Oxazolidinones boron enolates

I4 Boron enolates derived from oxazolidinone 3 arc reported to give either syn- or imp-adducts depending on the amounl of boryl Inflate and base employed, the character of the base, and the structure of the aldehyde see H. Danda, M. M. Hansen. C. H. Heathcock, J. Org. Chem. 55,173... 

Once again, excellent selectivity for formation of the j3-methyl isomer is observed in the case of the Lewis acid catalyzed reaction of the boron enolate of (4S )-4-isopropyl-3-(l-oxopropyl)-2-oxazolidinone 4177 (see Appendix). 

These oxazolidinones can be acylated and converted to the lithium, boron, tin, or titanium enolates by the same methods applicable to ketones and esters. For example, when they are converted to boron enolates using di-n-butylboron triflate and triethyl-amine, the enolates are the Z-stereoisomers.125... 

The reacting aldehyde displaces the oxazolidinone oxygen at the tetravalent boron in the reactive TS. The conformation of the addition TS for boron enolates is believed to have the oxazolidinone ring oriented with opposed dipoles of the ring and the aldehyde carbonyl groups. 

Reagent control This involves the addition of a chiral enolate or allyl metal reagent to an achiral aldehyde. Chiral enolates are most commonly formed through the incorporation of chiral auxiliaries in the form of esters, acyl amides (oxazolines), imides (oxazolidinones) or boron enolates. Chiral allyl metal reagents are also typically joined with chiral ligands. 

The chiral A/ -propionyl-2-oxazolidones (32 and 38) are also useful chiral auxiliaries in the enantioselective a-alkylation of carbonyl compounds, and it is interesting to observe that the sense of chirality transfer in the lithium enolate alkylation is opposite to that observed in the aldol condensation with boron enolates. Thus, whereas the lithium enolate of 37 (see Scheme 9.13) reacts with benzyl bromide to give predominantly the (2/ )-isomer 43a (ratio 43a 43b = 99.2 0.8), the dibutylboron enolate reacts with benzaldehyde to give the (3R, 25) aldol 44a (ratio 44a 44b = 99.7 0.3). The resultant (2R) and (25)-3-phenylpropionic acid derivatives obtained from the hydrolysis of the corresponding oxazolidinones indicated the compounds to be optically pure substances. 

The control of the three consecutive asymmetric centers in a-alkylated y-amino-p-hydroxy acids is achieved by aldol condensation of a chiral aldehyde and a chiral reagent (Scheme 17 and Table 6), e.g. boron enolate 43,150 79 oxazolidinones of Evans type lit80 or 45 [68>69>801 or Brown s or Roush s crotylorganoboron reagents 46[81 and 47J81,82 respectively. 

The approach for the enantioselective aldol reaction based on oxazolidinones like 22 and 23 is called Evans asymmetric aldol reaction.14 Conversion of an oxazolidinone amide into the corresponding lithium or boron enolates yields the Z-stereoisomers exclusively. Reaction of the Z-enolate 24 and the carbonyl compound 6 proceeds via the cyclic transition state 25, in which the oxazolidinone carbonyl oxygen and both ring oxygens have an anti conformation because of dipole interactions. The back of the enolate is shielded by the benzyl group thus the aldehyde forms the six-membered transition state 25 by approaching from the front with the larger carbonyl substituent in pseudoequatorial position. The... 

It has been demonstrated that optically active oxetanes can be formed from oxazolidinone 92, a crotonic acid moiety functionalized with Evans chiral auxiliary (Scheme 18) <1997JOC5048>. In this two-step aldol-cyclization sequence, the use of 92 in a deconjugative aldol reaction, with boron enolates and ethanal, led to formation of the syn-aldol 93. This product was then converted to the corresponding oxetanes, 94a and 94b, via a cyclization with iodine and sodium hydrogencarbonate. This reaction sequence was explored with other aldehydes to yield optically active oxetanes in similar yields. Unlike previous experiments using the methyl ester of crotonic acid, in an analogous reaction sequence rather than the oxazolidinone, there was no competing THF formation. 

In 1992 Ghosh and co-workers provided the first example of the utility of rigid cis-1 -amino-2-indanol-derived oxazolidinone 36 as the chiral auxiliary in the asymmetric. vv//-aldol reaction.60-61 Aldol condensation of the boron enolate of 37 with various aldehydes proceeded with complete diastereofacial selectivity. Effective removal and recovery of the chiral auxiliary was carried out under mild hydrolysis conditions (Scheme 24.6). As both enantiomers of the chiral auxiliary were readily available, both enantiomers of the. yyn-aldol could be prepared with equal asymmetric induction. 

Hexafluoroacetone has also demonstrated unusual reactivity when condensed with the boron cnolatc of an optically active oxazolidinone or the boron enolate of the sultam derived from camphorsulfonic acid s to give products 3 and 4, respectively. The absolute stereochemistry of the products 3 and 4 is the opposite of that formed on addition to nonfluorinated ketones and aldehydes. This change was attributed to the involvement of an open transition state in the aldol reaction, a consequence of the diminished basicity of fluorinated carbonyl oxygens. 

