Ketones oxazaborolidines

Enantioselective Reduction of Oxime 0-Ethers. In addition to the reduction of prochiral ketones, oxazaborolidine (3) has been used (both stoichiometrically and catalytically with borane-THF) to catalyze the enantioselective reduction of prochiral ketoxime O-ethers to the corresponding amine (eq Unlike the ketone reduction described above, the... 

Halo-substituted acetophenones such as m-bromo- [74] or p-chloroacetophe-none [46] were reduced with borane in high enantioselectivity in the presence of oxazaborolidines 4b and 47, respectively. Other important halogen-containing ketones are chloromethyl or bromomethyl ketones. Oxazaborolidine reduction of co-chloro- or co-bromoacetophenone gives enantio-enriched halohydrins that can be converted into chiral oxiranes [20]. Martens found that the sulfur-containing oxazaborolidine catalysts 60 show high enantioselectivity in this kind of reduction [44, 86, 87]. Enantiopure halohydrins were obtained as shown in Scheme 8. 

Enantioselective reductions of prochiral ketones by means of oxazaborolidines 97CLY9. 

Recent advances in the asymmetric catalytic reduction of ketones using chiral oxazaborolidines as ligands 98MI64. 

An expedient and stereoselective synthesis of bicyclic ketone 30 exemplifies the utility and elegance of Corey s new catalytic system (see Scheme 8). Reaction of the (R)-tryptophan-derived oxazaboro-lidine 42 (5 mol %), 5-(benzyloxymethyl)-l,3-cyclopentadiene 26, and 2-bromoacrolein (43) at -78 °C in methylene chloride gives, after eight hours, diastereomeric adducts 44 in a yield of 83 % (95 5 exo.endo diastereoselectivity 96 4 enantioselectivity for the exo isomer). After reaction, the /V-tosyltryptophan can be recovered for reuse. The basic premise is that oxazaborolidine 42 induces the Diels-Alder reaction between intermediates 26 and 43 to proceed through a transition state geometry that maximizes attractive donor-acceptor interactions. Coordination of the dienophile at the face of boron that is cis to the 3-indolylmethyl substituent is thus favored.19d f Treatment of the 95 5 mixture of exo/endo diastereo-mers with 5 mol % aqueous AgNC>3 selectively converts the minor, but more reactive, endo aldehyde diastereomer into water-soluble... 

The aziridine carbinols are also effective ligands in the preparation of oxazaborolidine catalysts for the asymmetric ketone reduction with borane (Fig. 4) [551. 

Other S/N ligands have been investigated in the enantioselective catalytic reduction of ketones with borane. Thus, Mehler and Martens have reported the synthesis of sulfur-containing ligands based on the L-methionine skeleton and their subsequent application as new chiral catalysts for the borane reduction of ketones." The in situ formed chiral oxazaborolidine catalyst has been used in the reduction of aryl ketones, providing the corresponding alcohols in nearly quantitative yields and high enantioselectivities of up to 99% ee, as shown in Scheme 10.60. 

Catalytic Enantioselective Reduction of Ketones. An even more efficient approach to enantioselective reduction is to use a chiral catalyst. One of the most developed is the oxazaborolidine 18, which is derived from the amino acid proline.148 The enantiomer is also available. These catalysts are called the CBS-oxazaborolidines. 

Scheme 5.6. Enantioselective Reduction of Ketones Using CBS-Oxazaborolidine... 

Another soluble polymer-enlarged catalyst was synthesized and tested by Wandrey et a/.[57] The catalyst was prepared by a coupling of an oxazaborolidine via a hydrosilylation reaction to a methyl hydrosiloxane-dimethylsiloxane copolymer (Figure 4.40). The catalyst was used in the enantioselective borane reduction of ketones. 

The use of such an oxazaborolidine system in a continuously operated membrane reactor was demonstrated by Kragl et /. 58] Various oxazaborolidine catalysts were prepared with polystyrene-based soluble supports. The catalysts were tested in a deadend setup (paragraph 4.2.1) for the reduction of ketones. These experiments showed higher ee s than batch experiments in which the ketone was added in one portion. The ee s vary from 84% for the reduction of propiophenone to up to >99% for the reduction of L-tetralone. The catalyst showed only a slight deactivation under the reaction conditions. The TTON could be increased from 10 for the monomeric system to 560 for the polymer-bound catalyst. 

Boranes have opened the door to asymmetric reduction of carbonyl compounds. The first attempt at modifying borane with a chiral ligand was reported by Fiaud and Kagan,75 who used amphetamine borane and desoxyephedrine borane to reduce acetophenone. The ee of the 1-phenyl ethanol obtained was quite low (<5%). A more successful borane-derived reagent, oxazaborolidine, was introduced by Hirao et al.76 in 1981 and was further improved by Itsuno and Corey.77 Today, this system can provide high stereoselectivity in the asymmetric reduction of carbonyl compounds, including alkyl ketones. 

Oxazaborolidine catalysts behave like an enzyme in the sense of binding with both ketone and borane, bringing them close enough to undergo reaction and releasing the product after the reaction. Thus these compounds are referred to as chemzymes by Corey.78 The oxazaborolidines listed in Figure 6-6 are representative catalysts for the asymmetric reduction of ketones to secondary alcohols. 

