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Enders alkylation

Utilization of Enders Alkylation with Other Electrophiles Enders hydrazones were also shown to react with other electrophiles than alkyl halides. Indeed, several carbon-centered electrophiles could be used such as aldehydes and ketones through aldolization reactions [22], various Michael acceptors [23], aziridines [24], but also some unconventional electrophiles such as THE in the presence of trialkylsilyl tiifluoromethane sulfonate or cyclopropenes with the zinc azaenolate [25]. [Pg.49]

Chiral hydrazones for asymmetric alkylations (RAMP/SAMP hydrazones- D. Enders "Asymmetric Synthesis" vol 3, chapt 4, Academic Press 1983)... [Pg.79]

Chiral oxazolines were the first ehiral auxiliaries used for asymmetrie enolate alkylations. Subsequent studies led to the development of a number of other ehiral auxiliaries (34-38) ineluding those reported by Evans, Myers, Enders, Sehollkopf, and others, whieh are now widely used in asymmetrie synthesis. Although these new auxiliaries frequently provide higher yields and enantioseleetivities than the oxazolines originally developed by Meyers, the pioneering work of Meyers laid the groundwork for these later studies. [Pg.241]

A more recent synthesis of 197 [365] is shown in Fig. 9. Enders introduced the stereogenic centre of (S)-lactic acid into the crucial position 10 in 197. The vinylsulfone B, readily available from lactic acid, was transformed into the planar chiral phenylsulfonyl-substituted (q3-allyl)tetracarbonyliron(+l) tetra-fluoroborate C showing (IR,2S,3 )-configuration. Addition of allyltrimethyl silane yielded the vinyl sulfone D which was hydrogenated to E. Alkylation with the dioxolane-derivative of l-bromoheptan-6-one (readily available from 6-bro-mohexanoic acid) afforded F. Finally, reductive removal of the sulfonyl group and deprotection of the carbonyl group furnished 197. A similar approach was used for the synthesis of 198 [366]. [Pg.150]

The use of chiral auxiliaries has been developed into elegant three-step sequences to achieve high ee s (Figure 2). In the general scheme a ketone is derivatized with a chiral amine. Low temperature lithiation and alkylation followed by hydrolysis produces the alkylated ketone in moderate to excellent ee s. The auxiliaries most often used are (S)-valine tert-butyl ester (Koga), l-amino-2-methoxymethylpyrrolidine (Enders) and (S)-2-amino-1-... [Pg.67]

In concurrent and independent work, Suzuki and Enders found that tethered keto-aldehydes undergo highly enantioselective cross-benzoin reactions using tria-zolium based catalysts [50, 51], The scope includes various aromatic aldehydes with alkyl and aryl ketones (Table 4). Additionally, aliphatic substrate 39a is cyclized in excellent enantioselectivity, albeit in 44% yield. [Pg.87]

In 1996, Enders and coworkers reported the asymmetric epoxidation of ( )-enones 91 in the presence of stoichiometric amounts of diethylzinc and (lR,2R)-A-methylpseudo-ephedrine (120) under an oxygen atmosphere to give fraw -epoxides 92 with excellent yields (94-99%), almost complete diastereoselectivity (>98% de) and with very good enantioselectivities (61-92%) (Scheme 54) . For the same reaction Pu and coworkers utilized achiral polybinaphthyl 121 as ligand (in excess) instead of the chiral aminoalcohol. For each substrate, only one diastereomer was formed, but in most cases yields were lower than observed with the Enders system. Enders catalyst shows high asymmetric induction for alkyl-substituted enones (ee 82-92%), but for substrates bearing only aromatic substituents only modest enantioselectivity was obtained (R = R = Ph ... [Pg.386]

Different synthetic routes have been used to prepare these carbenes (Scheme 8.6). The most common procedure is the deprotonation of the conjugate acid. In early experiments, sodium or potassium hydride, in the presence of catalytic amounts of either f-BuOK or the DMSO anion were used. ° Then, Herrmann et al. showed that the deprotonation occurs much more quickly in liquid ammonia as solvent (homogeneous phase), and many carbenes of type IV have been prepared following this procedure. In 1993, Kuhn and Kratz" developed a new and versatile approach to the alkyl-substituted N-heterocyclic carbenes IV. This original synthetic strategy relied on the reduction of imidazol-2(3//)-thiones with potassium in boiling tetrahydrofuran (THF). Lastly, Enders et al." reported in 1995 that the 1,2,4-triazol-5-ylidene (Vila) could be obtained in quantitative yield from the corresponding 5-methoxy-l,3,4-triphenyl-4,5-dihydro-l//-l,2,4-triazole by thermal elimination (80 °C) of methanol in vacuo (0.1 mbar). [Pg.338]

