Cyclization of carbanions

Stereospecific synthesis of arylidene and allylidene cyclopentanes and cyclohexanes can be achieved by palladium-catalyzed cyclization of carbanions containing a C — C triple bond in the presence of aryl or vinyl halides52 33". The reaction is stereoselective, occurring with irans selectivity. Thus, a palladacyclic intermediate, resulting from initial aryl or vinyl carbapallada-tion, is ruled out in favor of primary carbanion addition to the alkyne unit. 

In a similar procedure, palladium(O)- and copper(I)-mediated intramolecular cyclization of carbanions of the malonate type and alkynes, captured by an alkynyl halide, is achieved with up to 71 % yield54. Again the reaction is trans stereospedfic to give the -isomers exclusively. 

Enantio.selective cyclization of carbanions derived from iV.Ai-diisopropylcarbamates can lead to cis- or rrans-1,2-disubstituted cyclopentane derivatives by treatment with v-BuLi-(—)-sparteine. ... 

Tetrahydrooxepinols are formed in moderate yields on cyclization of carbanions formed from allyl glycidyl ethers the process competes with the formation of isomeric (vinyloxetanyl)carbinols <88CC625,90TL350l>. The mechanism has been rationalized as shown in Scheme 24. 

Cyclization of carbanions derived from bromo-esters of type (18) has been exploited by Kondo et al in a useful approach to chrysanthemic analogues (Scheme 9), and the related base-induced cyclizations of yS-unsaturated epoxides and of epoxysulphones o to appropriate cyclopropanes have also received attention. 

The reduction of o-nitrophenyl acetic acids or esters leads to cyclization to oxindoles. Several routes to o-nitrophenylacetic acid derivatives arc available, including nitroarylation of carbanions with o-nitroaryl halides[2l,22] or trif-late[23] and acylation of o-nitrotoluenes with diethyl oxalate followed by oxidation of the resulting 3-(u-nitrophenyl)pyruvate[24 26]. 

The main Uab synthetic pathway is illustrated in Scheme 6.1 and corresponds to C-acylation of an o-aminobenzyl carbanion equivalent. Acylation is normally followed by in situ cyclization and aromatization. This route is therefore closely related to the cyclizations of o-aminobenzyl ketones described in Section 2.3 but the procedures described here do not involve isolation of the intermediates. 

Asymmetric induction by sulfoxide is a very attractive feature. Enantiomerically pure cyclic a-sulfonimidoyl carbanions have been prepared (98S919) through base-catalyzed cyclization of the corresponding tosyloxyalkylsulfoximine 87 to 88 followed by deprotonation with BuLi. The alkylation with Mel or BuBr affords the diastereomerically pure sulfoximine 89, showing that the attack of the electrophile at the anionic C-atom occurs, preferentially, from the side of the sulfoximine O-atom independently from the substituent at Ca-carbon. The reaction of cuprates 90 with cyclic a,p-unsaturated ketones 91 was studied but very low asymmetric induction was observed in 92. 

Intramolecular cyclization of 2-phenysulfonylmethyl lactam 3 took place upon reaction with lithium hexamethyldisilazan via generating its a-sulfonyl carbanion to give a cyclized postulated intermediate that can be quenched with trimethylchlorosilane to afford the stable silyl ketal 4. The later ketal was desulfonylated by Raney-Ni and desilylated through treatment with tetrabutyl ammonium fluoride (BU4NF) to afford the carbacephem 5 (94M71) (Scheme 1). 

The cyclization of aryl 3-chloropropyl sulfones by potassium t-butoxide in t-butyl alcohol at 30 °C (equation 20) has a p value of 2.32 for substituents in Ar202. This is considered by Bird and Stirling to indicate the formation of an intermediate carbanion which is essentially in equilibrium with the reactants. A recent review by Stirling203 deals with structure-reactivity aspects of many sulfonyl promoted reactions of this type. 

