Butyllithium, reaction with imines

Additions of aryl- or alkyllithium reagents to N-silylated formamides 508 give the imines 509 in 55-80% yield [90, 91] some of these imines can subsequently be converted into the corresponding //-lactams by reaction with enolates of alkyl butyrates [92]. Conversion of N-silylated butyrolactam 388 into cyclic Schiff bases such as 390, by reaction with methyl- or butyllithium, via O-silylated butyrolactam 389, is discussed in Section 4.8 (Scheme 5.28). 

A synthesis of 2,3-diarylpyrroles was based on the use of a difunctional phosphine imine which is capable of both Wittig and aza-Wittig condensation. <94J0C4551> The reagent is prepared from benzotriazole, formaldehyde, sodium azide and triphenylphosphine which gives the precursor 13. Reaction with methylidene-triphenylphosphorane and butyllithium generated 14 which reacted with benzil derivatives to give the pyrroles. 

Rearrangement to an open chain imine (165) provides an intermediate whose acidity toward lithiomethylthiazole (162) is rather pronounced. Proton abstraction by 162 gives the dilithio intermediate (166) and regenerates 2-methylthiazole for further reaction. During the final hydrolysis, 166 affords the dimer (167) that could be isolated by molecular distillation (433). A proof in favor of this mechanism is that when a large excess of butyllithium is added to (161) at -78°C and the solution is allowed to warm to room temperature, the deuterolysis affords only dideuterated thiazole (170), with no evidence of any dimeric product. Under these conditions almost complete dianion formation results (169), and the concentration of nonmetalated thiazole is nil. (Scheme 79). This dimerization bears some similitude with the formation of 2-methylthia-zolium anhydrobase dealt with in Chapter DC. Meyers could confirm the independence of the formation of the benzyl-type (172) and the aryl-type... 

Imidazolidine-2-thiones functionalised on the four-position can be obtained by reaction of HN(CH3)R with n-butyllithium, followed by addition of carbon disulfide. The lithium thicarbamate can then by further lithiated and cyclisation occurs upon reaction of this species with an imine (S) [22],... 

The addition of terminal acetylenes to imines is an important reaction because of the importance of these products as building blocks. Conventionally, the addition reaction shown in Scheme 5.2 is performed with stoichiometric amounts of butyllithium in a step that is, separate from the subsequent nucleophilic addition reaction (see (b)). Carreira has recently developed a procedure that utilizes an iridium catalyst to effect the addition reaction to a wide range of aldimines and ketimines (see (a)). ... 

N-Unsubstituted azomethine ylides may be generated thermally (79), and the N-metalated, 2-azaallyl anion versions may be generated by action of nonmetalhc bases such as l,8-diazabicyclo[5.4.0]undec-7-ene (DBU) on certain imines (80). Although they are assumed to show similar chemical properties, these two species usually show different reaction patterns, as shown in Scheme 11.7, where the regio-and stereoselectivities of the cycloadditions are quite different (24,78-80). Metala-tion of (alkylideneamino)acetonitriles can be performed with metallic bases other than LDA. Thus, butyllithium, ethylmagnesium bromide, and magnesium bromide-diisopropylamide are also effective (78). The N-magnesioazomethine... 

The AH- 1,2-diazepine (99) reacted with butyllithium at -78 °C via addition to the 2,3-imine bond, but LDA gave the anion (100) which dimerized in the presence of oxygen. Reaction of (99) with Na/K at -20 °C in THF however led to the formation of (101) via ring contraction of (100) (72TL4891). Interestingly, however, when (100) was generated with LDA at 0 °C in TMEDA as solvent, no ring contraction was observed and the anion... 

