Benzaldehyde asymmetric reduction

Reduction of carbonyl groups Terpene and aromatic aldehydes (lOOppm) were reduced by microalgae. In a series of chlorinated benzaldehyde, m - or p-chlorobenzaldehyde reacted faster than the o-derivative. Due to toxicity, the substrate concentrations are difficult to increase. Asymmetric reductions of ketones by microalgae were reported. Thus, aliphatic " and aromatic " ketones were reduced. 

Two strategies for the synthesis of enantiomerically enriched diaryl methanols 27 are apparent first, asymmetric reductions of the corresponding diaryl ketones 36 [33], and, second, enantioselective aryl transfer reactions to the respective benzaldehyde derivatives 37 (Scheme 2.1.2.5) [34, 35]. 

On use as homogeneous catalysts in the asymmetric reductive alkylation of benzaldehyde with diethylzinc to form secondary alcohols, the corresponding dendritic titanium-TADDOL complexes having either chiral or achiral dendrons gave enantiomeric excesses (ee) of up to 98.5 1.5 at a conversion of 98.7% (for the catalyst with GO dendrons). With larger dendrons the reduction of the ee to 94.5 5.5 (G4) remained within reasonable limits, while the drop in conversion to 46.8% (G4) proved to be drastic. In comparison, the unsubstituted Ti-TAD-DOL complex gave an ee of 99 1 with complete conversion. This negative den-... 

Rogic, M. M. Conformational Analysis and the Transition State in Asymmetric Reductions with Boranes Based on (+)-a-Pinene. 1. Benzaldehyde Reduction with Alpine Borane and Other B-Alkyl-9-borabicyclo[3.3.1]nonanes. ASemiempirical Study. J. Org. Chem. 1996, 61, 1341-1346. 

Scheme 7.5. Alpine-borane method of asymmetric reduction, (a) Preparation of Alpine-Borane . (b) Reduction of deuterio benzaldehyde [52], (c) Reduction of propargyl ketones...

Asymmetric reduction. This organoborane reduces aldehydes within minutes, but reduces ketones rather slowly. Of greater interest, the chiral organoborane from ( + )-cc-pinene reduces benzaldehyde-a-d quantitatively to (S)-( + )-benzyl-a-d-alcohol in 81.6%, chemical yield (equation 1). In principle the opposite enantiomer could be prepared when (- )-ct-pinene is used. 

Meerwein-Ponndorf-Verley type asymmetric reduction has also been accomplished with alkyloxy magnesium halides prepared from optically active alcohols. Optically active 2-octyloxy-2-d magnesium bromide reduced butyraldehyde to optically active n-butyl-1-d alcohol (Streitwieser, 1953). Reduction of benzaldehyde with 1-deuteroisobornyloxy magnesium halide produced optically active benzyl-l-d alcohol (Streitwieser and Wolfe, 1957 Streitwieser et al, 1959). 

It is postulated that the reduction of benzaldehydes proceeds predominately through a cyclic process [9]. This conclusion is based on the second-order kinetic data, the change in rate with structural and electronic changes in the aldehydes, and the results of asymmetric reduction. However, greater steric effects, both in the organoboranes and substrate, lead predominantly to the dehydrobo-ration process. 

Asymmetric reductive alkylation has also been reported in reactions between benzaldehyde and chiral alkyl(trialkoxy)titanium reagents aryl carbinols are obtained with up to 88% e.e., best results coming from the menthol or binaphthol derivatives, (19) and (20), respectively. 

Chiral [a- Hlbenzyl alcohol has been prepared by asymmetric reduction of [l- H]benzaldehyde the most efficient reagent was bornyloxymagnesium bromide. ... 

Scheme 16 Asymmetric reductive aldol reaction of benzaldehyde and acrylate...

