Enol imines

Ojima, 1., Habus, 1., Zhao, M. (1991) Efficient and Practical Asymmetric Synthesis ofthe Taxol C-13 Side Chain, N-Benzoyl-(2R,3S)-3-phenylisoserine, and its Analogues via Chiral 3-Hydroxy-4-aryl-b-lactams Through Chiral Ester Enolate-Imine Cyclocondensation. Journal of Organic Chemistry, 56, 1681-1683. 

Several reviews of P-lactam chemistry have appeared including a general survey with 407 references <99MI335>. Other reviews include discussions of thioester enolate-imine reactions , enantio- and diastereo-selective routes to azetidinones <99MI221>, the use of diazoketones in diastereoselective synthesis <99MI43>, and solid-phase and combinatorial syntheses of p-lactams <99MI955>. 

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. 

Organic dye nanoparticles of DHIA and DHBIA (the chemical structures are shown in Fig. 1) have been synthesized in THF/water mixed solvent by a reprecipitation method [32]. These dye molecules possess a 2-(2-hydroxyphenyl) benzothiazole (HBT) unit, which is known to be more stable as an enol imine form in the ground state and as a keto amine form in the excited state [32, 33] (Fig. 6). The nanoparticles exhibited the AIEE phenomenon mainly due to a restricted intramolecular motion, that is, impediment to free rotation of two end-substituted HBT units around single bonds. It is interesting to note that the... 

Just as enamines are more nucleophilic than enols, imine anions are more nucleophilic than enolates and react efficiently with alkyl halides. One application of imine... 

Enantiomerically pure trans-2-phenylcyclohexanol, first used by Whitesell as a chiral auxiliary has become a popular reagent in a number of asymmetric transformations. Some recent applications include asymmetric azo-ene reactions, [4 + 2]-cycloaddition reactions, ketene-olefin [2 + 2]-reactions, enolate-imine cyclocondensations, Pauson-Khand reactions," palladium annulations and Reformatsky reactions. Despite its potential, use of this chiral auxiliary on a preparative scale is currently limited by its prohibitive cost. 

The chiral enolate-imine addition methodology was examined in detail (Thiruvengadam et al., 1999). Enolate formation proceeds to completion within an hour at temperatures from — 30 to 0°C with either 1 equiv. TiCl4 or TiClaO-iPr (preformed or prepared in the presence of substrate by addition of TiCl4 and followed by a third of an equivalent Ti(0-iPr)4 and two equivalents of a tertiary amine base). Unlike the aldol process with the same titanium enolate, the nature of the tertiary amine base had no effect on the diaster-eoselectivity. The diastereoselectivity is maximized by careful control of the internal temperature to below — 20°C during the imine addition (2 equiv.) as well as during the acetic acid quench. The purity of the crude 2-amino carboxamide derivatives (17a or... 

Wu and co-workers (Wu et al., 1999) have demonstrated a novel chiral lactone enolate-imine process to access 2-azetidinone diols such as 35 (Scheme 13.10). Treatment of 34 with LDA at — 25°C in THF followed by addition of imine 3, afforded only trace product. Addition of HMPA or the less toxic DMPU during the lithium enolate formation step improved the yield and the trans cis diastereoselectivity ( 90 10). Recrystallization improved the purity to >95 5 trans cis 2-azetidinone. Addition of an equivalent of lithium bromide accelerates the rate of ring closure, presumably by destabilizing the intermediate lithium aggregates. Side-chain manipulation of 35 was accomplished by sodium... 

Theoretical studies of the ester enolate-imine reaction <98MI1826>, the effects of solvation on barriers of reaction <99JPC8628>, interactions of P-lactams in aqueous solution <99MI1401> and their ammonolysis and aminolysis <99JOC3281,99MI1045> are available. 

Lithium ester enolate-imine condensation has been used for the preparation of / -lactam rings via addition at the imine moiety <1996H(43)1057>. But treatment of imino derivatives of the pyridazine 293 with the lithium enolate of ethyl a,a-dimethylacetate 294 in THE led to the formation of the pyrido[3,4-r/ pyridazine 295 and its oxidized form 296. Compound 295 was obtained by nucleophilic attack of the carbanion species at C-5 of the pyridazine ring followed by cyclization (Equation 24) <1996JHC1731>. 

UV, 1H, and 13C NMR investigations revealed that 5,7,8,9-tetrahydro and 1,2,3,4,5,7,8,9-octahydro tautomeric forms are predominant for 6-ethoxalyl derivatives 23 and 24, while the lower homologs, the pyrrolidino[2,l-Z>]-quinazolin-10-ones, exist in the enol-imine forms [89JCS(P2)1613]. 

C NMR data indicated the presence of a mobile formyl-enamine and enol-imine tautomeric mixture with the predominance of the former at 6-formyl-l,2,3,4,5,7,8,9-octahydro-ll//-pyrido[2,l-b]quinazolin-ll-ones (87JHC1045). 

