Benzaldehyde asymmetric allylation

As shown in Scheme 2.20, selective lithiation of substrate 2-87 by treatment with LDA in THF at -78 °C triggers an intramolecular Michael/intermolecular aldol addition process with benzaldehyde to give a mixture of diastereomers 2-90 and 2-91. 2-91 was afterwards transformed into 2-92, which is used as a chiral ligand for Pd-catalyzed asymmetric allylic substitution reactions [29]. 

Figure 6.25. Asymmetric allylation of benzaldehyde catalysed by a fluorinated Ti/BINOL complex under...

Practical and efficient asymmetric allylation of aldehydes is successfully promoted by Lewis acid catalysts bearing chiral auxiliaries to afford high levels of enantioselectivity.165 The effective catalysts for asymmetric allylation to benzaldehyde are shown below (Scheme j) 166-176 The catalytic asymmetric allylation of ketones has proved to be a more challenging transformation owing to the significantly low reactivity compared to aldehydes. In 2002, a catalyst based on titanium complex was developed (Equation (51)).A ... 

Denmark utilized the asymmetric allylation methodology in the synthesis of the serotonin antagonist LY426965 (17), preclinical studies of which suggest its pharmacotherapy use for smoking cessation and depression-related disorders16 (Scheme 3.2m). The key intermediate alcohol (19) was prepared in 94% ee via the asymmetric addition of the silane 18 to benzaldehyde in the presence of the chiral ligand (.S, .S )-16. 

The observed activation of allyltrihalosilanes with fluoride ion and DMF and the proposition that these agents are bound to the silicon in the stereochemistry-determining transition structures clearly suggested the use of chiral Lewis bases for asymmetric catalysis. The use of chiral Lewis bases as promoters for the asymmetric allylation and 2-butenylation of aldehydes was first demonstrated by Denmark in 1994 (Scheme 10-31) [55]. In these reactions, the use of a chiral phos-phoramide promoter 74 provides the homoallylic alcohols in high yield, albeit modest enantioselectivity. For example, the ( )-71 and benzaldehyde affords the anti homoallylic alcohol 75 (98/2 antUsyn) in 66% ee. The sense of relative stereoinduction clearly supports the intermediacy of a hexacoordinate silicon species. The stereochemical outcome at the hydroxy center is also consistent with a cyclic transition structure. 

The asymmetric allylation of achiral aldehydes with a novel silver complex has recently been reported (Scheme 10-51) [90]. Initially, it was shown that the silver-promoted reaction of allyltributylstannane with benzaldehyde could be accelerated by triphenylphosphine. A survey of various chiral phosphine reagents and silver salts identified the combination of binap and AgOTf as optimal. The reaction of benzaldehyde and allyltributylstannane promoted by 5 mol% of the binap-AgOTf... 

The enantioselective asymmetric allylation of imines has been a synthetic challenge, the initial solutions of which required stoichiometric amounts of chiral allylbor on [87], allylsilane [88], allylzinc [89], or allylindium reagents [90]. Itsuno showed that a chiral B allyloxazaborolidine derived from norephedrine could add to the N trimethylsilyl imine prepared from benzaldehyde in high yield and enantiomeric excess (Scheme 1.22) [91]. Brown later reported that B allyldiisopinocamphenylbor ane is also very effective for the allylation of the same electrophiles, but the addition of a molar amount of water is necessary to obtain high yields [92]. The diastereo and... 

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. 

Iseki et al. later improved the catalytic process and showed that chiral phos-phoramides 15,16, and 17, prepared from (S)-proHne, are suitable to catalyze the asymmetric allylation of aromatic aldehydes to give chiral homoallylic alcohols 34 with up to 88% ee (Scheme 13) [36,37]. The same group has also developed a chiral formamide 18 as a chiral Lewis base catalyst [38]. This catalyst is convenient for the allylation of aUphatic aldehydes with high enantioselectivity. A typical aromatic aldehyde, benzaldehyde, gives a low enantiomeric excess (Scheme 13). 

Scheme 7.35 Large-scale asymmetric allylation of benzaldehyde using allyltrimethylsilane.

Asymmetric activation of chiral BINOL zirconium catalyst was reported as shown in Equation 37 [42]. Addition of optically active naphthyl alcohol (81) to the asymmetric allylation of benzaldehyde with allyltributyltin in the presence of catalyst (80) improved the enantioselectivity of optically active homoallyl alcohol (82) compared with the reaction without activator (81). 

