Aldol reaction 1,5-Induction

The enantiomers are obtained as a racemic mixture if no asymmetric induction becomes effective. The ratio of diastereomers depends on structural features of the reactants as well as the reaction conditions as outlined in the following. By using properly substituted preformed enolates, the diastereoselectivity of the aldol reaction can be controlled. Such enolates can show E-ot Z-configuration at the carbon-carbon double bond. With Z-enolates 9, the syn products are formed preferentially, while fi-enolates 12 lead mainly to anti products. This stereochemical outcome can be rationalized to arise from the more favored transition state 10 and 13 respectively ... 

Asymmetric Lewis-Acid Catalyzed. Another important advance in aqueous Mukaiyama aldol reaction is the recent success of asymmetric catalysis.283 In aqueous ethanol, Kobayashi and co-workers achieved asymmetric inductions by using Cu(OTf)2/chiral >A(oxazoline) ligand,284 Pb(OTf)2/chiral crown ether,285 and Ln(OTf)3/chiral Mv-pyridino-18-crown-6 (Eq. 8.105).286... 

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. 

Double asymmetric induction (See section 1.5.3) can also be employed in aldol reactions. When chiral aldehyde 15 is treated with achiral boron-mediated enolate 14, a mixture of diastereomers is obtained in a ratio of 1.75 1. However, when the same aldehyde 15 is allowed to react with enolates derived from Evans auxiliary 8, a syn-aldol product 16 is obtained with very high stereo-... 

As with the above pyrrolidine, proline-type chiral auxiliaries also show different behaviors toward zirconium or lithium enolate mediated aldol reactions. Evans found that lithium enolates derived from prolinol amides exhibit excellent diastereofacial selectivities in alkylation reactions (see Section 2.2.32), while the lithium enolates of proline amides are unsuccessful in aldol condensations. Effective chiral reagents were zirconium enolates, which can be obtained from the corresponding lithium enolates via metal exchange with Cp2ZrCl2. For example, excellent levels of asymmetric induction in the aldol process with synj anti selectivity of 96-98% and diastereofacial selectivity of 50-200 116a can be achieved in the Zr-enolate-mediated aldol reaction (see Scheme 3-10). 

Thus far, most of the stereoselective approaches to aldol reactions mentioned have depended on substrate-based asymmetric induction by employing chiral... 

Now, we examine the interaction of chiral aldehyde (-)-96 with chiral enolate (S )-lOOb. This aldol reaction gives 104 and 105 in a ratio of 104 105 > 100 1. Changing the chirality of the enolate reverses the result Compound 104 and 105 are synthesized in a ratio of 1 30 (Scheme 3-38).66 The two reactions (—)-96 + (S )-lOOb and (—)-96 + (7 )-100b are referred to as the matched and mismatched pairs, respectively. Even in the mismatched pair, stereoselectivity is still acceptable for synthetic purposes. Not only is the stereochemical course of the aldol reaction fully under control, but also the power of double asymmetric induction is clearly illustrated. 

The most interesting developments involve catalysis of simple aldol reactions. The key to reactive immunisation is the use of a hapten that is chemically reactive, rather than a passive template. This means that (i) relevant chemistry is going on during the course of antibody induction, which thus happens in the presence of intermediates involved in the reaction, and so may be modified to favor the formation of antibodies which bind these intermediates (and perhaps transition states leading to them). Furthermore (ii) it becomes possible to select for antibodies that react with, rather than just bind, to the hapten. The system used for the development of aldolase antibodies is outlined in Scheme 2... 

In the reverse reaction, the addition anion reforms the carbonyi group by expeiiing the enoiate anion as ieaving group. This reverse aldol reaction is sufficientiy important in its own right, and we shaii meet exampies. Note that, as we saw with simpie aidehyde and ketone addition reactions, aidehydes are better eiectrophiies than ketones (see Section 7.1.1). This arises from the extra alkyl group in ketones, which provides a further inductive effect and extra steric hindrance. Accordingly, the aldol reaction is more favourable with aldehydes than with ketones. With ketones, it is absolutely essential to disturb the equilibrium in some way. 

