Borane chirally modified

Nonmetallic systems (Chapter 11) are efficient for catalytic reduction and are complementary to the metallic catalytic methods. For example lithium aluminium hydride, sodium borohydride and borane-tetrahydrofuran have been modified with enantiomerically pure ligands161. Among those catalysts, the chirally modified boron complexes have received increased interest. Several ligands, such as amino alcohols[7], phosphino alcohols18 91 and hydroxysulfoximines[10], com-plexed with the borane, have been found to be selective reducing agents. 

In the asymmetric reduction of ketones, stereodifferentiation has been explained in terms of the steric recognition of two substituents on the prochiral carbon by chirally modified reducing agents40. Enantiomeric excesses for the reduction of dialkyl ketones, therefore, are low because of the little differences in the bulkiness of the two alkyl groups40. In the reduction of ketoxime ethers, however, the prochiral carbon atom does not play a central role for the stereoselectivity, and dialkyl ketoxime ethers are reduced in the same enantiomeric excess as are aryl alkyl ketoxime ethers. Reduction of the oxime benzyl ethers of (E)- and (Z)-2-octanone with borane in THF and the chiral auxiliary (1 R,2S) 26 gave (S)- and (R)-2-aminooctane in 80 and 79% ee, respectively39. 

The conjugate addition of phosphorus nucleophiles of various oxidation states and in neutral or metallated form constitutes an efficient and well-known method for C—P bond formation [30]. In the case of phosphanes as nucleophiles especially, the corresponding phosphane-borane adducts have been used in 1,4-additions to Michael acceptors. Following the idea to use a chirally modified phosphorus nucleophile in asymmetric Michael additions to aromatic nitroalkenes, we synthesized the new enantiopure phospite 45 starting from TADDOL (44) with nearly quantitative yield. Due to the C2 symmetry, of the... 

Asymmetric Reduction with Chirally Modified Boranes and Alanes 170... 

Another chirally modified Lewis acid catalyst used in the borane reduction is the chiral lanthanum alkoxide [114]. The reaction of lanthanum triisopropoxide with enantiopure binaphthol gave a catalyst system for the borane reduction of ketones. Reduction of 6 -methoxy-2 -acetonaphtone gave the corresponding secondary alcohol in 100% yield with 61.8% ee (S) [114]. 

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. 

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... 

Figure 1.39 Chiral amine synthesis using modified boranes.

Borane and aluminum hydrides modified by chiral diols or amino alcohols are well-known, effective reagents for the stoichiometric enan-tioselective reduction of prochiral ketones and related compounds (34). Reduction of prochiral aromatic ketones with the Itsuno reagent, which is prepared from a chiral, sterically congested /3-amino alcohol and borane, yields the corresponding secondary alcohols in 94-100% ee... 

The oxazolidin-2-ones 53 (R = H=CCH=CH2 or COEt) are obtained in a one-pot reaction of amino alcohol carbamates 52 with sodium hydroxide, followed by allyl bromide or propi-onyl chloride (94TL9533). A modified procedure for the preparation of chiral oxazolidin-2-ones 56 from a-amino acids 54, which avoids the hazardous reduction of the acids with borane and the intermediacy of water-soluble amino alcohols, is treatment of the methyl ester of the amino acid with ethyl chloro-formate to give 55, followed by reduction with sodium borohydride and thermal ring-closure of the resulting carbamate f95SC561). The 2-prop-ynylcarbamates 57 (R = Ts, Ac, Bz, Ph or allyl) cyclize to the methyleneoxazolidinones 58 under the influence of silver cyanate or copper(I) chloride/triethylamine (94BCJ2838). 

