Borane reductions, alcohols from

Di(isopinocampheyl)borane Sec. alcohols from ketones Asym. reduction... 

Reductions with pyridine borane Prim, alcohols from aldehydes... 

Since the discovery of the CBS catalyst system, many chiral //-amino alcohols have been prepared for the synthesis of new oxazoborolidine catalysts. Compounds 95 and 96 have been prepared93 from L-cysteine. Aziridine carbi-nols 97a and 97b have been prepared94 from L-serine and L-threonine, respectively. When applied in the catalytic borane reduction of prochiral ketones, good to excellent enantioselectivity can be attained (Schemes 6-42 and 6-43). 

This observation has led to the preparation of more effective bicyclic oxaza-borolidines such as 1, prepared from (S)-(-)-2-(diphenylhydroxymethyl)pyrrolidine and BH3 (la) or methylboronic acid (lb). Both reagents catalyze borane reduction of alkyl aryl ketones to furnish (R)-alcohols in > 95% ee, by face-selective hydride transfer within a complex such as B. Catalyst lb is somewhat more effective than... 

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. ... 

Reduction of carbonyl compounds with metal hydrides or boranes a. primary alcohols from aldehydes, acids, acid halides, and esters... 

Radical Epoxide Reduction Borane-free Two-step Synthesis of anti-Markownikow Alcohols from Alkenes... 

Conversion to benzazepine was achieved under acidic conditions via hydrogenation in alcoholic solvents to form 25, which did not require isolation. Intermediate 25 was directly cyclized under basic conditions to give crystalline lactam 26. The base-mediated ring closure proceeded from the cis/trans mixture of 25 by epimerization of the benzylic methine permitting formation of the cyclic amide from the cis isomer. Finally, conversion of 26 to the desired benzazepine (8) was accomplished by in situ borane reduction and 8 was isolated as the tosylate salt in 81% yield. 

After the identification of aprepitant as a clinical candidate, Merck invested considerable process research toward an improved synthesis of aprepitant, which culminated in the elegant manufacturing process shown in Scheme 6.21,22 The key step relies on displacement of a trifluoroacetate from intermediate 48 by the optically active alcohol intermediate 49. The synthesis of 49 was accomplished via an oxazaborolidine-catalyzed borane reduction of the corresponding acetophenone. Although the displacement resulted in an almost equal mixture of the two diastereomers 50 and 51, the desired diastereomer 50 could be recovered in high yield by base-catalyzed equilibration of the mixture and crystallization. Addition of p-fluorophenyl magnesium bromide followed by hydrogenolysis afforded the key intermediate 40, which can be readily converted to 1 as detailed in the previous synthesis. 

The in situ generated catalyst from ATBH and trimethyl borate has also been used in the stereoselective reduction of a-oxoketoxime ethers to prepare the corresponding chiral 1,2-amino alcohols. Thus the asymmetric borane reduction of buta-2,3-dione monoxime ether followed by acidic work-up and subsequent reaction with benzyloxycarbonyl chloride affords a 90% yield of 7V-(Z)-3-aminobutan-2-ol with excellent enantioselectivities (eq 5). A trityl group in the oxime ether is required for high enantioselectivity. This method has been successively applied to both cyclic and acyclic a-oxoketoxime ethers. 

On the basis of such hypothesis, the synthesis and use of new phosphine oxides from (S)-prolinol has been realized. Thus, enantioselective borane reduction of chloroacetophenone at 60 °C in THF in presence of 1 mol% of 24 led to the expected alcohols in up to 94% ee [34]. 

An attempt to prepare cephalotaxine and 11-hydroxycephalotaxine from chiral precursors by means of a ring expansion of isoquinoline derivatives prepared by the Pictet-Spengler condensation was made by Hudlicky in 1981 (70,71) as shown in Scheme 37. Acid 210 was prepared by condensation of biogenic amines 208 (X = H or OH) with the pyruvate 209. Borane reduction to the corresponding alcohols 211, followed by acid-catalyzed solvolysis, led to the tricyclic enamines 212 and 213 (77). This approach was modeled on the biogenetic condensation of amines with pyruvates to generate 1,1-disubstituted tetrahydroisoquinolines, ubiquitous in alkaloid biogenesis (70). 