As above (eq 1), a major drawback of this reagent is the lack of a readily available enantiomer. There are many alternative methods for the enantioselective propionate aldol reaction. The most versatile chirally modified propionate enolates or equivalents are N-propionyl-2-oxazolidinones, a-siloxy ketones, boron enolates with chiral ligands, as well as tin enolates. Especially rewarding are new chiral Lewis acids for the asymmetric Mukaiyama reaction of 0-silyl ketene acetals. Most of these reactions afford s yw-aldols good methods for the anri-isomers have only become available recently. ... 

The chiral oxazolidinone auxiliaries introduced by Koell et al. [158] were used for halogenation reactions of various imides. The imide 223 was transformed into a boron enolate and reacted with NCS as the electrophile (Scheme 10.74). The (5)-configured a-chloro imide 224 was obtained in moderate yield with a diastereomeric ratio of 4 1. As in the alkylation reactions described above, an inversion of the stereoselectivity was observed for phenylacetimides. 

Chiral oxazolidinone auxiliaries based on D-glucose were used for aldol reactions by Koell et al. [160]. The highest select vities were observed with auxiliaries equipped with the pivaloyl protecting group. The pivaloylated oxazolidinone 228 was transformed into the boron enolate according to the procedure of Evans [161] and subsequently reacted with aliphatic and aromatic aldehydes. The best results were obtained with isobutyric aldehyde (Scheme 10.77). The syn-dldo 229 was formed in 16-fold excess over the a/i Z-diastereomer and with an acceptable yield of 59%. The authors explain the stereoselectivity by a chair-like transition state according to Zimmermann-Traxler. The electrophile approaches at the less hindered r -face of the (Z)-configured enolate double bond. For A -phenacetyl substituents, an inversed stereoselectivity was observed as described above for these oxazolidinone auxiliaries. 

Treatment of N-acyloxazolidinones with di-n-butylboron triflate in the presence of Et3N furnishes the (Z)-(O) boron enolates. These on treatment with aldehydes give the corresponding 2,3-syn aldol products (the ratio of syn- to anti- isomers is typically 99 1 ). On hydrolysis they produce chiral a-methyl-(3-hydroxy carboxylic acids, as exemplified below. The facial selectivity of the chiral boron enolate is attributed to the favored rotomeric orientation of the oxazolidinone carbonyl group, where its dipole is opposed to the enolate oxygen dipole. At the Zimmerman-Traxler transition state, the aldehyde approaches the oxazolidinone appendage from the face of the hydrogen rather than from the benzyl substituent. 

The Nicholas reaction was used to synthesize the p-lactam precursor of thienamycin in the laboratory of P.A. Jacobi and thereby accomplish its formal total synthesis. The necessary p-amino acid was prepared by the condensation of a boron enolate (derived from an acylated oxazolidinone) with the cobalt complex of an enantiopure propargylic ether. The resulting adduct was oxidized with ceric ammonium nitrate (CAN) to remove the cobalt protecting group from the triple bond, and the product was obtained with a 17 1 anti.syn selectivity and in good yield. 

We (Novartis) reported the first enantioselective synthesis of (27 ,2 7 )-(+)-f/7reo-methylphenidate hydrochloride (1), which involved an asymmetric aldol condensation of 5-chlorovaleraldehyde with the (Z)-boron enolate derived from 7V-phenylacetyl-(7 )-4-phenyl-2-oxazolidinone (29) as the key step to generate both stereogenic centers of 1 with desired absolute configuration (Scheme ll). ... 

Reaction of 5-chlorovaleraldehyde with the (Z)-boron enolate derived from 7V-phenylacetyl-(71)-4-phenyl-2-oxazolidinone (29) afforded the desired single diastereomer 30, as confirmed by H NMR, in 78%... 

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

The boron enolate of the starting material 102 reacts with an aldehyde such as PhCHO to give 103 with excellent selectivity the induction from the oxazolidinone to the methyl group is near perfect and the relative stereochemistry of the aldol11 is >500 1. Hydrolysis gives the hydroxy-acid 104 in nearly 100% ee and recovered auxiliary 87. 

Acetylenic cobalt complexes greatly facilitate the heterolytic cleavage of adjacent alcohols or ethers. On treatment with Lewis acids, these complexes afford cobalt stabilized carbenium ions, which can be captured by nucleophiles such as enolates. Jacobi and Zheng have employed chiral boron enolates of Evans s oxa-zolidinone 6.91 (R = i-Pr). After removal of the chiral auxiliary, they obtained anti adds 11.43 with a high selectivity [1677] (Figure 11.9). The reaction can be extended to the boron enolates of related oxazolidinones and to a-branched propargyl derivatives. This reaction has been applied to the synthesis of P-aminoacids after Curtius rearrangement and oxidation of the triple bond [1677]. 

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