Oxazolidinones deprotonation

In the alkylation reactions of the chiral 3-acyl-2-oxazolidinones, deprotonation to the lithium or sodium enolate is by treatment with lithium diisopropylamide or lithium or sodium hexamethyldisilazanide in tetrahydrofuran at low temperature (usually — 78 °C). The haloalka-ne, usually in excess, is then added to the enolate solution at low temperature (usually — 78 °C) for the sodium enolates and at higher temperatures (between —78 and 0CC) for the lithium enolates. When small, less sterically demanding halides, such as iodomethane, are used the sodium enolate is usually preferred 2 24 and in these cases up to five equivalents2,6- 24,26,27 of the halide are necessary in order to obtain good yields of the alkylation products. Conventional extractive workup provides the crude product as a diastereomeric mixture (d.r. usually > 90 10) which is relatively easy to separate by silica gel chromatography and/or by recrystallization (for crystalline products). Thus, it is possible to obtain one diastereomer in very high diastereomeric purity. 

N-(2-Hydroxypropyl)carbamates (8.139, Fig. 8.13,b) are prodrugs that resemble the A-(2-hydroxyphenyl)carbamates discussed above. Here, activation yielded the tranquilizer mephenoxalone (8.140, Fig. 8.13,b) and an alcohol or a phenol such as paracetamol. Other active oxazolidinones could be obtained by replacing the MeO group in 8.139 (Fig. 8.13, b) with another substituent. For this series, the mechanism of activation is not an intramolecular nucleophilic attack, but, rather, decomposition of the deprotonated carbamate group as shown in Fig. 8.7,b, Reaction b, with the intermediate isocyanate being trapped to form the oxazolidinone ring. 

The utility of -phenyl camphor-derived oxazolidinones as chiral formyl anion syn-thons has been demonstrated by Gawley and coworkers (Scheme 42). Deprotonation yields a dipole-stabihzed organolithium intermediate and the absolute configuration of the lithium-bearing carbon is presumed to be R. Additions to benzaldehyde and cyclohexane carboxaldehyde are 86% and 76% diastereoselective, respectively, but recrystallization affords a single diastereomer in the yields shown. Addition is postulated to proceed via the pre-complex shown in the inset, in which the aldehyde is coordinated to the R epimer... 

Deprotonation of 3-arylmethyl-2-oxazolidinones using standard conditions followed by alkylation at — 100 °C gives the a-alkylated oxazolidinones, with good yields and high diastereoselectivity (by NMR spectroscopy), which were subsequently converted to l-arylalkylamines32. 

The 3-acyl-2-oxazolidinones are readily deprotonated by strong, sterically hindered amide bases in dry telrahydrofuran at low temperature to afford the. vyn-enolates. Alkylation then provides products with induced chirality in the a-position of the amide with good to excellent di as tereo selectivities. 

S)-2-Amino-3-methylbutanol [(S)-valinol] derived oxazolidinones, i.e., (S)-3-acyl-4-iso-propyl-2-oxazolidinones 1, have been used extensively for the preparation of a-alkylated acids, aldehydes and alcohols. The enolates are formed by deprotonation with lithium diisopropyl-amide or sodium hexamethyldisilazanide at low temperature in tetrahydrofuran. Subsequent addition of a haloalkane gives alkylation, which occurs from the Si-face2. The diastereoselectivities are usually good (>90 10), and the products are usually purified by flash chromatography and/or recrystallization (see Table 10). Additional examples of alkylation of 1 have been published5 l0 12- 20 22-29 39.44.-47,49.57.70-78... 

A camphor-based 3-acyl-2-oxazolidinone has also been used for diastereoselective alkylations66. The A-acylated auxiliary 18 is prepared in three steps from 7,7-dimethyl-2-oxobicy-clo[2.2.1]heptane-l-carboxylic acid (ketopinic acid, 17)67. Deprotonation by lithium diiso-propylamide in tetrahydrofuran at — 78 °C and subsequent alkylation with activated halides [(bromo- or (iodomethyl)benzene, 3-bromo- or 3-iodopropene] furnished moderate to good yields of alkylation products in high diastereomeric ratios (>97 3 by H NMR). With added hexamethylphosphoric triamide the alkylation yields are increased and bromoalkanes also give satisfactory yields. The diastereomeric ratios are, however, much lower (d.r. 70 30 to 85 15)67. 