Metalation of unsymmetrical mines. Pioneering studies on the metalation and subsequent alkylation of unsymmetrical imines indicated that the reaction occurs predominantly at the less substituted a-position.5 This pattern has since been observed generally with lithium diethylamide, LDA, and ethylmagnesium bromide. Recent studies6 indicate that the site of alkylation is independent of the alkylating group but is dependent on the substituent on the imine and particularly on the basicity of the base. Butyllithium ( -, sec-, and /-) can abstract a proton from the more substituted a-carbon of the acyclic imine 1 to some extent. In the case of the cyclic imine 2, alkylation at the more substituted position is actually the main reaction. However, only substitution at the less substituted position of the dimethylhydrazone of 2-methylcyclohexanone is observed with either LDA or jcc-butyllithium (7,126-128). 

A general methodology for the construction of quaternary carbon atoms at the carbonyl carbon of ketones has been successfully exploited for the facile synthesis of ( )-lycoramine (299) (Scheme 30) (165). Thus, the O-allylated o-vanillin 322 was allowed to react with vinyl magnesium bromide followed by Jones oxidation, and the acid-catalyzed addition of benzyl IV-methylcarbamate to the intermediate a,(3-unsaturated ketone furnished 323. Wadsworth-Emmons olefination of 323 with the anion derived from diethyl[(benzylideneami-no)methyl]phosphonate (BAMP) provided the 2-azadiene 324. The subsequent regioselective addition of n-butyllithium to 324 delivered a metalloenamine that suffered alkylation with 2-(2-bromoethyl)-2-methyl-l,3-dioxolane to give, after acid-catalyzed hydrolysis of the imine and ketal moieties, the 8-keto aldehyde 325. Base-catalyzed cycloaldolization and dehydration of 325 then provided the 4,4-disubstituted cyclohexenone 326. The entire sequence of reactions involved in the conversion of 323 to 326 proceeded in very good overall yield and in one pot. 

Preparative Methods both enantiomers of the a-methyl sultam may be prepared on a multigram scale in optically pure form by asymmetric hydrogenation of imine (2a) followed by simple crystallization (eq 1). The (7 )-enantiomer of the a-f-butyl sultam may also be prepared in enantiomerically pure form by asymmetric reduction of imine (2b) followed by fractional crystallization. However, multigram quantities of either enantiomer of the a-t-butyl sultam may be prepared by derivati-zation of the racemic auxiliary (obtained in 98% yield from reaction of (2b) with Sodium Borohydride in MeOH) with 10-Camphorsulfonyl Chloride, separation of the resulting diastere-omers by fractional crystallization, and acidolysis. Prochi-ral imines (2a) and (2b) are readily prepared from inexpensive Saccharine by treatment with Methyllithium (73%) and t-Butyllithium (66%), respectively. 

The reaction is somewhat selective for the cis-diastereomer. The use of chiral additives in this reaction leads to aziridines enantioselectively. " Imines can be formed by the reaction of an aldehyde and an amine, and subsequent treatment with Me3SiI and butyllithium gives an aziridine. " A-Tosyl imines react with diazoalkenes to form A-tosyl aziridines, with good cis-selectivity " and modest enantioselectivity in the presence of a chiral copper catalyst, " but excellent enantioselectivity with a chiral rhodium catalyst. . It is noted that A-tosyl aziridines are formed by the... 

The reaction of 3,5-dichloro-A,A-diisopropyl-1 /.4,2,4,6-thiatriazin-l -amine (2) with butyllithi-um gives only dibutyl ketone, probably formed from the ring-transformation product benzoni-trile via butyllithium addition to the ketone imine.45 Reaction of phenylmagnesium bromide with 2 gives 3-chloro-Al,Af-diisopropyl-5-phenyl-lA4,2,4,6-thiatriazin-l-amine (3) in 30% yield.45... 

In another variant of the Niementowski reaction, it was found that this transformation can be carried out under relatively mild, base-catalyzed conditions. Since a variety of substituted anthranilamides (29) can be prepared by a regiospecific ortho metalation-amination sequence, this method appears to be a very versatile modification of the Niementowski quinoline synthesis. Lithiation of 28 with 5-butyllithium was followed by treatment with tosyl azide. Reduction of the azide with sodium borohydride under phase transfer conditions furnished 29. After conversion of 29 into the corresponding imine 30, treatment of 30 with LDA afforded 31 in good yield. 

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