Hydrazone auxiliary

A salient feature of the SAMP and RAMP hydrazone auxiliaries is their ready availability. SAMP (150) can be synthesized from L-proline (163), either in four steps via a nitroso intermediate or more conveniently by Hoffmann degradation (165 150, Scheme 3.26) [96]. Its enantiomer, RAMP, can likewise be obtained from n-proline or alternatively, in six steps and 35 % overall yield from the cheaper starting material (R)-glutamic acid (166) [93]. 

This goal might well be achieved by introducing an auxiliary that aids the coordination to the catalyst. After completion of the Diels-Alder reaction and removal of the auxiliary the desired adduct is obtained. This approach is summarised in Scheme 4.6. Some examples in which a temporary additional coordination site has been introduced to aid a catalytic reaction have been reported in the literature and are described in Section 4.2.1. Section 4.2.2 relates an attempt to use (2-pyridyl)hydrazone as coordinating auxiliary for the Lewis-acid catalysed Diels-Alder reaction. 

Inspired by the work of Burk and Feaster ) we attempted to use (2-pyridyl)hydrazine (4.36) as a coordinating auxiliary (Scheme 4.10). Hydrazines generally react effidently with ketones and aldehydes. Hence, if satisfactory activation of the dienophile can be achieved through coordination of a Lewis acid to the (2-pyridyl)hydrazone moiety in water. Lewis-add catalysis of a large class of ketone- and aldehyde-activated dienophiles is antidpated Subsequent conversion of the hydrazone group into an amine functionality has been reported previously by Burk and Feaster ... 

J Based on polarimctry. NMR and GC analysis. These results support a uniform stereochemical course of the reaction The nucleophile attacks the Re-face of the SAMP-hydrazone. b Obtained with RAMP (2c) as auxiliary. 

An excellent synthetic method for asymmetric C—C-bond formation which gives consistently high enantioselectivity has been developed using azaenolates based on chiral hydrazones. (S)-or (/ )-2-(methoxymethyl)-1 -pyrrolidinamine (SAMP or RAMP) are chiral hydrazines, easily prepared from proline, which on reaction with various aldehydes and ketones yield optically active hydrazones. After the asymmetric 1,4-addition to a Michael acceptor, the chiral auxiliary is removed by ozonolysis to restore the ketone or aldehyde functionality. The enolates are normally prepared by deprotonation with lithium diisopropylamide. 

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. 

Simple 1,2,4-triazole derivatives played a key role in both the synthesis of functionalized triazoles and in asymmetric synthesis. l-(a-Aminomethyl)-1,2,4-triazoles 4 could be converted into 5 by treatment with enol ethers <96SC357>. The novel C2-symmetric triazole-containing chiral auxiliary (S,S)-4-amino-3,5-bis(l-hydroxyethyl)-l,2,4-triazole, SAT, (6) was prepared firmn (S)-lactic acid and hydrazine hydrate <96TA1621>. This chiral auxiliary was employed to mediate the diastereoselective 1,2-addition of Grignard reagents to the C=N bond of hydrazones. The diastereoselective-alkylation of enolates derived from ethyl ester 7 was mediated by a related auxiliary <96TA1631>. 

The reaction of hydroximoyl chlorides with the chiral, nonracemic hydrazones 313 (Equation 58) in the presence of TEA gave the 4,5-dihydro-l,2,4-oxadiazoles 314 as single diastereomers from which the chiral auxiliary was easily removed to furnish the corresponding 4-unsubstituted 4,5-dihydro-l,2,4-oxadiazoles with high ee s <1999H(50)995>. 

It has been reported that the cleavage of SAMP hydrazones can proceed smoothly with a saturated aqueous oxalic acid, and this allows the efficient recovery of the expensive and acid-sensitive chiral auxiliaries SAMP and RAMP. No racemization of the chiral ketones occurs during the weak acid oxalic acid treatment, so this method is essential for compounds sensitive to oxidative cleavage.393... 

Several reviews and research papers discussing the application and extension of this method have appeared.40 For example, Weber et al.41 reported an interesting result in which cerium acted as a counterion in the modified proline auxiliary (SAMEMP 40) for selective addition of organocerium reagents to hydrazones. The initial adduct was trapped with either methyl or benzyl chloro-formate to afford the stable /V-aminocarbonatc 41 (Scheme 2-24). From this example readers can see that this proline chiral auxiliary can be used not only for a-alkylation but also for nucleophilic addition, which is discussed in detail later. 

Chapter 2 provided a general introduction to the a-alkylation of carbonyl compounds, as well as the enantioselective nucleophilic addition on carbonyl compounds. Chiral auxiliary aided a-alkylation of a carbonyl group can provide high enantioselectivity for most substrates, and the hydrazone method can provide routes to a large variety of a-substituted carbonyl compounds. While a-alkylation of carbonyl compounds involves the reaction of an enolate, the well known aldol reaction also involves enolates. 