For the final step involving functionalization at N( ) of 62, anilide deprotonation with lithiated 4-benzyl-2-oxazolidinone as a base and alkylation with benzyl bromides again proved effective. Compared to the results obtained in the benzodiazepine series, the N( 1 )-alkylation reaction was generally found to proceed less smoothly with the 3,4-disubstituted quinox-alinones 62. Good results were obtained only if the resin batches were submitted twice to the alkylation conditions. Figure 3.4 displays a selection of structures (63-65) accessible from this first synthetic approach. In no case was there any evidence for racemization at the a-carbon atom of the amino acid. 

The acid is converted with thionyl chloride into the corresponding acid chloride, which reacts in a second step with the anion of the Lvans oxazolidinone 3714 to give an /V-acyloxazolidinone. This is then deprotonated with sodium hexamethyldisilazide and subsequently alkylated selectively with methyl iodide to produce compound 8. 

Deprotonation of O-alkyl carbamates may be achieved in an enantioselective manner with s-BuLi-(-)-sparteine, and the most effective of these reactions employ the oxazolidinones 411. The related compounds 412 perform similarly, but have less neat NMR spectra. Enantioselective lithiation of 413, followed by carboxylation and methylation with diazomethane, generates the protected a-hydroxy acid 414 in >95% ee.176 Many other electrophiles perform well in the quench step, but not allylic or benzylic halides, which lead to partial racemisation.177 30... 

Ghosh et al. reported that the chiral oxazolidinone 87, derived from (1S,2R)-cis-l-amino-2-indanol (86), underwent a highly diastereoselective. vyn-aldol reaction with a variety of aldehydes30 (Scheme 2.1cc). Reaction of the indanolamine 86 with disuccinyl carbonate in acetonitrile gave the oxazolidinone 87, which was deprotonated with -BuLi and reacted with propionyl chloride to provide the N-propionyl derivative 88. Reaction of 88 with n-BioBOTf and... 

S)-4-(l-Methylethyl)-5,5-diphenyl-2-oxazolidinone (3), whose preparation is described here, has several advantages over Evans original auxiliaries i) Derivatives of 3 are more likely to crystallize. In many cases the separation and purification of diastereoisomers can be achieved by simple recrystallization rather than by expensive and time-consuming chromatography, ii) Acylation of 3 can be carried out at 0°C (instead of-78°C for 4 and 5) by deprotonation with BuLi, followed by treatment with an activated carboxylic acid derivative, iii) Lithium enolates of N-acyl derivatives of 3 can be obtained directly by treatment with BuLi at -78°C, in comparison to 4 and 5 when the more expensive... 

Bicyclic oxazolidinones derived from carbohydrates have been used as chiral auxiliaries in conjugate addition reactions [147]. After deprotonation with MeMgBr, the D-galacto-oxazolidin-2-one 178 and the D-g/wc6>-oxazolidin-2-one 179 (Figure 10.17) were A-acylated with... 

Chiral oxazolidinone auxiliaries derived from D-xylose were applied by Koell et al. [156]. The oxazolidinones were acylated with various acid halides furnishing imides, which are substrates for a-alkylation reactions. For example, the butyric acid derivative 213 was deprotonated with LDA to give the (Z)-configured enolate 214, which was reacted with methyl iodide (Scheme 10.71). The methylated product 215 was formed in a moderate yield of 45% and a diastereomeric ratio of 7 1. The approach of the electrophile occurred from the less hindered /-face of the enolate... 

Matsumura and his coworkers [38] have employed the 2-pyrrolidone anion, in DMF solution, to deprotonate arylacetic acid esters with subsequent oxidative dimerization of the corresponding carbanions. This study includes a useful comparison between the electrochemical and chemical generation of the 2-pyrrolidone anion (by fluoride anion displacement in A-trimethylsilyl-2-pyrrolidone). The advantage lies with the electrochemical route, which gave yields of final product of 80%, compared with the 30% obtained with the chemically generated base (Scheme 10). The overall process, formation of dimethyl 2,3-diphenylsuccinates, is not only efficient and convenient but also operates with high diastereoselectivity when under the control of an oxazolidinone chiral auxiliary (Scheme 10). 