Researchers at Sepracor later disclosed the use of a new class of chiral oxazaborolidines derived from r/. v-aminoindanol in the enantioselective borane reduction of a-haloketones.6,7 The 5-hydrogen oxazaborolidine ligand 10 was prepared in situ from d,v-aminoindanol 1 and BH3 THF.8 Stock solutions of 5-methyl oxazaborolidine 11-16 were obtained by reaction of the corresponding N-alkyl aminoindanol with trimethyl boroxine.6,7 5-Methyl catalyst 11 was found to be more selective (94% ee at 0°C) than the 5-hydrogen catalyst 10 (89% ee at 0°C), and enantioselectivities with 11 increased at lower temperatures (96% ee at -20°C). The catalyst structure was modified by introduction of A-a I kyI substituents. As a general trend, reactivities and selectivities decreased as the steric bulk or the chelating ability of the A -alkyl substituent increased (Scheme 17.4). 

There are a number of different approaches to performing enantioselective reductions of ketones within the flow domain, using either a borane-derived hydride transfer agent such as that described previously or modified transition metal hydrogenations an example of the latter involved a column of Pt/Al203 modified with O-methyl cinchonidine (21) to induce chirality in the product (Scheme 4.64). Continuous monitoring showed that a 30 min induction period was required before the optimal reaction rate and ee could be obtained. This was ascribed to the need for... 

Chiral oxazoborolidine systems have been regularly used as catalysts for the enantioselective Diels-Alder reaction [173]. Such a catalyst has been immobilized by copolymerization of a sulfonamide-modified styrene monomer to produce polystyrene beads and subsequently reacted with borane to furnish catalyst 49 (Scheme 4.77). A column of 49 was cooled to —30 °C and a 1 1.5 methylacrolein cyclopentadiene solution was flowed in. Following aqueous workup and column chromatography, the desired product 50 was isolated to yield 138 mmol of product in 95% yield and 71% ee by using only 5.7 mmol of catalyst. This result was found to be comparable with the heterogeneous batch reactions that were also attempted [174]. 

Reduction of C=0 and C=N Bonds. Asymmetric reductions of prochiral ketones (19) to the corresponding chiral alcohols (20) using (S)-proline-modified borohydride reagents as the reductant have been published. The borane reductions of ketones (19) employing (S)-proline as chiral mediator proceeds with enantiomeric... 

Chiral modification is not limited to boronate and aluminate complexes. Boranes or alanes are partially decomposed with protic substances such as chiral amines, alcohols or amino alcohols to form useful reagents for enantioselective reduction of carbonyl compounds. For example, reduction of acetophenone with borane modified with the amines (65) to (67) gives (5)-l-phenylethyl alcohol with 3.5-20%... 

The first attempt to use a chiral ligand to modify borane was Kagan s attempt at enantioselective reduction of acetophenone using amphetamine-borane and desoxy-ephedrine-borane in 1969 [18]. However, both reagents afforded 1-phenyl ethanol in <5% ee. The most successful borane-derived reagents are oxazaborolidines, introduced by Hirao in 1981, developed by Itsuno, and further developed by Corey several years later (reviews [19,20]). Figure 7.2 illustrates several of the Hirao-Itsuno and Corey oxazaborolidines that have been evaluated to date. All of these examples are derived from amino acids by reduction or Grignard addition. Hirao... 

Asymmetric, borane-modified MPV reduction of a variety of aromatic ketones to their corresponding alcohols has recently (43) been reported using a chiral aluminum alkoxide catalyst shown in Figure 5. This compound was formed in situ from aluminum isopropoxide and (R)-l,r-binapthyl-diol in... 

Deprotonation of t-Bu-BisP (BH3)2 with 1.2 equivalents of s-BuLi/( )-sparteine formed a mixture of mono- and dilithiated t-Bu-BisP (BH3)2 whose - intermolecular oxidative coupling with Cu(II) afforded a mixture of tetraphosphine borane 86 and hexaphosphine borane 87. The use of ( )-sparteine may surprise the reader, as the reaction does not involve any enantioselective deprotonation. However, it was found that its presence was beneficial to activate the -BuLi, showing that ( )-sp is not only a chiral inductor, but also modifies the reactivity of the organolithium reagents. After separation by column chromatography, 86 and 87 were obtained in 26% and 14% isolated yields respectively. Tetraphosphine borane 86 was subjected to similar reactions, affording compounds 88 (29% yield) and 90 (8% yield), which contain 8... 

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