The structurally more rigid (S)-prolinol-based amino alcohol was introduced early in the study of borane reductions [18]. Sterically more hindered ox-azaborolidines 4 (Fig. 1) based on (S)-(-)-diphenylhydroxymethylpyrrolidine have been prepared by Corey [23,25]. These catalysts have been widely used for the borane reduction of various kinds of ketones. After these successful results had appeared for asymmetric ketone reduction, several oxazaborohdines (Fig. 1) were prepared. Many of them were successfully used in the reduction of aromatic ketones. Selected results of enantioselective borane reduction using various oxazaborohdines are shown in Scheme 4. The table to this scheme shows only the data obtained from the reduction of acetophenone as a representative aromatic ketone. In most cases, high enantioselectivity is obtained in the nearly quantitative yield. 

A variety of optically active amines and amino alcohols have been used as chiral auxiliaries for borane reductions. With few exceptions9, early results gave poor to modest asymmetric induction. For example, a variety of amino alcohols derived from a-amino acids gave reduction products of up to 60% ee1U. These reagents presumably used one equivalent of borane per mole of amino alcohol. In 1983 it was shown that the ratio of borane to amino alcohol was important and that two equivalents of borane were required for maximum asymmetric induction. It was postulated that an amino-borane complex of an oxazaborolidinc was involved in the reduction11. 

Carbon-11 labeled BPA, 4, was synthesized from the corresponding aldehyde, 4-boronophenylacetaldehyde, 9. This boronated aldehyde was prepared from commercially available 4-bromophenylacetic acid, 10, in five synthetic steps (Scheme 1). The synthesis was initiated by the borane reduction of acid 10 to the 2-(4-boronophenyl)ethyl alcohol, 11. Alcohol 11 was then carefully oxidized to aldehyde 12. In the next step, 4-bromophenylacetaldehyde, 12, was refluxed with ethylene glycol in the presence of a catalytic amount of/>-toluenesulfonic acid to obtain the corresponding acetal 13.The boronic acid moiety was introduced at the para position of the phenyl ring 1 the reaction with butyllithium followed by triisopropyl borate" to obtain the 4-bronophenylacetaldehyde ethylene acetal, 14. In the final step of the synthesis, acetal 14 was treated with concentrated hydrochloric acid in methanol as solvent to obtain the desired precursor, 4-boronophenylacetaldehyde, 9, for the synthesis of carbon-11 labeled BPA, 4, Scheme 2. 

Indeed, by immobilization of optically active a- or )0-amino alcohols on cross-linked polystyrenes as in 6a-d, utilization of chiral borane complexes becomes feasible. These functionalized polymers were incorporated into simple columns and enantioselective reductions of aldehydes and ketones were performed. Thus, reduction of acetophenone with a borane complex prepared from 6d yielded optically active (-)-l-phenyl-2-propanol in high optical yield (>99% ee) [31]. In addition, the flow system also served for continuous regeneration of the immobilized complex. Injection of borane and valerophenone into the column, which was loaded with polymer 6a, was followed by collection of fractions every 30 min. The individual batches of collected 1-phenylpentanol were analyzed and the enantiomeric excess was determined to be 87,93, and 91% for three batches [32]. 

Bp3-OEt2 followed hy DiisobutyUduminum Hydride is used for the 1,2-reduction of y-aimno-Q, -unsaturated esters to give unsaturated amino alcohols, which are chiral building blocks for a -amino acids. Q , -Unsaturated nitroalkenes can be reduced to hydroxylamines by Sodium Borohydride and BF3-OEt2 in THF extended reaction times result in the reduction of the hydroxylamines to alkylamines. Diphenylamine-borane is prepared from sodium borohydride, BF3-OEt2, and diphenylamine in THF at 0 °C. This solid is more stable in air than BF3-THF and is almost as reactive in the reduction of aldehydes, ketones, carboxyhc acids, esters, and anhydrides, as well as in the hydrob-oration of alkenes. 

