Imines, reaction with ester enolates

Alcohol derivatives 1.155 (Y = CHOHR) are useful as auxiliaries in a-keto-ester reductions [540] or [4+2] cycloadditions of aciylates [548]. 6-Lactams are obtained from imines 1.155 (Y = CH=NAr) with a high enantiomeric excess after reaction with ester enolates and decomplexation [549]. Alkylations of benzylimine 1.155 (Y = Ph2N=CH) give interesting results [539], and some 1,3-dipdar cycloaddition reactions with nitrones have been described [550],... 

Since /1-lactams can be prepared via reactions of ester enolates with imines, these reactions are of great interest for synthetic and medicinal chemists. The synthesis of naturally occurring antibiotics and other physiologically active //-lactams is an objective of much current work. Though the stereocenters in those reactions are often established by addition of enolates to imines, they are discussed in Section D.1.6.1.3. In this section, only some basic results concerning //-lactams are presented. 

The scope was then extrapolated to the two-step three-component aza-Baylis-Hillman setup to obtain (3-amino-a-methylene structures. A two-step approach was chosen to avoid the competition between the aldehyde and the imine for the reaction with the enolate, that would lead to mixtures of Baylis-Hillman and aza-Baylis-Hillman adducts, that is (3-hydroxy and (3-amino esters [87]. 

The reactions of imines with ester enolates provide a route to (3-lactams. Because of the importance of this class of antibiotics, much study has been devoted to this type of reaction [116a, 316a]. Recently published theoretical treatments [1283, 1284] suggest a mechanistic pathway different from that of the aldol reaction... 

The reaction of ester enolates with imines is a general method for the preparation of /5-lactams. This reaction is clearly not a concerted cycloaddition. The enolate adds to the imine generating an arnido ester intermediate. This intermediate, which is usually not isolated, cyclizes to give the /3-lactam. Since this subject has been recently reviewed81, only the stereochemical aspects of this reaction will be discussed here. In this reaction there are four possible sites for the chiral auxiliary. As in ketene imine cycloadditions, stereogenic centers can be introduced into the substituent on the imine carbon (R1), the substituent on the imine nitrogen (R2) or the substituent on the acyl portion of the ester (R3). There is a fourth possibility in these cycloadditions since the stereogenic center can also be introduced into the alkyl portion of the ester (R4), In some cases /r K-/ -lactams are obtained exclusively, while in other cases, mixtures of cis- and trans-isomers are isolated. 

As an alternative procedure to the reaction of N-trimethylsilyl-imines with ester enolates Colvin et al. have now reported that silyl ketene acetals can be employed in a one-pot synthesis of -... 

A stochiometric approach was applied by Van Koten and co-workers [29], who used chiral carbosilane dendrimers as soluble supports in the in situ ester enolate-imine condensation in the synthesis of /Mactams (e.g. 19, Scheme 20). The formation of the /Mactam products proceeded with high trans selectivity, and with the same level of stereoinduction as was earlier established in reactions without the dendritic supports, (i.e. the use of the enantiopure dendritic support did not affect the enantioselectivity of the C-C bond formation). After the reaction, the dendrimer species could be separated from the product by precipitation or GPC techniques and reused again. 

An alternative route starting from serine 73 or threonine 68 74 makes use of diethoxy-triphenylphosphorane. Attempts to asymmetrically synthesize (25)-aziridine-2-carboxylic acid (1) by treating a, 3-dibromopropanoates with chiral amines 75 or by the Staudinger reaction from oxirane-2-carboxylic acid ester 70,76 leads to optically impure products, whereas 3-alkyl derivatives of tert-butyl aziridine-2-carboxylates can be prepared with high cis-selectivity from a-halo ester enolates and jV-trimethylsilyl imines. 77 Moreover, when optically... 

Asymmetric Mannich reactions provide useful routes for the synthesis of optically active p-amino ketones or esters, which are versatile chiral building blocks for the preparation of many nitrogen-containing biologically important compounds [1-6]. While several diastereoselective Mannich reactions with chiral auxiliaries have been reported, very little is known about enantioselective versions. In 1991, Corey et al. reported the first example of the enantioselective synthesis of p-amino acid esters using chiral boron enolates [7]. Yamamoto et al. disclosed enantioselective reactions of imines with ketene silyl acetals using a Bronsted acid-assisted chiral Lewis acid [8]. In all cases, however, stoichiometric amounts of chiral sources were needed. Asymmetric Mannich reactions using small amounts of chiral sources were not reported before 1997. This chapter presents an overview of catalytic asymmetric Mannich reactions. 

