Auxiliary Evans oxazolidinone

Among chiral auxiliaries, l,3-oxazolidine-2-thiones (OZTs) have attracted important interest thanks to there various applications in different synthetic transformations. These simple structures, directly related to the well-documented Evans oxazolidinones, have been explored in asymmetric Diels-Alder reactions and asymmetric alkylations (7V-enoyl derivatives), but mainly in condensation of their 7V-acyl derivatives on aldehydes. Those have shown interesting characteristics in anti-selective aldol reactions or combined asymmetric addition. Normally, the use of chiral auxiliaries which can accomplish chirality transfer with a predictable stereochemistry on new generated stereogenic centers, are indispensable in asymmetric synthesis. The use of OZTs as chiral copula has proven efficient and especially useful for a large number of stereoselective reactions. In addition, OZT heterocycles are helpful synthons that can be specifically functionalized. 

Although the racemization of the a-carbon can now be considered a potential problem, the synthesis of 32-peptides has been achieved in the same way as seen for 33-peptides. As the 32-amino acids cannot be prepared from the analogous a-amino acids, Seebach and co-workers 5,7 opted to use Evans oxazolidinone chemistry to produce enantiomerically pure 32-amino acids. Alkylation of 3-acyloxazolidin-2-ones 17 with A-(chloromethyl)benzamide yielded the products 18 with diastereomeric ratios between 93 7 and 99 1 (Scheme 8). Removal of the chiral auxiliary (Li0H/H202) and debenzoylation (refluxing acid) was followed by ion-exchange chromatography to yield the free 32-amino acids 20 which were converted by standard means into Boc 21 or benzyl ester 22 derivatives for peptide synthesis. 

Merck has used the L-phenylalanine-derived Evans oxazolidinone to make matrix metalloproteinase inhibitors such as 45 (Scheme 23.14) (see also Chapter 2).62 The mixed anhydride of 4-butyric acid was reacted with the lithium anion of the oxazolidinone. This was enolized with the standard titanium reagents. An enantioselective Michael addition was then carried out by the addition of t-butyl acrylate at low temperature. The auxiliary was removed with LiOH/peroxides to give the acid, which was further derivatized over multiple steps to yield the desired drug. 

The control of the C8 stereocenter was achieved by alkylation directed by an auxiliary at C7 involving Oppolzer sultams, Enders hydrazones and Evans oxazolidinones (Scheme 5 l-IIl, resp.). Either the corresponding propionate [14, 37] or propionaldehyde [13, 16] equivalents were alkylated with an alkyl iodide representing the principal part of the northern half of epothilones (Scheme 5 1, II), or C-8 of a sui-table chain was methylated diastereoselec-tively (Scheme 5 III, IV). 

While the sultame and the oxazolidinone auxiliaries represent carboxylate equivalents, which have to be reduced (and sometimes re-oxidized) to the required aldehyde function at C7, the strength of Enders SAMP and RAMP auxiliaries is their direct use as aldehyde and ketone equivalents. However, Nicolaou et al. [13, 16] for the synthesis of the protected building blocks 17a-c had to give up the correct oxidation state in order to allow necessary later manipulations. Considering the necessity of reduction, the cheaper and recoverable Evans-oxazolidinones 18 appear to be the auxiliaries of choice, as demonstrated by Schinzer et al. [21, 22, 36]. A similar methylation is described in an early publication of De Brabander et al. [38] where sultame 21 was methylated and reduced to the a-methylaldehyde 20b in only two steps in good yield and enantiomeric excess. 

Dianion aldol condensation reactions with Evans oxazolidinones or Oppolzer sultams as chiral auxiliaries have been demonstrated to be a useful method to generate the core skeleton of furofurans with diastereoselectivities of 5 1-20 1. Stereoselective total syntheses of the furofuran lignans (-l-)-eudesmin, (+)-yangambin, (—)-eudesmin, and (-)-yangambin according to this procedure have been reported (Equation 102) <2006TL6433>. 