The cyclopropane cyclizations by elimination of triflinic acid (CF3S02H) are readily effected by basic treatment of triflones (trifluoromethyl alkyl sulfones) with activated /-protons (equations 46 and 47)39. The cyclopropane diesters 45 are formed on treatment of 44 with potassium hydride in DMSO or sodium methoxide in methanol (equation 48). In contrast, the monoester 46 failed to give the desired cyclopropane40. Addition of carbanions derived from /f, y-unsaturated phenyl sulfones to a, /i-unsaturated carboxylic esters and subsequent elimination of benzenesulfinate ion give cyclopropanes possessing the unsaturated side chain and the ester function in trans positions (equation 49)41. 

Cory and Renneboog53 have devised an efficient bicycloannulation for the synthesis of tricyclo[3.2.1.02,7]octane-6-one (66) as shown in equation 63. The method involves three steps (1) the enolate undergoes an initial conjugate addition to phenyl vinyl sulfone, (2) the resulting sulfone-stabilized carbanion undergoes an intramolecular Michael addition to the enone, and (3) the resulting enolate displaces phenylsulfinyl moiety from the tricyclooctanone. The amount of HMPA (3 mol equivalents) is critical for effective cyclization of the enolate. 

Cyclopropyl sulfones were shown to be obtained either by cyclization of y-p-tosyloxy sulfones 232 with base or by treatment of phenylsulfonylacetonitrile 233a or ethyl phenyl sulfonyl acetate 233b with 1,2-dibromoethane in the presence of benzyltriethyl-ammonium chloride (BTEA) and alkali in good yields. Chang and Pinnick synthesized various cyclopropane derivatives 234 upon initial treatment of carbanions derived from cyclopropyl phenyl sulfone with either alkylating agents or a carbonyl compound and subsequent desulfonylation, as shown below. 

In a similar manner, starting from 2-methylchloride-naphtho[l,8-de][l,2,3]triazine and magnesium, via a novel sonication-promoted Barbier reaction, an a-aminomethyl carbanion equivalent is generated which reacts in situ with a variety of carbonyl compounds. Subsequent catalytic hydrogenolysis of the triazine moiety yields the corresponding amines <00TL4685>. Sterically controlled regiospecific cyclization of aldose-5-ethyl-l,2,4-... 

Like the electrohydrodimerization and electrohydrocyclizahon reactions, this process also requires the consumphon of two electrons and two protons. It has been shown to occur via a sequence consisting of electron transfer followed by a ratedetermining protonation of the resulting radical anion, addihon of a second electron to generate a carbanion, cyclization of the carbanion onto the carbonyl acceptor unit and the addition of the second proton [16]. Carbon acids like dimethyl malonate and malononitrile are often used as a proton source. The course of this and other... 

The opportunity for tandem cyclization was explored. Here, the results can be accommodated by postulating the intermediacy of a vinyl radical [66]. For example, the controlled potential reduction of enol phosphate 246 affords 247 as a mixture of stereoisomers, in addition to a 15% yield of the linearly fused tricyclopentanoid 248. Assuming that the initial reduction cleaves the phosphate unit, then there exists the opportunity for the resulting radical 249 to be further reduced to afford a carbanion, or undergo a 5-exo-trig radical cyclization onto the pendant alkene. Given the nature of the products and the fact that they are inconsistent with the expectations of carbanion chemistry, it seems clear that the latter pathway dominates. 

Cyclization of the product (27-2) under Friedel-Crafts conditions gives the desired indolinone (27-3). Reaction of the carbanion obtained on treatment of that with 3-chloropropyldimethylamine then gives the alkylation product (27-4). It should be noted that, in spite of this extra step, the scheme is greatly simplified by starting with the very readily available tertiary amine. The superfluous methyl group is then removed by reaction of (27-4) with ethyl chloroformate in the current version of the Von Braun reaction. There is thus obtained amedalin (27-5). Reduction of the amine by any of several methods, for example diborane, leads to the antidepressant daledalin (27-6) [28]. 

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