Stoichiometric and catalytic asymmetric reactions of lithium enolate esters with imines have been developed using an external chiral ether ligand that links the components to form a ternary complex.36 The method affords /i-lactams in high enantiomeric excess. 

Asymmetric formation of /i-lactams (38) in high ee has been achieved by reaction of achiral imines (36) with a ternary complex of achiral lithium ester enolate (35), achiral lithium amide, and a chiral ether ligand (37) (in either stoichiometric or catalytic amount) 45 the size and nature of the lithium amide have a considerable effect on the enantioselectivity of the ternary complex. 

Fujisawa et al. [89] have reported the stereodivergent synthesis of spiro-[S-1 act a ms 64, 65 (Scheme 17) by reaction of lithium or titanium ester enolates 62 with single chiral imines 63 by taking advantage of different coordination states of the enolate metals. Almost complete reversal of the diastereofacial-discrimination with respect to the C-4 of the (3-lactam skeleton has been attained in this reaction coupled with flexibility in the selection of the enolates and ready removal of the chiral auxiliary. 

Chlorophenyl)glutarate monoethyl ester 87 was reduced to hydroxy acid and subsequently cyclized to afford lactone 88. This was further submitted to reduction with diisobutylaluminium hydride to provide lactol followed by Homer-Emmons reaction, which resulted in the formation of hydroxy ester product 89 in good yield. The alcohol was protected as silyl ether and the double bond in 89 was reduced with magnesium powder in methanol to provide methyl ester 90. The hydrolysis to the acid and condensation of the acid chloride with Evans s chiral auxiliary provided product 91, which was further converted to titanium enolate on reaction with TiCI. This was submitted to enolate-imine condensation in the presence of amine to afford 92. The silylation of the 92 with N, O-bis(trimethylsilyl) acetamide followed by treatment with tetrabutylammonium fluoride resulted in cyclization to form the azetidin-2-one ring and subsequently hydrolysis provided 93. This product was converted to bromide analog, which on treatment with LDA underwent intramolecular cyclization to afford the cholesterol absorption inhibitor spiro-(3-lactam (+)-SCH 54016 94. 

The condensation reaction of immobilized ester enolates with imines has been reported to give (3-lactam resins in good yields and high diastereomeric excess (Scheme 49), [133]. Traceless cleavage from the linker system yielded the desired (3-lactams. 

An asymmetric synthesis of a,(3-disubstituted (3-amino esters and (3-lactams has been reported [181]. Chiral (3-amino esters were prepared by a stereocon-trolled Mannich reaction with enolizable imines using an enolate derived from... 

In Yb(OTf)3-catalyzed Mannich-type reaction of the imine with silicon enolate conducted in SCCO2, the desired product is obtained in only 10 % yield after 3 h due to the low solubility of reactants in scC02 (Scheme 3.11, R1, R2, R3, R4, Rs=Ph, Bn, Me, Me, OMe) [57]. Addition of PEG is found to improve the yield to 72 %. The formation of emulsions can be observed in the presence of PEG. The highest yield (72 %) can be reached at 15 MPa CO2 pressure using PEG400 (MW = 400). This system has been applicable to various substrates including imines derived from aromatic and heterocyclic as well as aliphatic aldehydes and silicon enolates derived from esters, thioesters, and a ketone as depicted in Scheme 3.11. 

The one-pot condensation of an ester enolate with an imine is a very powerful synthetic procedure toward azetidin-2-ones (Equation 183). Various types of esters and imines can be utilized. Although in the vast majority the reactions have been mediated by lithium, various other metals mediate the reaction as well. Some examples include zinc, aluminium, tin, boron, indium, and titanium <1996MI119>. Theoretical studies on these reactions have been reviewed <1998JCC1826>. 

Aldehydes, ketones, carboxylic esters, carboxylic amides, imines and iV,jV-disubstituted hydrazones react as electrophiles at their sp2-hybridized carbon atoms. These compounds also become nucleophiles, if they contain an H atom in the a position relative to their C=0 or C=N bonds. This is because they are C,H-acidic at that position, that is, the H atom in the a position can be removed with a base (Figure 10.1). The deprotonation forms the conjugate bases of these substrates, which are called enolates. Depending on the origins of these enolates, they may be called aldehyde enolates, ketone enolates, ester enolates, or amide enolates. The conjugate bases of imines and hydra-zones are called aza-enolates. The reactions discussed in this chapter all proceed via enolates. 

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