An anticonvulsant, CI-1008,(16), was recently developed using the Evans oxazolidinone auxiliary 17 derived from (7.S, 2A)-(-)-norephedrine [45], The route was scaled up to produce several hundred kilogram quantities at production and pilot plant scale and provided early clinical trial malerial (Scheme 2). 

A different approach to enantioselective electrophilic fluorination is the use of chiral auxiliary groups on the substrate this converts the problem into a diastereo-selective fluorination. The ground-breaking work in this field was done since 1992 by the Davis group [207], by fluorination of imide enolates modified by Evans oxazolidinone chiral auxiliary [208] using N-fluoro-o-benzenedisulfonimide (NFTh) as the electrophilic fluorination agent (Scheme 2.94). 

Application of asymmetric alkylation with Evans auxiliaries Aldol Reactions with Evans Oxazolidinones The syn aldol reaction with boron enolates... 

Anti-aldols by Lewis acid-catalysed reactions with Evans oxazolidinones Chiral Auxiliaries... 

Michael additions with 8-phenylmenthyl esters of unsaturated acids Chiral auxiliaries attached elsewhere in asymmetric Michael additions Other Chiral Auxiliaries in Conjugate Addition The Evans oxazolidinones Chiral sulfoxides Asymmetric Birch Reduction Birch reduction of benzene Asymmetric Birch reduction of heterocycles... 

The succinate core can be prepared by alkylation of a simple carboxylic acid (74a or b) with a bromoacetate using the Evans oxazolidinone chiral auxiliary derived from phenylalanine (chapter 27). The branched alkyl group must be present in the substrate for alkylation and the second acid group added in the alkylation so that there is no competition between two carbonyl groups during enolate formation. After hydrolysis (91% yield) the alkylated succinic acid 77 has >95% ee. Notice that the two acid groups are differentiated by this procedure.10... 

Scheme 33 illustrates the use of two standard persistent auxiliaries. The Evans oxazolidinone 33-1 [83] is highly versatile, i.e., suitable for enolate reactions and double bond additions alike. In the enolate alkylation case [reaction (99)] the high diastereoselectivity depends on the formation of a chelate 33-2 which fixes the reaction site in a defined conformation in which one of the diastereofaces is efficiently shielded. The removal of the auxiliary requires the chemoselective cleavage of the exo cyclic amide bond which is sometimes difficult to achieve. In boron mediated aldoltype additions [Scheme 34, reaction (100)] no chelate can be formed so that the extremeley high diastereoselectivity with which the syn-adduct 34-1 is formed must be due to some other effect, presumably allyl 1,3-strain on the stage of the enol borinate 34-1. 

In addition to amino acids, 1,2-amino alcohols can be used as chiral auxiliaries. The synthesis of the amino acid derivative 16 outlined in Scheme 9.15 is a variation of a Strecker reaction. - Evans oxazolidinone chemistry is well documented, which allows for a wide variety of reactions to be performed with a high degree of predictability. In addition to alkylation reactions to introduce the side chain of an amino acid, the nitrogen group can also be introduced in a variety of ways, one of which is illustrated in Scheme 9.16. ... 

A highly versatile auxiliary is the Evans oxazolidinone imide (Figure 5.4c, see also Scheme 3.16), available by condensation of amino alcohols [86,87] with diethyl carbonate [86]. Deprotonation by either LDA or dibutylboron triflate and a tertiary amine affords only the Z(0)-enolate. Scheme 5.12 illustrates open and closed transition structures that have been postulated for these Zf0)-enoIates under various conditions, and Table 5.4 lists typical selectivities for the various protocols. The first to be reported (and by far the most selective) was the dibutylboron enolate (Table 5.4, entry 1), which cannot activate the aldehyde and simultaneously chelate the oxazolidinone oxygen [75]. Dipolar alignment of the auxiliary and approach of the aldehyde from the Re face of the enolate affords syn adduct with outstanding diastereoselection, presumably via the closed transition structure illustrated in Scheme 5.12a [75]. The other syn isomer can be formed under two different types of conditions. In one, a titanium enolate is postulated to chelate the oxazolidinone... 

