Binaphthols reduction

Just as selective oxidation can be carried out on these systems, reduction also occurs with considerable selectively. Hydrogenation of binaphthol (Pd catalyst) in glacial acetic acid at room temperature for seven days affords the octahydro (bis-tetrahydro) derivative in 92% yield with no apparent loss of optical activity when the reaction is conducted on optically pure material. The binaphthol may then be converted into the bis-binaphthyl crown in the usual fashion. 

Finally, the use of S/P ligands derived from (i )-binaphthol has been considered by Gladiali et al. in the asymmetric rhodium-catalysed hydrogen-transfer reduction of acetophenone performed in the presence of i-PrOH as the hydrogen donor.It was noted that racemisation occurred when the reaction time increased and consequently the corresponding alcohol was obtained in only low enantioselectivities (< 5% ee) as shown in Scheme 9.21. Similar results were more recently reported by these authors by using iridium combined with the same ligands. ... 

Pu and co-workers incorporated atropisomeric binaphthols in polymer matrixes constituted of binaphthyl units, the macromolecular chiral ligands obtained being successfully used in numerous enantioselective metal-catalyzed reactions,97-99 such as asymmetric addition of dialkylzinc reagents to aldehydes.99 Recently, they also synthesized a stereoregular polymeric BINAP ligand by a Suzuki coupling of the (R)-BINAP oxide, followed by a reduction with trichlorosilane (Figure 10).100... 

Another method for ketone reduction, BINAL-H asymmetric reduction, can also be used in co-side chain synthesis. An example of applying BINAL-H asymmetric reduction in PG synthesis is illustrated in Scheme 7-27. This has been a general method for generating the alcohol with (15. -configuration. The binaphthol chiral auxiliary can easily be recovered and reused. As shown in Scheme 7-27, when the chiral halo enone 91 is reduced by (S -BINAL-H at — 100°C, product (15S)-92 can be obtained with high enantioselectivity. 

Recently, Schaumann et al. 153,154 an(j Bienz et tf/.155,156 have developed dependable routes for the resolution of racemic functionalized organosilanes with Si-centered chirality using chiral auxiliaries, such as binaphthol (BINOL), 2-aminobutanol, and phenylethane-l,2-diol (Scheme 2). For instance, the successive reaction of BINOL with butyllithium and the chiral triorganochlorosilanes RPhMeSiCl (R = /-Pr, -Bu, /-Bu) affords the BINOL monosilyl ethers 9-11, which can be resolved into the pure enantiomers (A)-9-ll and (7 )-9-11, respectively. Reduction with LiAlFF produces the enantiomerically pure triorgano-H-silanes (A)- and (R)-RPhMeSiH (12, R = /-Pr 13, -Bu 14, /-Bu), respectively (Scheme 2). Tamao et al. have used chiral amines to prepare optically active organosilanes.157... 

It was discovered by J. C. Saddler and co-workers at Upjohn that for reproducible results it was necessary to reflux the mixture of binaphthol, UiAIH4, and EtOH before performing the reduction. Enantioselective reduction of the acyl stannane can also be effected with Chirald, albeit with slightly diminished enantioselectivity.2... 

In this context, a chiral hydride reagent, BINAL-H, prepared by modification of lithium aluminum hydride with equimolar amounts of optically pure binaphthol and a simple alcohol, is extremely useful (9b, 18a, 35) Scheme 15 shows the utility of the three-component coupling synthesis. The < > side-chain unit and the hydroxycyclopentenone can be prepared with very high enantioselectivity by reduction of the corresponding enone precursors (35-38). 

The utility of the BINAL-H asymmetric reduction in other PG syntheses is shown in Scheme 16 (35, 39). This asymmetric reduction is a general method for generating the 15S configuration and is highly practical, because the binaphthol ancillary is easily recovered in reusable form from the reaction mixture. In fact, this reduction is undertaken on a multikilogram scale in the Corey synthesis (Ono Pharmaceutical Co.). The observed high diastereoselectivity leading to the desired 155... 

Asymmetric reduction of alkyl aryl ketones with trialkoxysilanes is promoted by a catalytic amount of chiral nucleophiles [39]. The reactive species is a transiently prepared hypervalent silicon hydride. 2, 4, 6 -Trimethylacetophenone was reduced with equimolecular amounts of trimethoxysilane in the presence of the monolithio salt of (R)-BINAPHTHOL (substrate Li=20 l) in a 30 1 ether-TMEDA mixed solvent at 0 °C to afford the R product in 90% ee (Scheme 21) [40]. The presence of TMEDA was crucial to achieve high yield and enantiose-lectivity. Reduction of less hindered ketonic substrates preferentially gave the... 

Kagan and Schiffers carefully studied the effect of the lithium salts of BINOL (17) and related axially chiral binaphthols on the reduction of a variety of ketones with trialkoxysilanes [24]. They found that diethyl ether, with TMEDA as an additive, was the best solvent for asymmetric reduction of ketones. In the presence of 5 mol% of the monolithium salt of BINOL (17), acetophenone (1) could be reduced with trimethoxysilane in 80% yield and with 61% ee. Enantiomeric excesses > 90% were achieved under the same conditions with 2, 4, 6 -trimethyl-acetophenone (18) or a-tetralone (19) as substrates. Aliphatic ketones such as... 

Enantioselective reduction of ketones. Marshall et al.1 report that more consistent results obtain when BINAL-H is prepared by refluxing a mixture of the binaphthol, LiAlH4, and ethanol in THF for a short time before use. They also note that the expensive binaphthol can be recovered and reused. 

