthermore, they do not show selectivities as good as in the case of the (Z)-enolates. Finally, although elements other than boron -such as zirconium [30] and titanium [31]- have been also used succesfully much work remains to be done in the area of catalysis. In this context, the work of Mukaiyama and Kobayashi [32a,b,c] on asymmetric aldol reactions of silyl enol ethers with aldehydes promoted by tributyltin fluoride and a chiral diamine coordinated to tin(II) triflate... 

Several methods for the anti-selective, asymmetric aldol reaction recorded in the literature include (i) the use of boron, titanium, or tin(ll) enolate carrying chiral ligands, (ii) Lewis acid-catalyzed aldol reactions of a metal enolate of chiral carbonyl compounds, and (iii) the use of the metal enolate derived from a chiral carbonyl compound. Although many of these methods provide anti-aldols with high enantioselectivities, these methods are not as convenient or widely applicable as the method reported here, because of problems associated with the availability of reagents, the generality of reactions, or the required reaction conditions. 

Dialkylboron trifluoromethanesulfonates (triflates) are particularly useful reagents for the preparation of boron enolates from carbonyl compounds, including ketones, thioesters and acyloxazolidinones.4 Recently, the combination of dicylohexylboron trifluoromethanesulfonate and triethylamine was found to effect the enolization of carboxylic esters.5 The boron-mediated asymmetric aldol reaction of carboxylic esters is particularly useful for the construction of anti (3-hydroxy-a-methyl carbonyl units.6 The present procedure is a slight modification of that reported by Brown, et al.2... 

The aldol reaction of an enolate or enolate equivalent with an imine is referred to as the Mannich-type reaction. Asymmetric Mannich-type reactions provide useful routes for the synthesis of enantiomerically enriched p-amino acid derivatives, which are versatile chiral building blocks for the synthesis of nitrogen-containing biologically important compounds [23]. Despite the enormous progress made in asymmetric aldol reactions [24], the corresponding asymmet-... 

The asymmetric aldol reaction is one of the most important topics in modern catalytic synthesis [54]. The products, namely />-hydroxy carbonyl compounds, have a broad range of applications and play a key role in the production of pharmaceuticals [55], Since the discovery of the catalytic asymmetric aldol reaction with enolsi-lanes by Mukaiyama et al. [56], steady improvements of the metal-catalyzed asymmetric aldol reaction have been made by many groups [57]. For this type of aldol reaction a series of chiral metal catalysts which act as Lewis acids activating the aldol acceptor have been shown to be quite efficient. It was recently shown by the Shibasaki group that the asymmetric metal-catalyzed aldol reaction can be also performed with unmodified ketones [57a], During the last few years, several new concepts have been developed which are based on use of organocatalysts [58], Enolates and unmodified ketones can be used as aldol donors. 

The approach for the enantioselective aldol reaction based on oxazolidinones like 22 and 23 is called Evans asymmetric aldol reaction.14 Conversion of an oxazolidinone amide into the corresponding lithium or boron enolates yields the Z-stereoisomers exclusively. Reaction of the Z-enolate 24 and the carbonyl compound 6 proceeds via the cyclic transition state 25, in which the oxazolidinone carbonyl oxygen and both ring oxygens have an anti conformation because of dipole interactions. The back of the enolate is shielded by the benzyl group thus the aldehyde forms the six-membered transition state 25 by approaching from the front with the larger carbonyl substituent in pseudoequatorial position. The... 

Because these asymmetric aldol reactions are ideal methods for constructing (3-hydroxy carbonyl compounds in optically active form, the development of an asymmetric aldol reaction without the use of an organostannane would be advantageous. Yamagishi and coworkers have reported the Mukaiyama aldol reaction using trimethylsilyl enol ethers in the presence of the BINAP-AgPF6 complex to afford the adducts with moderate enantioselectivities (Table 9.9).18 They have also assigned... 

The complex (A,A)-(ebthi)TiCl(OMe) has been synthesized from the corresponding titanium dichloride. This compound catalyzes the asymmetric aldol reaction of enol trichloroacetate of cyclohexanone with aromatic aldehydes with the result that the optically active syn-aldol adduct is obtained with up to 91% ee.1664... 