The next task was to form the C2-C3 aldol bond stereoselectively. However, asymmetric coupling of acetate derivatives to aldehydes is often accompanied by poor / -induction [89]. Moreover, the C3-C4 bond is particularly sensitive to retro-aldol reaction, especially under basic conditions. In the natural products, this was observed to be the main decomposition reaction. The first total syntheses of epothilones circumvented this problem by constructing this part of the molecule in an indirect manner, e.g., by using reduced forms at Cl or C5. We decided to employ our chromium-Reformatsky methodology, which avoids these problems and allows the direct use of reagents in the correct oxidation state. The non-basic reaction conditions, the intermediacy of a chromium(III) aldolate that is resistant to retro-aldol reaction, and the potential of a direct asymmetric carboxymethyl ( acetate ) transfer favor the use of this method [90]. 

The development of enantioselective aldol reactions has been widely studied in conjunction with the synthesis of natural products. Highly enantioselective aldol reactions have been achieved by employing chiral enolates of ethyl ketones and propionic acid derivatives.(1) On the other hand, achieving high asymmetric induction in the asymmetric aldol reaction of methyl ketones is still a problem.(2)... 

In the above asymmetric aldol reaction, the introduction and the removal of the chiral auxiliary are carried out by simple procedures, and high asymmetric induction is achieved even at ice—bath temperature. However, at least a stoichiometric amount of a chiral auxiliary is required in such a stereo-differentiating reaction (chiral auxiliary is attached to the reactant.). 

There is an important difference between Horeau s and Heathcock s examples in that the aldol reaction generates two chirality elements in the bond-forming step. In principle, analysis of such a reaction requires evaluation of two aspects, i.e., the effect of double asymmetric induction on simple and induced diastereoselectivity. The aldol reaction is not particularly suited for this... 

Asymmetric induction is another important aspect of the directed aldol reaction. The approach involves the use of a chiral aldehyde which influences the stereochemistry of the addition reaction. Reaction of a chiral phenylpropanaldehyde with a lithium enolate yields only two of the possible diastereoisomers in the ratio of 86 14 (equation 76).377... 

The aldol reaction of p-nitrobenzaldehyde with acetone is catalyzed by Zn2+ complexes of a-amino acid esters in MeOH, giving the optically active aldol adduct (Scheme 8B1.12) [28]. Although the enantiomeric excesses of the product have not been determined, the extent of asymmetric induction is dependent on the structure of a-substituents in the amino acids. The Zn2+ complexes of amino acid esters bearing an aromatic substituent such as esters of phenylalanine, tyrosine, and tryptophane (Trp) are more effective in terms of both catalytic activity and asymmetric induction. The highest asymmetric induction is observed with Trp-OEt ligand. 

Asymmetric induction in the aldol reaction of enolsilane and metal enolate nucleophiles with yS-substituted aldehydes gives rise to both excellent yields and good diastereoselectivities (equation 128)507. The best diastereoselectivity was obtained using a trimethylsilyl enolate in the presence of boron trifluoride-etherate (92 8 anti. syn). The key step in the synthesis of the N-terminal amino acid analogue of nikkomycin B and Bx (nucleoside peptide antibiotics) has been performed using this type of methodology508. 

The final aldol reaction used in our synthesis of spongistatin 1 was one of the more remarkable reactions of this type our group has witnessed over the years. The aldol union of ketone 64 with ( )-4-chloro-2,4-pentadienal 65 required the creation of the (475) stereochemistry in the resultant alcohol 66. Formally, this would require 1,5-syn induction from the ketone 64, which is opposite to that observed previously for boron aldol reactions with simple [i-alkoxy methyl ketones. However, ketone 64 is densely packed with stereocentres, and predicting the influence of these remote centres on the reaction outcome was not possible with any degree of certainty. It was hoped that should 64 display undesirable 1,5-anti bias, this may be overturned by appropriate choice of Ipc ligands on boron. 