The phebox-Rh acetate complex 5 is an efficient catalyst for the asymmetric reductive aldol reaction (Scheme 16) [22]. For example, the reaction of benzaldehyde with t-butyl acrylate in the presence of 1 mol% of the benzyl-phebox complex 5-Bn proceeded in an/i-selectivity and was completed within 0.5-1 h to form the... 

The triazole 76, which is more accurately portrayed as the nucleophilic carbene structure 76a, acts as a formyl anion equivalent by reaction with alkyl halides and subsequent reductive cleavage to give aldehydes as shown (75TL1889). The benzoin reaction may be considered as resulting in the net addition of a benzoyl anion to a benzaldehyde, and the chiral triazolium salt 77 has been reported to be an efficient asymmetric catalyst for this, giving the products (/ )-ArCH(OH)COAr, in up to 86% e.e. (96HCA1217). In the closely related intramolecular Stetter reaction e.e.s of up to 74% were obtained (96HCA1899). 

Multi-step syntheses of a radiopharmaceutical involving an aromatic nucleophilic radiofluorination An example of a multi-step radiosynthetic pathway is the no-carrier-added synthesis of 6-[ F]fluoro-L-DOPA (Scheme 45). The first step involves the preparation of 4,5-dimethoxy-2-[ F]fluorobenzaldehyde from the corresponding nitro-substituted benzaldehyde. The following steps involve its condensation with an asymmetric chiral inductor [206] followed by L-selectride reduction of the... 

The highly enantioselective production of ( + )-(S )-benzenemethan-a-configurational determination of 8 rests on an asymmetric Meerwein-Ponndorf reduction (with isobornyloxymagnesium bromide). On mechanistic grounds the reduction of benzaldehyde-rf was assumed to produce preferentially the 7 -isomer225. 

Asymmetric alkylation of benzaldehyde can be performed in a toluene/FC-72 biphasic system with Ti(0-iPr)4 and the fluorous BINOL ligand 7 (Figure 2) with reasonable yield and enantioselectivity [24]. The asymmetric hydrogen-transfer reduction of ketones works fairly... 

A bimetallic catalyst prepared from BINOL and lithium aluminum hydride has been found to result in useful asymmetric induction in the Pudovik reaction [17]. The (f )-ALB catalyst 64 (10 mol %) facilitates the addition of dimethyl phosphite to a variety of electron-rich and electron-poor aryl aldehydes in high yield with induction in the range 71-90 % ee. The nature of the solvent is important in this reaction—the induction for addition to benzaldehyde dropped from 85 % ee to 65 % ee when the solvent was changed from toluene to dichloromethane. Aluminum seems to be a key to the success of this reaction, because reaction with benzaldehyde was not as successful with other bimetallic catalysts. BINOL catalysts with lanthanum and potassium gave only 2 % ee, a catalyst with lanthanum and sodium gave a low 32 % ee, and a catalyst with lanthanum and lithium gave only a 28 % ee [18]. Aliphatic aldehydes were not successfully hydrophosphonylated with dimethyl phosphite by catalyst 64 (Sch. 9). Induction was low (3-24 % ee) for unbranched and branched substrates. a,/3-Unsaturated aldehydes were, however, reported to work nearly as well as aryl aldehydes with four examples in the range 55-89 % ee. The failure of aliphatic aldehydes with this catalyst can be overcome by reduction of the product obtained from reactions with a,)3-unsaturated aldehydes. As illustrated by the reduction of 67 with palladium on carbon, this can be done without epimerization of the a-hydroxy phos-phonate. 

In addition to four component condensation, several other applications of chiral primary ferrocenylalkyl amines have been published. Thus, an asymmetric synthesis of alanine was developed (Fig. 4-3la), which forms an imine from 1-ferrocenylethyl amine and pyruvic acid, followed by catalytic reduction (Pd/C) to the amine. Cleavage of the auxiliary occurs readily by 2-mercaptoacetic acid, giving alanine in 61% ee and allowing for recycling of the chiral auxiliary from the sulfur derivative by the HgClj technique [165]. Enantioselective reduction of imines is not limited to pyruvic acid, but has recently also been applied to the imine with acetophenone, although the diastereoisomeric ferrocenylalkyl derivatives of phenylethylamine were obtained only in a ratio of about 2 1 (Fig. 4-31 b). The enantioselective addition of methyl lithium to the imine with benzaldehyde was of the same low selectivity [57]. Recycling of the chiral auxiliary was possible by treatment of the secondary amines with acetic acid/formaldehyde mixture that cleaved the phenylethylamine from the cation and substituted it for acetate. 

