Aldol asymmetric activation

A similar enantiomer-selective activation has been observed for aldol " and hetero-Diels-Alder reactions.Asymmetric activation of (R)-9 by (/f)-BINOL is also effective in giving higher enantioselectivity (97% ee) than those by the parent (R)-9 (91% ee) in the aldol reaction of silyl enol ethers (Scheme 8.12a). Asymmetric activation of R)-9 by (/f)-BINOL is the key to provide higher enantioselectivity (84% ee) than those obtained by (R)-9 (5% ee) in the hetero-Diels-Alder reaction with Danishefsky s diene (Scheme 8.12b). Activation with (/ )-6-Br-BINOL gives lower yield (25%) and enantioselectivity (43% ee) than the one using (/f)-BINOL (50%, 84% ee). One can see that not only steric but also electronic factors are important in a chiral activator. 

ASYMMETRIC ACTIVATION AND DEACTIVATION OF RACEMIC CATALYSTS (a) Aldol reaction... 

The advantage of asymmetric activation of the racemic BINOL-Ti(OPr )2 complex ( 2) is highlighted in a catalytic version (Table 8C.3, entry 5) wherein high enantioselectivity (80.0% ee) is obtained by adding less than the stoichiometric amount (0.25 molar amount) of (R)-BI-NOL [42a], A similar phenomenon has been observed in the aldol [42c] and (hetero) Diels-Al-der [44] reactions catalyzed by the racemic BINOL-Ti(OPr )2 catalyst (+2). 

Keywords Ene reaction, Hetero-Diels-Alder reaction, Ene cyclization, Desymmetrization, Kinetic resolution. Non-linear effect. Asymmetric activation, Metallo-ene, Carbonyl addition reaction, Aldol-type reaction. Titanium, Aluminum, Magnesium, Palladium, Copper, Lanthanides, Binaphthol, Bisoxazoline, Diphosphine, TADDOL, Schiff base. 

Acetoxy-l,7-octadiene (40) is converted into l,7-octadien-3-one (124) by hydrolysis and oxidation. The most useful application of this enone 124 is bisannulation to form two fused six-membered ketonesfl 13], The Michael addition of 2-methyl-1,3-cyclopentanedione (125) to 124 and asymmetric aldol condensation using (5)-phenylalanine afford the optically active diketone 126. The terminal alkene is oxidi2ed with PdCl2-CuCl2-02 to give the methyl ketone 127 in 77% yield. Finally, reduction of the double bond and aldol condensation produce the important intermediate 128 of steroid synthesis in optically pure form[114]. 

A similar Evans asymmetric aldol/reduction sequence could also serve well in a synthesis of fragment 158. Compounds 161 and 162 thus emerge as potential precursors to 158. In theory, building blocks 161 and 162 could be procured in optically active form from commercially available and enantiomerically pure (+)-/ -citro-nellene (163) and D-mannitol (164), respectively (see Scheme 42). 

These results show that chemical yields are generally higher than for most aldol-type additions of ester cnolates. mainly because of the chemical activation of the methylene group by the sulfoxide, which makes this reaction suitable for any aldehyde or ketone. High asymmetric induction is also generally observed. The aldol adducts obtained by addition to aldehydes have been transformed into optically active four- and five-membered lactones38. 

Demailly and coworkers195 found that the asymmetric induction increased markedly when optically active methyl pyridyl sulfoxide was treated with an aldehyde. They also synthesized (S)-chroman-2-carboxylaldehyde 152, which is the cyclic ring part of a-tocopherol, by aldol-type condensation of the optically active lithium salt of a,/3-unsaturated sulfoxide. Although the diastereomeric ratio of allylic alcohol 151 formed from lithium salt 149 and 150 was not determined, the reaction of 149 with salicylaldehyde gave the diastereomeric alcohol in a ratio of 28 72196. 

Over the last few years several examples have been reported in the field of asymmetric catalysis that are based on the interaction of two centers.6,119 Recently, Shibasaki and coworkers have developed an asymmetric two-center catalyst. Scheme 3.14 shows preparation of optically active La binaphthol (BINOL). This catalyst is effective in inducing the asymmetric nitro-aldol reaction, as shown in Scheme 3.15. 

Aldolases catalyze asymmetric aldol reactions via either Schiff base formation (type I aldolase) or activation by Zn2+ (type II aldolase) (Figure 1.16). The most common natural donors of aldoalses are dihydroxyacetone phosphate (DHAP), pyruvate/phosphoenolpyruvate (PEP), acetaldehyde and glycine (Figure 1.17) [71], When acetaldehyde is used as the donor, 2-deoxyribose-5-phosphate aldolases (DERAs) are able to catalyze a sequential aldol reaction to form 2,4-didexoyhexoses [72,73]. Aldolases have been used to synthesize a variety of carbohydrates and derivatives, such as azasugars, cyclitols and densely functionalized chiral linear or cyclic molecules [74,75]. 

In asymmetric reactions, chiral phosphine ligands such as BINAP derivatives are used as effective chiral ligands in silver complexes. In particular, an Agr-BINAP complex activates aldehydes and imines effectively and asymmetric allylations,220-222 aldol reactions 223 and Mannich-type reactions224 proceed in high yield with high selectivity (Scheme 51). 

Recently, novel bifunctionalized zinc catalysts have been developed (compounds (N) and (P), Scheme 55). They have both Lewis-acid and Lewis-base centers in their complexes, and show remarkable catalytic activity in direct aldol reactions.233-236 A Zn11 chiral diamine complex effectively catalyzes Mannich-type reactions of acylhydrazones in aqueous media to afford the corresponding adducts in high yields and selectivities (Scheme 56).237 This is the first example of catalytic asymmetric Mannich-type reactions in aqueous media, and it is remarkable that this chiral Zn11 complex is stable in aqueous media. 

Sn(OTf)2 can function as a catalyst for aldol reactions, allylations, and cyanations asymmetric versions of these reactions have also been reported. Diastereoselective and enantioselective aldol reactions of aldehydes with silyl enol ethers using Sn(OTf)2 and a chiral amine have been reported (Scheme SO) 338 33 5 A proposed active complex is shown in the scheme. Catalytic asymmetric aldol reactions using Sn(OTf)2, a chiral diamine, and tin(II) oxide have been developed.340 Tin(II) oxide is assumed to prevent achiral reaction pathway by weakening the Lewis acidity of Me3SiOTf, which is formed during the reaction. 

Ligands for catalytic Mukaiyama aldol addition have primarily included bidentate chelates derived from optically active diols,26 diamines,27 amino acid derivatives,28 and tartrates.29 Enantioselective reactions induced by chiral Ti(IY) complex have proved to be one of the most powerful stereoselective transformations for synthetic chemists. The catalytic asymmetric aldol reaction introduced by Mukaiyama is discussed in Section 3.4.1. 

This chapter has introduced the aldol and related allylation reactions of carbonyl compounds, the allylation of imine compounds, and Mannich-type reactions. Double asymmetric synthesis creates two chiral centers in one step and is regarded as one of the most efficient synthetic strategies in organic synthesis. The aldol and related reactions discussed in this chapter are very important reactions in organic synthesis because the reaction products constitute the backbone of many important antibiotics, anticancer drugs, and other bioactive molecules. Indeed, study of the aldol reaction is still actively pursued in order to improve reaction conditions, enhance stereoselectivity, and widen the scope of applicability of this type of reaction. 

Another classic transformation, a catalytic asymmetric version of which has been the focus of serve-ral studies is the aldol reaction. Evans, Camera and Shibasaki are three of the active researchers in this area. 

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