Chelation Chiral auxiliary

When chiral enolates or chiral Michael acceptors are used, for instance, when stereogenic centers are present in the substrate or when X or Y are chiral auxiliaries, both simple and induced diastereoselectivity is observed. This results, in principle, in the formation of four diastereomers 1 -4. The diastereoselectivity in the Michael addition of lithium enolates to enones can be rationalized by consideration of chelated transition states A-D372. 

The chiral auxiliary can be recovered without any racemization. A chelated transition state has been suggested in which the Grignard reagent is delivered to the 7t-face more distal from the sterically demanding toy-butyl group1 2. 

The addition reactions of alkyllithium-lithium bromide complexes to a-trimethylsilyl vinyl sulfones that have as a chiral auxiliary a y-mono-thioacetal moiety derived from ( + )-camphor are highly diastereoselective. A transition state that involves chelation of the organolithium reagent to the oxygen of the thioacetal moiety has been invoked. The adducts are readily converted via hydrolysis, to chiral a-substituted aldehydes22. 

These examples and those in Scheme 2.6 illustrate the key variables that determine the stereochemical outcome of aldol addition reactions using chiral auxiliaries. The first element that has to be taken into account is the configuration of the ring system that is used to establish steric differentiation. Then the nature of the TS, whether it is acyclic, cyclic, or chelated must be considered. Generally for boron enolates, reaction proceeds through a cyclic but nonchelated TS. With boron enolates, excess Lewis acid can favor an acyclic TS by coordination with the carbonyl electrophile. Titanium enolates appear to be somewhat variable but can be shifted to chelated TSs by use of excess reagent and by auxiliaries such as oxazolidine-2-thiones that enhance the tendency to chelation. Ultimately, all of the factors play a role in determining which TS is favored. 

The cyclic a-hydroxylactone, pantolactone, has been used extensively as a chiral auxiliary in D-A reactions.84 Reactions involving TiCl4 and SnCl4 occur through chelated TSs.85... 

Aldol addition and related reactions of enolates and enolate equivalents are the subject of the first part of Chapter 2. These reactions provide powerful methods for controlling the stereochemistry in reactions that form hydroxyl- and methyl-substituted structures, such as those found in many antibiotics. We will see how the choice of the nucleophile, the other reagents (such as Lewis acids), and adjustment of reaction conditions can be used to control stereochemistry. We discuss the role of open, cyclic, and chelated transition structures in determining stereochemistry, and will also see how chiral auxiliaries and chiral catalysts can control the enantiose-lectivity of these reactions. Intramolecular aldol reactions, including the Robinson annulation are discussed. Other reactions included in Chapter 2 include Mannich, carbon acylation, and olefination reactions. The reactivity of other carbon nucleophiles including phosphonium ylides, phosphonate carbanions, sulfone anions, sulfonium ylides, and sulfoxonium ylides are also considered. 

Mg11 complexes are also effective for controlling asymmetric radical reactions.33,34 Moreover, enantioselective radical reactions using chiral Mg11 complexes have been studied, and high enantioselectivities have been realized in the presence of stoichiometric or catalytic amounts of chiral auxiliaries such as bis-oxazolines (Scheme 8).35-39 In most cases, substrates having bidentate chelating moieties are required. 

Prolinol-Type Chiral Auxiliaries. In this section, applications of chelation-enforced chirality transfers with nitrogen derivatives are discussed... 

Evans and Takacs23 demonstrated a diastereoselective alkylation based on metal ion chelation of a lithium enolate derived from a prolinol-type chiral auxiliary. This method can provide effective syntheses of a-substituted carbox-... 

Access to the corresponding enantiopure hydroxy esters 133 and 134 of smaller fragments 2 with R =Me employed a highly stereoselective (ds>95%) Evans aldol reaction of allenic aldehydes 113 and rac-114 with boron enolate 124 followed by silylation to arrive at the y-trimethylsilyloxy allene substrates 125 and 126, respectively, for the crucial oxymercuration/methoxycarbonylation process (Scheme 19). Again, this operation provided the desired tetrahydrofurans 127 and 128 with excellent diastereoselectivity (dr=95 5). Chemoselective hydrolytic cleavage of the chiral auxiliary, chemoselective carboxylic acid reduction, and subsequent diastereoselective chelation-controlled enoate reduction (133 dr of crude product=80 20, 134 dr of crude product=84 16) eventually provided the pure stereoisomers 133 and 134 after preparative HPLC. 

A further step towards improved selectivity in aldol condensations is found in the work of David A. Evans. The work of Evans [3a] [14] is based in some early observations from Meyers laboratory [15] and the fact that boron enolates may be readily prepared under mild conditions from ketones and dialkylboron triflates [16]. Detailed investigations with Al-propionylpyrrolidine (31) indicate that the enolisation process (LDA, THE) affords the enolate 32 with at least 97% (Z>diastereoselection (Scheme 9.8). Finally, the observation that the inclusion of potential chelating centres enhance aldol diastereoselection led Evans to study the boron enolates 34 of A(-acyl-2-oxazolidones (33), which allow not only great diastereoselectivity (favouring the 5yn-isomer) in aldol condensations, but offer a possible solution to the problem of enantioselective total syntheses (with selectivities greater than 98%) of complex organic molecules (see below, 9.3.2), by using a recyclisable chiral auxiliary. 