The utility of thiazolidinethione chiral auxiliaries in asymmetric aldol reactions is amply demonstrated in a recent enantioselective synthesis of apoptolidinone. This synthesis features three thiazolidinethione propionate aldol reactions for controlling the configuration of 6 of 12 stereogenio centers <05JA13810>. For example, addition of aldehyde 146 to the enolate solution of A -propionyl thiazolidinethione 145 produces aldol product 147 with excellent selectivity (>98 2) for the Evans syn isomer. Compound 145 also undergoes diastereoselective aldol addition with bisaryl aldehyde 148 to give the Evans syn product 149, which is converted to eupomatilone-6 in 6 steps <05JOC9658>. 

There are also stereochemical considerations here and Holmes used the Evans asymmetric aldol reaction (chapter 27) to make the starting material 174 R=Bn. The formation of any allyl vinyl ether reagent involves no change in the stereochemistry of the allyl alcohol - this is acetal exchange at the vinyl ether or acetal centre. The enol ether was added in masked form as a selenium compound 175 (chapter 32) as selenoxides eliminate at room temperature. The stereochemistry is developed directly from that in 177 as it transforms during the [3,3] shift. 

Catalytic asymmetric aldol reactions have emerged as one of the most powerful carbon-carbon bond-forming processes affording synthetically useful, optically active /3-hydroxy carbonyl compounds [36]. Among them, chiral Lewis acid-catalyzed reactions of aldehydes with silyl enol ethers are one of the most promising methods. Although several successful examples have been developed since 1990 [37], most of the reactions have to be conducted at low reaction temperatures (e.g., — 78°C) in aprotic anhydrous solvents such as dry dichloromethane, toluene, and propionitrile. 

SoUadid has introduced a-sulfinyl acetates as reagents for asymmetric aldol reactions.Compound (211) is prepared in good optical purity from the menthyl ester of p-tolylsulfinic acid. The magnesium enolate of (211), prepared by reaction of the sulfrnyl ester with r-butylmagnesium bromide, reacts with aldehydes and ketones to give diastereomeric mixtures of a-sulfinyl-3-hydroxy esters (Scheme 13). No... 

The synthesis of the fragment C3-C13 was achieved in five steps from 169. Treatment of the tosylated stereotetrad 169 with 5 equivalents of lithium acetylide in DMSO led an acetylenic compound which was treated with ra-Buli and methyl iodide, and then reduced by Na/NH3 to produce the E-geometry of the C12-C13 double bond with concomitant removal of the PMB group at C5, giving the primary alcohol 170 (49% yield for the three-step sequence). Swern oxidation of 170 gave the corresponding aldehyde which was involved in an Evans-type asymmetric aldol reaction with the boron enolate A to produce the adduct 171 (dr > 95/5, 90% yield). (Scheme 33). 

In analogy t 0 the Cu(II) complex systems, the silver(I) -catalyzed aldol reaction is also proposed to proceed smoothly through a Lewis acidic activation of carbonyl compounds. Since Ito and co-workers reported the first example of the asymmetric aldol reaction of tosylmethyl isocyanide and aldehydes in the presence of a chiral silver(I)-phosphine complex (99,100), the catalyst systems of sil-ver(I) and chiral phosphines have been applied successfully in the aldol reaction of tin enolates and aldehydes (101), Mukaiyama aldol reaction (102), and aldol reaction of alkenyl trichloroacetates and aldehydes (103). In the Ag(I)-disphosphine complex catalyzed aldol reaction, Momiyama and Yamamoto have also examined an aldol-type reaction of tin enolates and nitrosobenzene with different silver-phosphine complexes (Scheme 15). The catalytic activity and enantioselectivity of AgOTfi(f )-BINAP (2 1) complex that a metal center coordinated to one phosphine and triflate were relay on solvent effect dramatically (Scheme) (104). One catalyst system solves two problems for the synthesis of different O- and AT-nitroso aldol adducts under controlled conditions. 

Catalytic enantioselective protonation of prochiral ketone enolates is a beneficial route to optically active carbonyl compounds possessing a tertiary asymmetric carbon at the a-position. In the asymmetric protonation of trimethylsilyl enolates with methanol, BINAP-AgF has been found to act as a chiral catalyst [90,91], which is also known to catalyze asymmetric allylation of aldehydes with allylic trimethoxysilanes [42] as well as asymmetric aldol reaction with trimethoxysilyl enolates [54]. This protonation can be most effectively performed using 6 mol% ofBINAP and 10 mol% of... 

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