In 1972, Tsuchihashi disclosed that the carbanion (28 Ar = p-tolyl), generated from (/ )-methyl p-tolyl sulfoxide with lithium diethylamide, adds to benzaldehyde or a-tetialone to give an adduct (29) in a dia-stereomeric ratio of 50 50 or 64 36, respectively. Additions of this carbanion to various unsymmetrical ketones are also reported to be poorly diastereoselective (for example, EtCOMe 50 50, Bu COMe 55 45, Bu COPh 70 30). Note that in the case of Ar = 2-pyridyl a chiral sulfinyl group increases the asymmetric induction observed in the addition of the corresponding carbanion to carbonyl compounds (PhCHO 80 20, R-C9H19CHO 70 30). Since diastereomer pairs of (29) are separable, chromatographic separation followed by reductive desulfurization with Raney Ni provides a method for obtaining optically active alcohols (30 Scheme 9). 

In 1999, Cozzi and Umani-Ronchi described a diastereoselective intermolecular pinacol coupling of aromatic and aliphatic aldehydes in the presence of a catalytic quantity of TiCl4(THF)2/Schiff base (Eq. 3.38) [60]. Manganese is employed as the stoichiometric reductant with the Cozzi/Umani-Ronchi system, zinc generally affords a lower yield of the diol. The reaction is believed to proceed via a pathway analogous to that illustrated in Fig. 3-5. The observations of Cozzi and Umani-Ronchi that the Schiff base affects reaction diastereoselectivity and increases the reaction rate bode well for studies of asymmetric variants. In an initial investigation, these workers obtained 10% ee in a reductive dimerization of benzaldehyde (Eq. 3.39). 

Woerpel has recently reported a tandem double asymmetric aldol/C=0 reduction sequence that diastereoselectively affords propionate stereo-triads and -pentads commonly found in polyketide-derived natural products (Scheme 8-2) [14], When the lithium enolate of propiophenone is treated with excess aldehyde, the expected aldolates 30/31 are formed however, following warming to ambient temperature a mono-protected diol 34 can be isolated. In a powerful demonstration of the method, treatment of 3-pentanone with 1.3 equiv of LDA and excess benzaldehyde yielded product in corporating five new stereocenters in 81% as an 86 5 5 3 mixture of diastereomers (Eq. (8.8)). A series of elegant experiments have shown that under the condition that the reaction is conducted, the aldol addition reaction is rapidly reversible with an irreversible intramolecular Tischenko reduction serving as the stereochemically determining step (32 34, Scheme 8-2). 

Tagliavini and Umani-Ronchi found that chiral BINOL-Zr complex 9 as well as the BINOL-Ti complexes can catalyze the asymmetric allylation of aldehydes with allylic stannanes (Scheme 9) [27]. The chiral Zr catalyst 9 is prepared from (S)-BINOL and commercially available Zr(0 Pr)4 Pr0H. The reaction rate of the catalytic system is high in comparison with that of the BINOL-Ti catalyst 4, however, the Zr-catalyzed allylation reaction is sometimes accompanied by an undesired Meerwein-Ponndorf-Verley type reduction of aldehydes. The Zr complex 9 is appropriate for aromatic aldehydes to obtain high enantiomeric excess, while the Ti complex 4 is favored for aUphatic aldehydes. A chiral amplification phenomenon has, to a small extent, been observed for the chiral Zr complex-catalyzed allylation reaction of benzaldehyde. 

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