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). [Pg.204]

Enders et al. 205) metalated the (S)-proline-derived chiral allylamines (209). The resulting homoenolate (210) was subsequently alkylated. Upon hydrolysis P-sub-stituted aldehydes (211) were obtained (e.e. = 64-67%). [Pg.223]

D. Enders in Asymmetric Synthesis, Ed. J. D. Morrison, Academic Press, New York (1984), Vol 3, Chpt 4 (Alkylation of Chiral Hydrazones)... [Pg.1517]

D. E. Bergbreiter and M. Newcombe (1983). Alkylation of imine and enamine salts , in Asymmetric Synthesis, Ed. J. D. Morrison. Orlando, Florida Academic Press. Vol. 2A, p. 243 D. Enders (1984). Alkylation of chiral hydrazones , in Asymmetric Synthesis. Ed. J. D. Morrison. Orlando, Florida Academic Press, Vol. 3, p. 275. [Pg.819]

Seebach, D. Enders, D. Umpolung of amine reactivity. Nucleophilic a-(secondary amino)-alkylation via metalated nitrosamines. Angew. Chem. Int. Ed. 1975, 14, 15-32. [Pg.214]

The aldimine of Figure 13.34 is a chiral and enantiomerically pure aldehydrazone C. This hydrazone is obtained by condensation of the aldehyde to be alkylated, and an enantiomerically pure hydrazine A, the S-proline derivative iS-aminoprolinol methyl ether (SAMP). The hydrazone C derived from aldehyde A is called the SAMP hydrazone, and the entire reaction sequence of Figure 13.34 is the Enders SAMP alkylation. The reaction of the aldehydrazone C with LDA results in the chemoselective formation of an azaenolate D, as in the case of the analogous aldimine A of Figure 13.33. The C=C double bond of the azaenolate D is fraws-configured. This selectivity is reminiscent of the -preference in the deprotonation of sterically unhindered aliphatic ketones to ketone enolates and, in fact, the origin is the same both deprotonations occur via six-membered ring transition states with chair conformations. The transition state structure with the least steric interactions is preferred in both cases. It is the one that features the C atom in the /3-position of the C,H acid in the pseudo-equatorial orientation. [Pg.548]

It is worth mentioning that chiral N,N-dialkylhydrazones (SAMP, RAMP) had been introduced by Enders for asymmetric a-alkylation of carbonyl compounds [29], and addition of organometallic reagents to the C=N bond had also been demonstrated ([30] selected organometallic additions to other chiral hydrazones [31-34]). However, the SAMP and RAMP hydrazones require a multistep preparation, and lacked a carbonyl function for two-point binding, which we regarded as a key design element (see below). [Pg.63]

The aldimine of Figure 10.31 is a chiral and enantiomerically pure aldehydrazone C. This hydrazone is obtained by condensation of the aldehyde, which shall be alkylated, and an enantiomerically pure hydrazine A (see Table 7.2 for the mechanism), the S-proline derivative Aaminoprolinol methyl ether (SAMP). The hydrazone C derived from aldehyde A is called the SAMP hydrazone, and the entire reaction sequence of Figure 10.31 is the Enders SAMP procedure. The reaction of the aldehydrazone... [Pg.397]

Fig. 10.31. Enders SAMP method for the generation of enantiomerically pure a-alkylated carbonyl compounds SAMP, S-aminoprolinol methyl ether = S-2-methoxymethyl-1 -pyrrolidinamine. Fig. 10.31. Enders SAMP method for the generation of enantiomerically pure a-alkylated carbonyl compounds SAMP, S-aminoprolinol methyl ether = S-2-methoxymethyl-1 -pyrrolidinamine.
Electrophilic substitution. A number of chiral nucleophilic species have been described that result in optically active a-alkyl aldehydes, ketones, acids, and acid derivatives upon alkylation and (usually) subsequent hydrolytic cleavage. Enders provides a number of examples (Figure 3) one of which results in the ant alarm pheromone, 4-methyl 3-heptanone (26 2 7). Studies by A. I. Meyers of the chemistry of anions of chiral oxazolines (Figure 4) were the first of the genre, however ( 8 ). Related reactions of chiral anions of metalloenamines and hydrazones (29, 30, 31) have in common with the alkylation of oxazolines metallated azaenolate intermediates that predispose one face of an azaenolate double bond to reaction with the electrophile. [Pg.63]

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