RAMP hydrazine auxiliary

Recently Pan and Liu unveiled two SAMP and RAMP hydrazine analogs, namely, (S)/(R)-2-amino-3-methoxyme-thyltetrahydro-quinoline, also called SAMIQ and RAMIQ hydrazines [21]. Interestingly, instead of building their chiral auxiliaries around the proline framework, the authors used (S)- and (R)-phenylalanine. The tetrahydroquinoline moiety was prepared via a Pictet-Spengler annulation with formaldehyde. These chiral auxiliaries were evaluated for their... 

The SAMP/RAMP Method As early as 1976, azaenolates derived from A,A-dialkyl hydrazones were studied as an alternative to direct ketone and aldehyde enolate alkylations. These species were found to exhibit higher reactivity toward electrophiles, as well as better regioselectivity for C-alkylation than their parent carbonyl compounds. A,A-diaIkyl hydrazones are stable and are relatively easy to prepare, making them appealing from a practical point of view in comparison with imines and enamines, which can be difficult to form quantitatively and are hydrolytically unstable. Given these desirable attributes, Enders undertook the development of chiral nonrace-mic A,A-diaIkyl hydrazine auxiliaries for the asymmetric a-alkylation of ketones. The result of his efforts were (5)-and (R)-l-amino-2-methoxypyrrohdine hydrazine (1 and 2, respectively), now commonly known as the SAMP and RAMP auxiliaries, respectively (Figure 7.1). Over the years, the SAMP/RAMP method has come to be considered the state-of-the-art approach to asymmetric ketone... 

In the late 1970s, Enders pioneered an elegant method for ketone and aldehyde alkylation involving the use of metalated chiral hydrazones [92, 93). Extensive studies with the (S)-l-amino-2-methoxymethylpyrrolidine (SAMP, 150, Scheme 3.24) auxiliary and its enantiomer RAMP established these as superb chiral auxiliaries with numerous applications. In a typical alkylation sequence, a RAMP/SAMP hydrazine is condensed with an aldehyde or a ketone to form the corresponding hydrazone, such as 152. This can subsequently be deprotonated and the resulting enolate trapped with a variety of electrophilic reagents including alkyl halides, aldehydes, Michael acceptors, silyl triflates, and disulfides. The RAMP/SAMP hydrazine auxiliary may be removed by acidic hydrolysis or ozonolysis to reveal the alkylated... 

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. 

The use of hydrazines as chiral auxiliaries was initiated by Enders and coworkers [315]. They have developed the chemistry of hydrazones derived from epimeric 1 -amino-2-methoxymethylpyrrolidines 1.76, Samp and Ramp [161, 169, 253, 261, 315, 316], These compounds are commercially available, or they can easily be prepared from (S)-prolinol 1.64 (R = CH2OH) or (R)-glutamic add [261]. Hydrazones have some advantages over their related imine derivatives. First, they are formed in quantitative yield even from sterically hindered ketones. Second, their derived anions are often more reactive than the related aldehyde or ketone enolates. 

Diastereoselectivity is also observed in reactions of carbanions derived from imines and hydrazones, when those species contain a chiral center or a chiral auxiliary (sec. 9.4.F). Asymmetric imines can be used, and chiral oxazoline derivatives have also been prepared and used in the alkylation sequence (sec. 9.3.A). Meyers showed that chiral oxazoline 478 could be alkylated to give the ethyl derivative, 479. A second alkylation generated the diastereomeric product 480, and hydrolysis provided the chiral lactone (481) in 58% yield and with a selectivity of 70% ee for the (R) enantiomer. 53 As pointed out in Section 9.4.F.ii, hydrazone carbanions can be used for alkylation or condensation reactions. In a synthesis of laurencin. Holmes -l prepared the asymmetric hydrazone 483 (prepared by Enders by reaction of cycloheptanone and the chiral hydrazine derivative called SAMP, 482-A-amino-(2S)-(methoxymethyl)pyrrolidine)- - and showed that treatment with LDA and reaction with iodomethane gave an 87% yield of the 2-ethyl derivative in >96% de. Ozonolysis cleaved the SAMP group to give (/ )-2-ethylcycloheptane (484) in 69% yield. The enantiomer of 482 is also known (it is called RAMP, A-amino-(27 )-(methoxymethyl)pyrrolidine). 

Alkylation of lithiated hydrazones forms the basis of an efficient method for the asymmetric alkylation of aldehydes and ketones, using the optically active hydrazines (5)-l-amino-2-(methoxymethyl)pyrroUdine (SAMP) 59 and its enantiomer (RAMP) as chiral auxiliaries. Deprotonation of the optically active hydra-zones, alkylation and removal of the chiral auxiliary under mild conditions (ozonol-ysis or acid hydrolysis of the A-methyl salt) gives the alkylated aldehyde or ketone with, generally, greater than 95% optical purity. This procedure has been exploited in the asymmetric synthesis of several natural products. Thus, (S)-4-methyl-3-heptanone, the principal alarm pheromone of the leaf-cutting ant Am texana, was prepared from 3-pentanone in very high optical purity as shown in Scheme 1.74. 

The hydrazine SAMP, derived from (S)-proline, and its enantiomer RAMP were developed by EndersO ] for the asymmetric alkylation of aldehydes and ketones, and are commercially available, though expensive. The chiral auxiliary may be removed either by quatemisation with methyl iodide followed by hydrolysis, or by ozonolysis. 

One of the most successful classes of chiral auxiliaries for asymmetric synthesis is that of Enders proline-based hydrazines, namely (S)-l-amino-2-methoxymethylpyrrolidine (SAMP, 74) and its (R)-enantiomer RAMP (Scheme 11.11) [68]. Enders has reported that chiral hydrazones such as 75 undergo diastereoselective additions with organolithium reagents. The facile removal of the auxiliary by reductive cleavage of the N-N bond enables it as a versatile tool for the synthesis of a wide range of chiral secondary amines [69, 70]. As shown in Scheme 11.11, the secondary amine 77 was thus prepared in 73 % overall yield and 93 % ee [69]. 

The chiral hydrazines SAMP (81) and RAMP (ent-81) developed by Enders have proven useful as auxiliaries in asymmetric conjugate additions of their... 

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