For example, Mikolajczyk and Kielbasinski [172-175] studied the acylation of phosphine boranes 259 using CAL (Chirazyme ) lipase from Candida Antarctica and Lipase AK from Pseudomonas fluorescencs (Scheme 84). The best enantios-electivity was attained in the lipase AK-catalyzed acylation of 259 in cyclohexane solution with vinyl butyrate as an acyl donor (99% ee) for unreacted hydroxypho-sphinate 259 and 43% ee for the acylated product 260. The E-values were on the level of 15. The enzymatic resolution of alkoxy (hydroxymethyl)phenyl-phosphine boranes (/ /S)-261 was achieved by trans-esterification with vinyl acetate in the presence of CALB, Amano AK, Amano PS, Amano AH, and LPL in various solvents. The best enantioselectivity of imreacted alcohol 261 and acylated product 262 was attained in cyclohexane (37% ee, conversion 50%). Kielbasinski [176] recently reported some additional data, including theoretical calculations and more accurate chemical correlation, which proved that the borane reduction of acyclic phosphine oxides proceeded with inversion of configuration at the phosphoms center. On this basis, the stereochemistry of the enzymatic reaction was ultimately determined (Scheme 85). 

The pioneering work from Itsuno group [11-14] on stoichiometric 1,2-aminoalcohol-borane complex-mediated borane reduction of ketones led to the discovery of well-defined oxazaborolidine catalyzed asymmetric reduction by Corey and coworkers [15-18]. Known as Corey-Bakshi-Shibata reaction, or CBS reduction, this reaction has become a standard method for making chiral secondary alcohols for complex molecule synthesis [19]. The generally accepted mechanism of this reaction is shown in Fig. 2. Coordination of the electrophilic reductant BH3 to the nitrogen atom of... 

Paterson et al. [98] in their attempt used a similar disconnection for rhizopodin as described by Menche (fragments 144 and 149) (Scheme 2.151). However, unlike, Menche, they used silyl ketene acetal 16 in an asynunetric VMAR for the addition to ( )-iodoacrolein (142) to obtain dioxinone 143 in 94% ee. Methanolysis removed the aceto-nide, and the subsequent Narasaka reduction [99] provided the syn-diol 144 in 80% yield and a 10 1 selectivity for the desired isomer. The synthesis of segment 149 started with aldehyde 145, which was ultimately derived from Roche ester. Carbon chain extension was achieved through a chelation-controlled Mukaiyama aldol reaction with silyl ketene acetal 146, which installed the new chiral center with excellent stereocontrol (20 1 dr). For the installation of the third secondary alcohol, six-membered lactone 148 was obtained by treatment with K COj in methanol. Subsequent borane reduction provided stereospecifically the desired alcohol, which was then further transformed to the desired acid (149). 

There have been significant discoveries of methods that enable the enantioselective addition of an alkyne to an aldehyde or a ketone [182]. The resulting chiral propargyl alcohols are amenable to a wide variety of subsequent structural modifications and function as useful, versatile chemical building blocks. In 1994, Corey reported the enantioselective addition reactions of boryl acetylides such as 292, prepared from the corresponding stannyl acetylenes (e.g., 291) in the presence of the oxazaborolidine 293 as the chiral catalyst (Scheme 2.36) [183]. Both aliphatic and aromatic aldehydes were demonstrated to participate in these addition reactions, which proceeded in high yields and with impressive enantioselectivity. The proposed transition state model 295 is believed to involve dual activation both of the nucleophile (acetylide) and of the electrophile (aldehyde). The model bears a resemblance to the constructs previously proposed for alkylzinc addition reactions (Noyori, 153) and borane reductions (Corey. 188). 

The most successful of the Lewis acid catalysts are oxazaborolidines prepared from chiral amino alcohols and boranes. These compounds lead to enantioselective reduction of acetophenone by an external reductant, usually diborane. The chiral environment established in the complex leads to facial selectivity. The most widely known example of these reagents is derived from the amino acid proline. Several other examples of this type of reagent have been developed, and these will be discussed more completely in Section 5.2 of part B. 

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