The addition of a-lithiomethoxyallene 144 [55] to benzaldehyde dimethylhydra-zone 145 (Eq. 13.48) leads to a mixture of pyrroline 146 and dihydroazete 147 [56]. The cydization in this case, which takes place in the same operation as the addition to the hydrazone, follows two distinct pathways, with attack of the nitrogen atom taking place at the inner, in addition to the terminal, carbon atom of the allene. A similar reaction of 144 with SAMP-hydrazone 148 (Eq. 13.49) leads to 3-pyrroline 149 in 88% yield and excellent diastereoselectivity [57]. Cleavage of the chiral auxiliary group from 149 takes place in two steps (1, methyl chloroformate 2, Raney nickel, 50 bar, 50 °C) in 74% overall yield. When the addition of 144 to 148 is conducted in diethyl ether, cydization of the adduct does not take place. Surprisingly, the hydrazones of aliphatic aldehydes react with 144 in poor yield in THF, but react quantitatively and diastereoselectively in diethyl ether to give the (uncyclized) allenyl hydrazone products. 

Substituted 1,2,4-oxadiazoles were prepared by addition of nitrile oxides to imines or hydrazones. It has been reported that interaction of hydroximoyl chlorides 262 with chiral hydrazones 263 in the presence of EtsN leads to intermediates 264 with diastereoselectivity up to 97%. A subsequent N-N bond cleavage to remove chiral auxiliary by formic acid leads to 1,2,4-oxadiazolines 265 with ee up to 91% (equation 113). ... 

The fluorination of enolates of ketone, amide, or hydrazone bearing a chiral auxiliary (SAMP, Evans oxazolidine) with nonchiral fluorination reagent (A-fluoro sulfonimides, A-fluoropyridine) occurs with excellent diastereoselectivities. ... 

Dihydrooxadiazoles 106 have been syntheised in moderate to high diastereomeric excess by the addition of aromatic nitrile oxides across the C=N bond of the hydrazones 105. The N-N bond can subsequently be cleaved with formic acid, and the chiral auxiliary recycled <99H(50)995>. The oxadiazolone 108 was produced (56%) from the oxime 107 by heating it with phenyl isocyanate <99SC3889>. ... 

Excellent enantioselectivities up to complete asymmetric induction are achieved in the preparation of a-alkylated aldehydes, acyclic and cyclic ketones via (-)-(S)- and (+ )-(7 )-1 -amino-2-methoxymethylpyrrolidine (SAMP/RAMP-hydrazones) (see Section 1.1.1.4.2.). Due to the unique mechanism of metalation and alkylation, the absolute configuration of the final products can be predicted. Since both antipodes of the auxiliary are available, either enantiomer of the desired alkylated carbonyl compound can be prepared... 

In contrast to the variety of chiral auxiliaries which have been used in the asymmetric alkylation of imine-derived azaenolates (see Section 1.1.1.4.1Table 7), alkylations of the hydrazone analogues employ mainly (-)-(S)-l-amino-2-methoxymethylpyrrolidine (SAMP) and its opti-cal antipode (RAMP). r A oCH, O ... 

After use of this cleavage method, the chiral auxiliary may be partially recycled by neutralization and extraction of the aqueous layer. In this way a mixture of methylated hydrazine, the SAMP-hydrazone of formaldehyde and SAMP (1 7 2) is obtained, which is subjected to air oxidation and hydrolysis8. 

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). 

One way to achieve a higher stereoselectivity in these aldol reactions could obviously be the variation of the alkoxy group on the pyrrolidine sidechain of the chiral auxiliary. Thus, Enders and co-workers synthesized the SAMP-analogue (159). While acetone-SAMP-hydrazone leads to a (+)-[3-hydroxyketone in 47% e.e., the corres-... 

During our investigations on asymmetric C—C bond formation reactions via conjugate addition of SAMP hydrazones to various a,(3-unsaturated Michael acceptors, it occurred to us to use the chiral hydrazine auxiliary S AM P as a nitrogen nucleophile and a chiral equivalent of ammonia in aza-Michael additions. Thus, we developed diastereo- and enantioselective 1,4-additions for the synthesis of P-amino acids and P-aminosulfonates [14, 15]. 

In continuation of our efforts to explore the utility of the SAMP/RAMP hydra-zone methodology, we developed the first asymmetric synthesis of a-phosphino ketones via formation of a carbon-phosphorus bond in the a-position to the carbonyl group [70]. The key step of this asymmetric C—P bond formation is the electrophilic phosphinylation of the ketone SAMP hydrazone 87, giving rise to the borane-adduct of the phosphino hydrazone 88 with excellent diastereoselectiv-ity (de = 95-98%). Since these phosphane-borane adducts are stable with respect to oxidation, the chemoselective cleavage of the chiral auxiliary by ozonolysis leading to the a-phosphino ketones (R)-89 could be accomplished with virtually no racemization. Using RAMP as a chiral auxiliary, the synthesis of the enantiomer (S)-89 was possible (Scheme 1.1.25). 

The methyl group was introduced by a two-step procedure. Thus, the hydrazone Michael adducts 52 were converted into the enol pivaloates 53 in excellent yields and diastereomeric excesses de > 96%) by treatment with pivaloyl chloride and triethylamine. After treatment with lithium dimethylcuprate the chiral auxiliary was removed by addition of 6n HCl in order to obtain the 5-substituted 2-methylcyclopentene carboxylate 54 in good yields and with excellent stereoselectivity (de, ee > 96%). Finally, the asymmetric synthesis of dehydroiridodiol (55, R = Me, = H) and its analogues was accomplished by reduction of 54 with lithium aluminum hydride or L-selectride leading to the desired products in excellent yields, diastereo- and enantiomeric excesses (de, ee > 96%). 

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