Darzens reaction of (-)-8-phenylmethyl a-chloroacetate (and a-bromoacetate) with various ketones (Scheme 2) yields ctT-glycidic esters (28) with high geometric and diastereofacial selectivity which can be explained in terms of both open-chain or non-chelated antiperiplanar transition state models for the initial aldol-type reaction the ketone approaches the Si-f ce of the Z-enolate such that the phenyl ring of the chiral auxiliary and the enolate portion are face-to-face. Aza-Darzens condensation reaction of iV-benzylideneaniline has also been studied. Kinetically controlled base-promoted lithiation of 3,3-diphenylpropiomesitylene results in Z enolate ratios in the range 94 6 (lithium diisopropylamide) to 50 50 (BuLi), depending on the choice of solvent and temperature. ... 

Another approach for the chemoselective and asymmetric iodination of unactivated C H bonds was reported with a palladium catalyst using a chiral auxiliary (Scheme 5.19). Excellent diastereoselectivities were induced by chelating the auxiliary to the palladium catalyst center followed by an electrophilic C—H activation and iodination. Studies showed that I2 acts as both the reactant and the activator to form the reactive catalyst precursor, Pd3(OAc)3. After the reaction was completed, the formed Pdl2 was precipitated from the solution and could be reused several times without losing reactivity and selectivity. 

The problem in the above example is to perform an enantiocontrolled electrophilic substitution in the a-position of a carboxylic acid derivative 1. To this end, chiral auxiliary 2, readily available in both (R) and (5) form from phenylalanine, is attached to the acid chloride 1 by amide formation. The amide 3 is converted into the (T )-enolatc 4, with the chelate ring forming... 

Due to their configurational instability, asymmetric synthesis involving these reagents must usually be done with the aid of chiral auxiliaries that block one side of the nucleophilic carbon atom against electrophilic attack (passive volume) or fix the metal on one side by chelation (active volume)l9. 

One of the most important factors for successful diastereoselection in chiral amide enolate alkylation reactions is the presence of strongly chelated ionic intermediates1 3. The chelation serves the purpose of locking the chiral auxiliary in a fixed position relative to the enolate. The metal counterion is chelated between the enolate oxygen and an additional polar group, anionic, carbonyl or ether oxygen attached to the chiral auxiliary. 

Deprotonation of either the (4S.5R)- or (4/ ,5S)-enantiomer of 3-acyl-1,5-dimelhyl-4-phenyl-2-imidazolidinones 4 by lithium cyclohexylisopropylamide (LICA)1 or diisopropylamide2 furnishes chiral, supposedly chelated enolates, very similar to those enolates obtained from 2-oxazolidi-nones (see Section 1.1.1.3.3.4.2.1.). With LICA the. yyn-enolate is formed exclusively, as shown by O-silylation of the enolate with /ert-butylchlorodimethylsilane1. Attack of an electrophile, such as a haloalkane, from the less hindered side furnishes products (usually crystalline) with a moderate to high degree of diastereoselectivity (see Tabled)1 2. The diastereoselectivities observed in comparable alkylation reactions of the 3-acyl-4-cyclohexyl-l,5-dimethylimidazo-lidinone 3b are superior to those obtained with the 4-phenyl derivative 3a2,7. Thus, as also observed in similar alkylations with oxazolidinones10 (see Section 1.1.1.3.3.4.2.1), a phenyl substituent on the chiral auxiliary seems to be relatively inefficient as a steric control element. 

In summary, of the many chiral auxiliaries used in the asymmetric synthesis of carbonyl compounds via imines, those able to form a methoxymethyl-chclated azaenolate show the best enantioselectivities (see Tabic 7). The same is true for valine and im-leucine derivatives which form rigid chelates via their carboxyl groups. In particular, quaternary centers (see Table 6) and a-alkvl-/i-oxo esters arc effectively prepared using these chiral auxiliaries. 

In late 1975, Enders et al.156) started a research project directed towards the development of a new synthetic method for asymmetric carbon-carbon bond formation. A new chiral auxiliary, namely the (S)-proline derivative SAMP (137), was allowed to react with aldehydes and ketones to give the hydrazones (138), which can be alkylated in the a-position in an diastereoselective manner 157,158). Lithiation 159) of the SAMP hydrazones (138), which are formed in excellent yields, leads to chelate complexes of known configuration 160). Upon treatment of the chelate complexes with alkyl halogenides the new hydrazones (139) are formed. Cleavage of the product hydrazones (139) leads to 2-alkylated carbonyl compounds (140). 

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