Evans s oxazolidinones 1.116 and 1.117 are a class of chiral auxiliaries that has been widely applied [160, 167, 261, 411]. Deprotonation of 7/-acyl-l,3-oxa-zolidin-2-ones 5 30 and 5.31 smoothly gives chelated Z-enolates, which then suffer alkylation between -78 and -30°C on their least hindered face [167, 1036]. After hydrolysis, the corresponding enantiomeric acids are obtained according to the auxiliary that was used (Figure 5.21). Due to the low reactivity of lithium enolates, sodium analogs are preferred in some cases [411, 862, 1036], This methodology has been applied to the synthesis of chiral a-arylpropionic acid anti-inflammatory drugs [1037, 1038], natural products [1039, 1040], and a-substituted optically active 3-lactams en route to nonracemic a,a-disubstituted aminoacids [136,1041]. 

Most metal enolates are generated by transmetalation from Li enoiates. However, Ti-enolates can be formed by action of TiCiyz -PrjNEt on carbonyl confounds [404,1042] and Zr-enolates can be generated by similar reactions with Zr(0-/ert-Bu)4 [1245], Lithium E-endates are obtained by deprotonation of ketones or esters with a branched Li-amide (LDA, LICA, LOB A, LTMP) in a weakly polar medium (THF or THF-hexane), while Z-enolates are formed by using LDA or LHMDS in the presence of HMPA or DPMU [1016], Tertiary amides always give Z-endates, and difunctionalized derivatives such as Evans s oxazolidinones 5.30 and 5.31 are chelated to the metal prior to enolization. 

Introduction of the auxiliary 52 to the substrate required the acylation of the oxazolidinone nitrogen with various carboxylic acids. Deprotonation and subsequent alkylation with different electrophiles (R2X) were performed. Through LiOOH mediated hydrolysis, the a-branched carboxylic acids 53 were obtained in 50-70% yield and enantiomeric excesses of 84—97% (Scheme 12.20). The resin-bound chiral auxiliary 52 could be recovered and recycled, thereby maintaining stereoselectivity. 

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 an extensive investigation, Seebach has developed a deprotonative chiral auxiliary approach with an oxazolidinone to provide a reagent for enantioselec-tive formylation of aldehydes and ketones [ 14-16]. Lithiation-substitution of 20 gives a diasteromeric mixture of 21, as representative examples, with the major diastereoisomer formed in drs greater than 70 30, and up to 95 5 in most cases. The separated diastereoisomers were converted to highly enantioenriched products via the hemiaminal and hydrolysis, as shown in the representative examples in Scheme 6. Additions to imine derivatives were also foimd to be possible in this approach [14-16]. 

The deprotonation of N—H bonds in diverse oxazoUdin-2-ones with KHMDS as the base followed by tbe treatment of tbe crade reaction mixtures with trimethylsilylethynyl iodonium triflate electrophiles afforded trimethylsilyl-terminated IV-ethynyl oxa-zolidinones in 50-60% yields (eq 74). Desilylation could be realized on the purified products or the crude reaction mixtures, and the alk)myl oxazolidinones were elaborated into novel stannyl enamines in the subsequent steps. In contrast, protocols employing -BuLi in toluene, or CS2CO3 in DMF gave yields lower than 20%. The procedure could be successfully applied to chiral oxazolidinones, since substitution at the C4 position of the oxazolidinones did not have a detrimental effect on reactivity. 

The chiral auxiliary is the oxazolidinone (24) derived from IS,2R) norephedrine. Acylation with propionyl chloride gives (25) and this is deprotonated to afford exclusively the internally chelated Z-enolate, which reacts with methallyl iodide from the face opposite the methyl and phenyl groups of the auxiliary. The product (26), a 97 3 mixture of diastereomers, is purified to a ratio of better than 500 1. Reductive removal of the auxiliary and careful oxidation of the primary alcohol under non-racemising conditions affords the chiral (5)-aldehyde (27). This in turn is reacted with the boron enolate of (25), which furnishes with remarkable selectivity the u aldol product (28). The reason for the choice of boron rather than lithium is to invert the facial selectivity of the reaction— the enolate is no longer constrained to be planar by internal chelation and rotates in order to place the bulky dibutyl borinyl group on the opposite side to the methyl and phenyl ... 

Computational studies of oxazolidinone-directed Nazarov cyclization show that the chiral oxazolidinone auxiliaries provide control over the torquoselectivity of 4n electrocyclic ring closure and the regioselectivity of subsequent deprotonation (Scheme 177). °... 

Copper-promoted aminations have recently been reported as a general strategy for the A-alkynylation of carbamates, sulfonates, and chiral oxazolidinones and imidazolidinones (eq 7). A variety of substituted ynamides can be synthesized via deprotonation of amides with KHMDS followed by reaction with copper(I) iodide and an alkynylbromide or iodide. 

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