In our synthesis [36] of spiruchostatin A, we followed Simon s procedure for the preparation of 3. We too were unable to achieve the Carreira aldol in good yield. Moreover, the reaction requires the preparation of three noncommercial materials the binaphthyl chiral aminophenol, the t-butyl salicaldehyde, and the silyl ketene acetal. Instead, we opted for a diastereoselective aldol with the Nagao auxiliary. For reasons that are not completely clear, the Nagao thiazolidinethione auxiliary exhibits high diastereoselectivity in acetate aldols unlike the more popular Evans oxazolidinone auxiliary. In this case, aldol adduct 7 was obtained in good yield (Scheme 12-3). Unlike the other syntheses, this was coupled directly to the peptide rather than hydrolyzed to the acid 5. 

Reactions B and C show the use of the most popular, versatile, and successful chiral auxiliaries, namely Evans oxazolidinones [15], easily obtained from aminoalcohols of the chiral pool . The two oxazolidinones reported here behave as quasi-enantiomers, thus avoiding the use of their much more expensive real enantiomers. 

Table 11.16. Evans Oxazolidinone Auxiliaries in an Intramolecular Diels-Alder Reaction...

Polymer-bound Evans oxazolidinones were recently studied by several groups.774-276 Burgess and compared the benzylation of propionylated auxiliary 71 attached to Merrifield resin... 

For example, in a synthesis of the immunosuppressant (-)-sanglifehrin A, the alcohol 57 was converted into the chiral alcohol 58 as a single enantiomer (1.73). The procedure involves oxidation of the alcohol 57 with pyridinium chlorochro-mate (PCC) and conversion to the Evans oxazolidinone (via the mixed anhydride), followed by stereoselective enolate formation and alkylation, then reduction to remove the auxiliary. 

The asymmetric aldol reaction using the Evans oxazolidinone auxiliary has been used in a number of syntheses. Suggest reagents for the preparation of the imide 2, used in a synthesis of cytovaricin and explain the stereoselectivity of this reaction. Suggest how you would obtain the other syn aldol product and explain the difference in the stereoselectivity. 

The final fragment is a simple chiral carboxylic acid, so we need a method for its asymmetric synthesis. The most obvious choice is probably an asymmetric alkylation using Evans oxazolidinone auxiliary formation of the appropriate derivative of hexanoic acid is simple, and the enolate will be alkylated diastereoselectively by methyl iodide. You would probably take this approach if you need to make a few grams for initial studies. 

But the Merck chemists noticed that amino alcohol itself, certainly once protected, has a remarkable similarity to Evans oxazolidinone auxiliaries anyway, and it turns out that this amino alcohol will function very successfully as a chiral auxiliary, which does not need to be removed, avoiding waste and saving steps The amino alcohol was acylated with the acyl chloride, and the amide was protected as the nitrogen analogue of an acetonide by treating with 2-methoxypropene (the methyl enol ether of acetone) and an acid catalyst. The enolate... 

For an early discussion of the Evans oxazolidinone chiral auxiliaries, see D. A. Evans, J. V. Nelson,... 

Scheme 4-6 Evans oxazolidinone-based chiral auxiliaries in diastereoselective aldol...

Chiral ketene fragments have proven to offer more general utility in the quest for enantioselective Staudinger reactions. In particular, ketenes containing the Evans oxazolidinone have proven to offer high diastereoselectivities in the synthesis of 3-amino-P-lactams. The ease of preparation of the carboxylic acid precursor, the low cost of the auxiliary, and the facile unmasking of the 3-amino group from the auxiliary all... 

Li and co-workers developed a novel asymmetric halo aldol reaction using Evans oxazolidinones as chiral auxiliaries for tandem I-C/C-C bond formations. This reaction provides a practical approach to a variety of halo aldols of a non-Evans type that cannot be easily prepared by other methods. Excellent diastereoselectivity (> 95% de) and yields (80-93%) have been obtained. This reaction can be considered as a Lewis acid (Et2Al-I)-promoted Morita-Baylis-Hillman (MBH) process. 

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