Al complexes prepared in situ from Al[OCH(CH3)2]3 and two equivalents of (K)-BINAPHTHOL (9) and (i )-H8-BINAPHTHOL (10) promoted the enanti-oselective reduction of propiophenone with borane-dimethyl sulfide and gave the S alcohol in 83% and 90% ee, respectively (Scheme 7) [47]. The reaction was much slower and afforded a racemic product in the absence of Al[OCH(CH3)2]3 under otherwise identical conditions. The addition of a catalytic amount of Al(OC2H5)3 increased both the rate and enantioselectivity in the hydroboration of ketones with a chiral amino alcohol [48]. 

The chiral BINAPHTHOL derivative (H)-ll and two equivalents of Zn(C2H5)2 produced an active catalyst for the asymmetric reduction of acetophenone with... 

In 1979, Noyori and co-workers invented a new type of chiral aluminum hydride reagent (1), which is prepared in situ from LiAlEE, (S)-l, E-bi-2-naphthol (BINOL), and ethanol. The reagent, called binaphthol-modified lithium aluminum hydride (BINAL-H), affects asymmetric reduction of a variety of phenyl alkyl ketones to produce the alcohols 2 with very high to perfect levels of enantioselectivity when the alkyl groups are methyl or primary1 (Scheme 4.3a). 

The binaphthol-modified lithium aluminum hydride reagents (BINAL-Hs) are also effective in enantioselective reduction of a variety of alkynyl and alkenyl ketones2 (Scheme 4.3b). When the reaction is carried out with 3 equivalents of (S)-BINAL-H at —100 to —78 C, the corresponding propargylic alcohol 3 and allylic alcohol 4 are obtained in high chemical yields with good to excellent levels of enantioselectivity. As is the case with aryl alkyl ketones, the alcohols with (.V)-con figuration are obtained when (S)-BINAL-H is employed. 

The racemic acid can be resolved by crystallization of the salt of (+ )-l with cinchonine. The optically pure acids are useful for resolution of amines. Reduction of the corresponding methyl esters provides a particularly useful route to (S)-( -)- and (R)-( + )-binaphthol (9, 169-170). ... 

Chiral Ligand of LiAlH4 for the Enantioselective Reduction of a,p-Unsaturated Ketones. Enantioselective reductions of a,p-unsaturated ketones afford optically active ally lie alcohols which are useful intermediates in natural product synthesis. Enantioselective reduction of a,p-unsaturated ketones with LiAlH4 modified with chiral amino alcohol (1) affords optically active (S)-allylic alcohols with high ee s. When 2-cyclohexen-l-one is employed, (5)-2-cyclohexen-l-ol with 100% ee is obtained in 95% yield (eq 2). This is comparable with the results obtained using LiAlH4-chiral binaphthol and chiral 1,3,2-oxazaborolidine. ... 

Reduction of acetophenone with the LAH complexes of nitrogen analogs of binaphthol, (/ )-(23) and (5)-(24), affords (R)-l-phenylethyl alcohol in 43% ee and 46% ee, respectively. Optical yields for the reduction of other prochiral ketones are similarly moderate. 

Sih (38) has described the reduction of E-l-iodo-l-octen-3-one with Penicillium decumbens to give the desired S-alcohol. Based on optical rotation, the e.e. was about 80%, An asymmetric chemical reduction of this same ketone, using lithium aluminum hydride that had been partially decomposed by one mole each of S-2,2 -dihydroxy-l,T-binaphthol and ethanol (42), gave the desired alcohol in 97% e.e. This reagent also reduced l-octyn-3-one in 84% e.e. to the corresponding alcohol (43). A 92% e.e. could be obtained with B-3-pinanyl-9-borabicyclo[3.3.1]nonane as the reducing agent (44). 

Two asymmetric synthesis approaches to chiral cyclopentenone derivatives can be envisaged. The first, reduced to practice by Noyori (43), involved reduction of cyclopentene-l,4-dione with lithium aluminum hydride chirally modified with binaphthol to give R-4-hydroxycyclopent-2-en-l-one in 94% e.e. Alternatively, manganese dioxide oxidation of allylic alcohol [40] (Fig. 7), in analogy to the cis isomer (54), would be expected to give the same enone. 

Reduction of (S)-(+)- and (R)-(-)-BNP methyl esters or acids by lithium aluminum hydride, or by Red-Al (this volume, p. 13) yields (S)- -)-and (R)-(+)-binaphthol, respectively. This is, at present, the most convenient access to optically active binaphthols, used by Cram and co-workers to prepare macrocyclic polyethers and by Japanese authors in asymmetric synthesis of cyclic binaphthyl-esters. 

Borane in the presence of (/ )-binaphthol-La(0-i-Pr)3 reduces various ketones but with a low ee [ZYl]. Other chiral boranes can be used to carry out enantioselec-tive reductions [ACl, BP2, BR4, DS5, M2, NNl, S3, S4], but the transferred hydride comes from the carbon skeleton therefore, these reagents are outside the scope of this book. 

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]. 

JR)- and (S)-binaphthols 1.44 [230-235] have sometimes been used as chiral auxiliaries. Examples include reduction of y-ketoester 1.45 [236], nucleophilic substitution of binaphthol ethers (G = binaphthol) 1.46, by organomagnesium reagents, organocuprate additions to binaphthol monodnnamates [237], and alkylations of arylacetic or crotonic esters [238,239]. 

---