Acyliron complexes with central chirality at the metal are obtained by substitution of a carbon monoxide with a phosphine ligand. Kinetic resolution of the racemic acyliron complex can be achieved by aldol reaction with (1 R)-( I (-camphor (Scheme 1.14) [41], Along with the enantiopure (R, c)-acyliron complex, the (Spe)-acyliron-camphor adduct is formed, which on treatment with base (NaH or NaOMe) is converted to the initial (SFe)-acyliron complex. Enantiopure acyliron complexes represent excellent chiral auxiliaries, which by reaction of the acyliron enolates with electrophiles provide high asymmetric inductions due to the proximity of the chiral metal center. Finally, demetallation releases the enantiopure organic products. 

Chiral sulfoximines liganded to copper(II) give highly enantioselective vinylogous Mukaiyama-type aldol reactions under mild conditions.137 A chiral sulfinyl group has been used to achieve 1,5- and 1,6-asymmetric induction in Mukaiyama aldols, using Yb(OTf)3 catalysis.138... 

Recently, a conceptually different synthesis of MeBmt using an asymmetric glycine aldol reaction was reported by Evans and Weber [29]. The key step consists in the stereochemically controlled condensation of the chiral glycine enolate synthon (23) with the (R)-aldehyde (24) mediated by stannous triflate (tin salt of trifluoromethanesulphonic acid). The desired syn-aldol adduct (25) was isolated in form of the heterocyclic compound (26). The sense of asymmetric induction in the aldol reaction was established by conversion of (26) over three steps into uniform MeBmt (3). 

Disubstituted cyclopentane-1,3-diones and cyclohexane-1,3-diones were used as substrates. After formation of the aldol adducts subsequent intramolecular dehydration furnished products of types 94 and 96. The asymmetric intramolecular aldol reaction proceeds with a broad variety of natural amino acids as organocata-lysts. Among these L-proline was usually found to be the most versatile. For example, conversion of the 2,2-disubstituted cyclopentane-1,3-dione 93 in the presence of L-proline gave the desired product 94 in 86.6% yield and with enantioselectivity of 84% ee [97]. This example and a related reaction with a 2,2-disubstituted cyclohexane-1,3-dione 95 are shown in Scheme 6.42. Chiral induction depends... 

Asymmetric aldol reactions.4 The borane complex 3 can also serve as the Lewis acid catalyst for the aldol reaction of enol silyl ethers with aldehydes (Mukaiyama reactions).5 Asymmetric induction is modest (80-85% ee) in reactions of enol ethers of methyl ketones, but can be as high as 96% ee in reactions of enol ethers of ethyl ketones. Moreover, the reaction is syn-selective, regardless of the geometry of the enol. However, the asymmetric induction is solvent-dependent, being higher in nitroethane than in dichloromethane. 

In 1992 Ghosh and co-workers provided the first example of the utility of rigid cis-1 -amino-2-indanol-derived oxazolidinone 36 as the chiral auxiliary in the asymmetric. vv//-aldol reaction.60-61 Aldol condensation of the boron enolate of 37 with various aldehydes proceeded with complete diastereofacial selectivity. Effective removal and recovery of the chiral auxiliary was carried out under mild hydrolysis conditions (Scheme 24.6). As both enantiomers of the chiral auxiliary were readily available, both enantiomers of the. yyn-aldol could be prepared with equal asymmetric induction. 

The use of Lewis acid drastically changes the regioselectivity. The highly enantioselective and O-selective nitroso aldol reactions of tin enolates with nitrosobenzene have been developed with the use of (i )-BINAP-silver complexes as catalysts. AgOTf and AgCICL complexes are optimal in the O-selective nitroso aldol reaction in both asymmetric induction (up to 97% ee) and regioselection (0/N= > 99/1), affording amino-oxy ketone. The product can be transformed to a-hydroxy ketone without any loss of enantioselectivity (Equation (71)).224... 

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