Addition of triethylamine to the oxazaborolidine reaction system can significantly increase the enantioselectivity, especially in dialkyl ketone reductions.79 In 1987, Corey et al.80 reported that the diphenyl derivatives of 79a afford excellent enantioselectivity (>95%) in the asymmetric catalytic reduction of various ketones. This oxazaborolidine-type catalyst was named the CBS system based on the authors names (Corey, Bakshi, and Shibata). Soon after, Corey s group81 reported that another fi-methyl oxazaborolidine 79b (Fig. 6-6) was easier to prepare and to handle. The enantioselectivity of the 79b-catalyzed reaction is comparable with that of the reaction mediated by 79a (Scheme 6-36).81 The -naphthyl derivative 82 also affords high enantioselectivity.78 As a general procedure, oxazaborolidine catalysts may be used in 5-10 mol%... 

Figure 6-6. Representative oxazaborolidines for the asymmetric reduction of prochiral ketones.

New chiral oxazaborolidines that have been prepared from both enantiomers of optically active inexpensive a-pinene have also given quite good results in the asymmetric borane reduction of prochiral ketones.92 Borane and aromatic ketone coordinate to this structurally rigid oxazaborolidine (+)- or (—)-94, forming a six-membered cyclic chair-like transition state (Scheme 6-41). Following the mechanism shown in Scheme 6-37, intramolecular hydride transfer occurs to yield the product with high enantioselectivity. With aliphatic ketones, poor ee is normally obtained (see Table 6-9). 

The reduction of dialkylketones and alkylaryl ketones is also conveniently accomplished using chiral oxazaborolidines, a methodology which emerged from relative obscurity in the late 1980s. The type of borane complex (based on (,V)-diphenyl prolinol)[39] responsible for the reductions is depicted below (10). Reduction of acetophenone with this complex gives (/ )-1 -phenylethanol in 90-95% yield (95-99% ee) [40]. Whilst previously used modified hydrides such as BiNAL-H (11), which were used in stoichiometric quantities, are generally unsatisfactory for the reduction of dialkylketones, oxazaborolidines... 

Enantioselective reduction of ketones using n-arylsulfonyl oxazaborolidines... 

ENANTIOSELECTIVE REDUCTION OF KETONES USING N-ARYLSULFONYL OXAZABOROLIDINES... 

Chiral oxazaborolidines. Enantioselective reduction of ketones with a reagent prepared from BH, and the chiral vic-amino alcohol 1 (12,31) is now known to involve an oxazaborolidine. Thus BH3 and (S)-l, derived from valine, react rapidly in THF to form 2, m.p. 105-110°, which can serve as an efficient catalyst... 

Enantioselective reduction of ketones.1 The ability of diborane in combination with the vic-amino alcohol (S)-2-amino-3-methyl-l,l-diphenyl-l-butanol (12, 31) to effect enantioselective reduction of alkyl aryl ketones involves formation of an intermediate chiral oxazaborolidine, which can be isolated and used as a catalyst for enantioselective borane reductions (equation I). 

Surface modification of skeletal nickel with tartaric acid produced catalysts capable of enantiose-lective hydrogenation [85-89], The modification was carried out after the formation of the skeletal nickel catalyst and involved adsorption of tartaric acid on the surface of the nickel. Reaction conditions strongly influenced the enantioselectivity of the catalyst. Both Ni° and Ni2+ have been detected on the modified surface [89]. This technique has already been expanded to other modified skeletal catalysts for example, modification with oxazaborolidine compounds for reduction of ketones to chiral alcohols [90],... 

As an example of non-enzymatic catalyst using oxazaborolidines [10], Corey and his associates have described an efficient synthesis of (-i-)-l(S),5(R),8(S)-8-phenyl-2-azabicyclo[3.3.0]octan-8-ol (2.) and its enantiomer. The B-methyloxazaborolidine derivatives (3) of these amino alcohols are excellent catalysts -or chemzymes- for the enantioselective reduction of a variety of achiral ketones to chiral secondary alcohols [11]. 

Enantioselective borane reduction of ketones catalyzed by chiral oxazaborolidines. 

Borane reduction catalyzed by chiral oxazaborolidines (CBS reduction, CBS = Corey, Bakshi, and Shibata) exhibits excellent enantio- and chemoselectiv-ity for a wide variety of ketonic substrates (Figure 1.27). This reaction was originally developed as a stoichiometric system consisting of diphenylvalinol and borane, ° but was later extended to a useful catalytic method. Because of the high efficiency of this reaction, many chiral oxazaborolidines have been synthesized from p-amino alcohols.Among them the prolinol-derived oxazaboro-lidine is one of the most widely used catalysts. ... 

Figure 1.27. Asymmetric reduction of ketones with borane catalyzed by oxazaborolidines.

Scheme 5.4. Enantionselective Reduction of Ketones Using Oxazaborolidine Catalyst... 

The CBS-reduction [137] of prochiral ketones is a well-known process which employs a chiral oxazaboroHdine as catalyst and BHs-THF or catecholborane as stoichiometric reductants. It is believed that the active catalytic species is a LLA, resulting from coordination of the oxazaborolidine nitrogen with the boron reagent to render the oxazaborolidine boron atom highly Lewis acidic [87]. Similarly, Corey... 

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