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. 

Scheme 49 Solid-phase synthesis of P-lactams via ester enolate-imine condensation...

The synthesis of monocyclic p-lactams via the ester-enolate imine condensation route has been reported to be carried out utilizing triazene esters (Scheme 54), [141], Esters were attached to benzylamine resin by a triazene linker employing the respective diazonium salts. Immobilized ester-enolates were reacted with various imines to give polymer-bound p-lactams in different substitution patterns. Traceless cleavage from the triazene linker yielded the desired p-lactams. 

The ester enolate-imine condensation, also called Gilman-Speeter reaction, is another well-accepted method for (3-lactam synthesis (Scheme 4) [67-69]. In 1997, Tomioka reported the first example of a direct catalytic enantioselective synthesis of (3-lactam by using this method [70]. The active reagent is a ternary complex (comprising LDA, the ester enolate, and tridentate amino diether), which finally affords the (3-lactam compounds in high yields and good ee values. 

Schunk and Enders [134] disclosed the first solid-phase synthesis of (5-1 actants via ester enolate-imine condensation employing an immobilized ester enolate in a simple three-step procedure (Scheme 31). The protocol showed high purity, excellent diastereoselectivity, and good yields of the product. The substrates were attached to the polymer with a Tl-triazene linker, which was cleaved traceless. The... 

The possibility of the triazene linking system for the ester-enolate imine condensation was initially investigated on model compounds 110 and 111 (Scheme 35). Dibenzyltriazene 110 was used as a model compound for monobactam derivatives and prepared by diazotization of hippuric acid methyl ester. Dibenzyltriazene 111 was used as a model compound for 3-phenyl-substituted azetidin-2-ones and prepared by diazotization of 2-(4-aminophenyl)-propionic acid methyl ester and conversion with dibenzylamine in 64% overall yield. The low yields of /V-unsub-stituted lactams, during the model studies, hint at a problematic transfer to solid support. 

When dihydro-1,3-benzothiazine 203 was allowed to react with KF in DMF (or NaOMe in MeOH), an open ring tautomeric isomer 204 was formed. When 2-bromoacetophenone 169 (R = H) is present in the reaction medium, a mixture of two diastereoisomers of 206 was obtained (75%) after enolate/imine addition of intermediate 205 with a slight excess of the m-isomer 206a over the trans-isomer 206b (Scheme 35). The same result was obtained by a synthesis from [6+1] fragments, reported in the next section <1995TL753>. 

R2 = COOEt) exists as about a 9 1 mixture of formyl-enamine and enol-imine tautomers. 

Protonation of 9-formyltetrahydropyrido[l,2-a]pyrimidinones takes place at the formyl oxygen, and the protonated enol-imine tautomers on the N(l) atom became the predominant tautomer forms [86JCS)P2)1911]. Similar phenomena were observed for the 9-formyltetrahydro-2// pyrido[l,2-a]pyrimidin-2-ones and their homologs [85JCS)P2)1873 88MI7]. 

The role of the metal ion may be purely conformational, acting to place the reactants in the correct spatial arrangement for cyclisation to occur, or it may play a more active role in stabilising the enol, enolate, imine or enamine intermediates. The prototypical example of such a reaction is shown in Fig. 6-18. The nickel(n) complex of a tetradentate macrocyclic ligand is the unexpected product of the reaction of [Ni(en)3]2+ with acetone. There are numerous possible mechanisms for the formation of the tetradentate macro-cyclic ligand and the exact mechanism is not known with any certainty. 

After examining the feasibility of an asymmetric [2 + 2] ketene-imine cycloaddition route and an asymmetric ester enolate-imine cyclocondensation route, we chose the latter route for the efficient asymmetric synthesis of (3/ ,4Sj-3-hydroxy-4-phenylazetidin-2-one and (2R,35)-/V-benzoyl-3-phenylisoserine. The cyclocondensation of the lithium enolate of (-)-(1 / ,2S)-2-phenyl-1 -cyclohexyltriiso-propylsiloxyacetate (5a P = (i-Pr)3Si (TIPS) and R = (-)-(lR,2S)-2-phenyl-1 -cyclohexyl) with A-trimethylsilylbenzaldimine (6a R1 = Ph) in THF at -78 °C gives (3/ ,4S)-3-triisopropylsiloxy-4-phenylazetidin-2-one (7a P = TIPS and R1 = Ph)... 

Polymer-bound P-lactams have been prepared via the ester enolate imine condensation route <02JOC8034>. On the other hand, an efficient asymmetric synthesis of 2-azetidinones was accomplished when chiral acid chlorides or chiral aldehydes were used in the polymer-supported Staudinger reaction <02TA905>. 

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