Asymmetric allylation of aldehydes with allyhc agents catalyzed by Lewis acid is a practical method for synthesizing optically active hranoallylic alcohols [10]. The chloro complex 1 serves as an efficient catalyst for asymmetric allylation of aldehydes with allylstannane [8, 9, 11]. In the presence of 5 mol% of the benzyl-phebox-Rh complex 1-Bn, the coupling reaction of benzaldehyde with allyltributyl-stannane in CH2CI2 at room temperature proceeded smoothly to provide the corresponding homo-aUyl alcohol 7a in 88% yield with 61% ee (Scheme 2). When methaUylstannane was subjected to the reactiOTi, enantioselectivity of the allylated product 8 significantly increased to be over 90% ee. 

A Ti-BINOL based LLA system was developed for asymmetric allylation by Yamamoto group in 2004 (Scheme 1.17) [23]. Allylation reaction of benzaldehyde with allyltributyltin has been found to be dramatically accelerated by addition of 5 mol% of 4-(trifluoromethyl)boroxine to Ti-(S)-BINOL catalyst. 

The highest enantioselectivity of 84% (R) was obtained in the reaction of benzaldehyde with allyl chloride (Scheme 12.8). Using the more reactive allyl iodide resulted in a racemic product, most likely because of the reaction of the iodide with Mn, affording an achiral allylating species. Changing silylating agents was reported not to have an influence on the asymmetric induction of the process. 

Nagasawa and co-workers reported the use of a chiral bis-thiourea catalyst (108) for the asymmetric MBH reactions of cyclohexenone with aldehydes [95]. Since others had already shown that thioureas form hydrogen bonds with both aldehydes and enones, it was hypothesized that the inclusion of two thiourea moieties in close proximity on a chiral scaffold would organize the two partners of the MBH reaction and lead to enantiofacial selectivity. Initial studies showed that the achiral 3,5-bis-(trifluoromethyl)phenyl-substituted urea increased the rate of MBH reaction between benzaldehyde and cyclohexenone. These authors then showed that chiral 1,2-cyclohexyldiamine-linked bis-thiourea catalyst 108, used at 40 mol% loading in the presence of 40 mol% DMAP, promoted the MBH reactions of cyclohexenone with various aliphatic and aromatic aldehydes (40) to produce allylic alcohols in moderate to high yields (33-99%) and variable enantio-selectivities (19-90% ee Table 6.33). 

Many noticeable examples of chiral Lewis base catalyzed allylation of carbonyl compounds have also appeared. Iseki and coworkers published a full paper on enantioselective addition of allyl- and crotyltrichlorosilanes to aliphatic aldehydes catalyzed by a chiral formamide 28 in the presence of HMPA as an additive [41]. This method was further applied to asymmetric allenylation of aliphatic aldehydes with propargyltrichlorosilane [40]. Nakajima and Hashi-moto have demonstrated the effectiveness of (S)-3,3 -dimethyl-2,2 -biquinoline N,AT-dioxide (29) as a chiral Lewis base catalyst for the allylation of aldehydes [42]. In the reaction of (fs)-enriched crotyltrichlorosilane (54 , E Z=97 3) with benzaldehyde (48), y-allylated anfi-homoallylic alcohol 55 was obtained exclusively with high ee while the corresponding syn-adduct was formed from its Z isomer 54Z (fs Z= 1 99) (Scheme 6). Catalytic amounts of chiral urea 30 also promote the asymmetric reaction in the presence of a silver(I) salt, although the enantioselectivity is low [43]. 

Tridentate salen ligands (10) derived from 1 have given excellent results in the enantiocontrol of the hetero Diels-Alder addition reaction of dienes with aldehydes (eq 7) and in the asymmetric additions of TMS-azide to mc5o-epoxide and trimethylsilyl cyanide to benzaldehyde (up to 85% ee). Phosphino-oxazolines derived from 1 have been employed for the asymmetric control of palladium-catalyzed allylic substitution reactions products of 70-90% ee were obtained. Photolysis of crystalline adducts of enantiomerically pure 1 with prochiral alcohols results in asymmetric inductions of up to 79% in a rare example of a solid-state enantioselective reaction. ... 

Allyltrichlorosilane reacts with benzaldehyde in the presence of BU4NF to give l-phenylbut-3-en-lol7 and with a chiral additive the reaction proceeds with good enantioselectivity. When chiral titanium complexes are used in the reaction, allylic alcohols are produced with good asymmetric induction/ Other chiral additives have been used, as well as chiral catalysts,and chiral complexes of allyl silanes 7 Chiral allylic silyl derivatives add to aldehydes to give the chiral homo-allylic alcoholJ ... 

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