Hydrazones lithiated

The synthesis of pyrazolines and pyrazoles of the [CCNN + C] type with the creation of two bonds, N(2)-C(3) + C(3)-C(4) (or N(l)-C(5) + C(5)-C(4)), has been studied by several groups. Beam and coworkers have published a series of papers on the synthetic utility of lithiated hydrazones. Thus, the methylhydrazone of acetophenone (598) is converted by butyllithium into the dianion (599), which in turn reacts with methyl benzoate to afford the pyrazole (600) (76SC5). In earlier publications Beam et al. have used aldehydes and acyl chlorides to obtain pyrazolines and pyrazoles by the same method. 

Thus, the lithiated SAMP hydrazones of various methyl ketones on addition to 2-(aryl-methylene)- , 3-propanedionates and propanedinitriles provide, after the removal of the auxiliary, (R)-2-( l-aryl-3-oxobutyl)-1,3-propanedioates and -propanedinitriles with high enantiomeric excess (> 95%) in 50 82% yield (sec Table 6) 195,197. Using similar methods optically active (5-lactones (90% to > 96% ee) are obtained198. 

Additions of stabilized carbanions to imines and hydrazones, respectively, have been used to initiate domino 1,2-addition/cyclization reactions. Thus, as described by Benetti and coworkers, 2-subshtuted 3-nitropyrrolidines are accessible via a nitro-Mannich (aza-Henry)/SN-type process [165]. Enders research group established a 1,2-addition/lactamization sequence using their well-known SAMP/ RAMP-hydrazones 2-308 and lithiated o-toluamides 2-307 as substrates to afford the lactams 2-309 in excellent diastereoselectivity (Scheme 2.72) [166]. These compounds can be further transformed into valuable, almost enantiopure, dihydro-2H-isoquinolin-l-ones, as well as dihydro- and tetrahydroisoquinolines. 

Hydrazones may also direct lithiation, and are particularly effective after deprotonation to an azaenolate 131 (Scheme 59). ... 

In the case of 489, the product 490 cyclizes to the isoquinolone 491, and the amide substituent is a required part of the target molecule" . However, it frequently occurs that the amide substituent is not required in the final product, and the acid-sensitive alkenyl substituent of 492 has been used as a solution to the problem of cleaving a C—N bond in the product (Scheme 193) ° °. Weinreb-type amides 493 can also be laterally lithiated, and the methoxy group removed from 494 by TiCU" . Hydrazones similarly can be laterally lithiated and oxidatively deprotected. ... 

The lithiated hydrazone (130) reacts with the salt (131) to give the amidrazone (132) in 35% yield. Oxidation of (132) with lead tetraacetate gives the 3,4-dihydrotriazole (133) (Scheme 26) <86CC1721 >. 

Lithiated hydrazones usually appear as yellow solutions or upon cooling, especially in solvents such as dimethoxyethane and diethyl ether, as colorless precipitates. 

The stereoselectivity of deprotonation is dependent on the solvent. Thus, the lithiated SAMP-hydrazone of propanal, which is generated in tetrahydrofuran, shows Ecc-Zcs configuration in >98% stereoselectivity. On the other hand, deprotonation in tetrahydrofuran/hex-amethylphosphoric triamide leads to a species with the opposite Zee cN configuration in >95% stereoselectivity. Alkylation of these azaenolates provides products of opposite absolute configuration23. 

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). 

Regiospecific and enantioselective aldol reactions 168) were also performed with SAMP (137). Lithiated hydrazones obtained from ketones (154) as described above were alkylated with carbonyl compounds and the adducts then treated with chloro-trimethylsilane. The resulting trimethylsilylethers (155) were finally oxidatively hydrolyzed to yield the chiral (3-hydroxyketones (156) (e.e. = 31-62%)168),... 

As is depicted in Scheme 1.2.29, the epoxide 128 was synthesized starting from 2,2-dimethyl-l,3-dioxan-5-one RAMP hydrazone (R)-96, which was double-alkylated with methyl iodide at a- and a -positions leading to the trons-dimethylated hydrazone 131 in 79% yield over two steps and excellent stereoselectivity (de, ee > 96%) [68]. The quaternary stereocenter bearing the desired tertiary alcohol function was generated using benzyloxymethyl chloride (BOMCl) as the electrophile to trap the lithiated hydrazone 131, providing the a-quaternary hydrazone 132 in very good yield (92%), excellent diastereomeric and enantiomeric excesses (de, ee > 96%) and with the required cis relationship of the methyl substituents. 

A highly selective method for the preparation of optically active 3-substituted or 3, y-disubstituted-S-keto esters and related compounds is based on asymmetric Michael additions of chiral hydrazones (156), derived from (5)-l-amino-2-methoxymethylpyrrolidine (SAMP) or its enantiomer (RAMP), to unsaturated esters (154).167-172 Overall, a carbonyl compound (153) is converted to the Michael adduct (155) as outlined in Scheme 55. The actual asymmetric 1,4-addition of the lithiated hydrazone affords the adduct (157) with virtually complete diastereoselection in a variety of cases (Table 3). Some of the products were used for the synthesis of pheromones,169 others were converted to 8-lactones.170 The Michael acceptor (158) also reacts selectively with SAMP hydrazones.171 Tetrahydroquinolindiones of type (159) are prepared from cyclic 1,3-diketones via SAMP derivatives like (160), as indicated in Scheme 56.172... 

Cycloalkenyllithiums.3 Alkenyllithiums are usually prepared by reductive lithiation of trisylhydrazones of ketones with butyllithium, but this method fails with the hydrazones of cyclic ketones. However, the cycloalkenyl sulfides, prepared by reaction of cyclic ketones with thiophenol, can be reductively lithiated with LDBB at -78°. This lithiation fails in the case of cyclopentenyl sulfides, but is useful in the case of the vinyl sulfides obtained from 6-, 7-, and 8-membered cycloalkanones. 

Remarkably, some hydrazones may be doubly lithiated with the second lithiation occurring a to N at the trigonal carbon atom (101).68 Doubly lithiated hydroazones of a different kind are intermediates in the Shapiro reaction (section 8.1). 

Reactions of titanated hydrazones with aldehydes occur cleanly at —20 °C (Equation 69). It is not clear whether the observed erythro-selectivity (Table 8) depends upon the geometry of the double bond, since attempts to prepare Z configurated analogs were not rewarding115). The lithiated precursors themselves are unsuitable for selective additions. Titanation not only increases stereo-differentiation, but also chemoselectivity 115). The assumption of a pericyclic transition state means that chair orientations 213 and 214 must be considered, the latter being of higher energy. However, boat transition states also explain the results U5). 

In a comprehensive study, using -NMR measurements and trapping product analysis, that was designed for understanding the stereoselectivity in electrophilic substitutions of hydrazones that underwent lithiation, it was found that lithium di-methylhydrazone salts of aldehydes are obtained as a mixture of two stereoisomers 52 and 53107,108 (equation 31). 

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