Aldehydes Et2Zn addition

Marshall and co-workers have demonstrated that allenylindium [277] and allen-ylzinc [276] reagents can be formed in situ from propargyl mesylate 389 and that these reagents react enantioselectively with aldehydes without additional Lewis acid catalysis (Scheme 11-28). The allenylzinc and allenylindium reagents 392 and 391 are derived from the allenylpalladium intermediate 390 via metathesis with Et2Zn and Ini, respectively. Allenylpalladium intermediate 390 in turn is derived from (7 )-389 via invertive displacement of the mesylate functionality of 389 with Pd(0). 

Addition to aldehydes. Qrganozinc addition to aldehydes with BINOLs as catalysts likely involves precoordination. 3,3 -Disubstituted BINOLs, especially with substituents providing additional ligating groups, are found to be highly effective, as exemplified by the use of 1 and 2 in reaction of Et2Zn and alkynylzincs (in situ), respectively. 

Chiralcel OD is suitable to nicely separate the enantiomers. The pure enantiomers of 278 were used as a chiral ligand in the Et2Zn addition to benzaldehyde. The ees increased for electron attracting groups on the aldehyde (96JOC8002). 

On the basis of the original studies [111-113], the DoM-cross-coupHng sequence represents a significant entry into chiral binaphthol (BINOL) and achiral biphenol (BIPOL) ligands (Table 14.18) [111-119], which are outside the scope of this review but are widely used for enantioselective reactions, for example, Et2Zn addition to aromatic aldehydes, the Mannich-type reactions, and the Diels-Alder as well as asymmetric ring-closing metathesis (ARCM) reactions. 

Et2Zn also participates in the reductive coupling as a formal hydride source. Results for the Ni-catalyzed, Et2Zn-promoted homoallylation of carbonyl compounds with isoprene are summarized in Table 7 [30]. Et2Zn is so reactive that for the reaction with reactive aromatic aldehydes it causes direct ethylation of aldehydes, and the yields of homoallylation are diminished (runs 1 and 2). Unsaturated aldehydes seem to be subject to the Michael addition of Et2Zn. Accordingly, for the reaction with cinnamaldehyde, none of the expected homoallylation product is produced instead, the 1,4-addition product of Et2Zn, 3-phenylpentanal is produced exclusively (run 3). 

In a seminal study various libraries of chiral ligands and activators in the addition of Et2Zn to aldehydes (51) were investigated (Scheme 11).87,89... 

The disulfonamide library was tested in the TifO PrC-mcdiatcd addition of Et2Zn to aldehydes, a known process using the bis-trifluoromethylsulfonamide of 1,2-diaminocyclohexane.106 The tests were run in 30 different reaction vessels in parallel format. In order to increase throughput, each vessel was charged with four different aldehydes, and the enantioselectivities of the four reaction products were determined by conventional GC analysis of the crude mixtures. The idea of using a given catalyst to screen combinatorially the reactions of different substrates had previously been proposed but in a different context.45 In the present case each mixture required about one hour to be screened, which means that about 96 ee-determinations of products (52) (Scheme 11) could be performed per day.105 A total of 120 results were collected, the best ees being >90%. 

Though several intermolecular catalytic reductive aldol additions are reported, corresponding reductive cyclizations have received less attention. The first reported reductive aldol cyclization involves use of a (diketonato)cobalt(ll) precatalyst in conjunction with PhSiHj as terminal reductant.48,486 The reductive cyclization is applicable to aromatic and heteroaromatic enone partners to form five- and six-membered rings. As demonstrated by the reductive cyclization of mono-enone mono-aldehyde 65a to afford aldol 65b, exceptionally high levels of ty -diastereoselectivity are observed. Interestingly, exposure of the substrate 65a to low-valent nickel in the presence of excess Et2Zn provides the isomeric homoaldol cyclization product 65c via reductive coupling to the enone /3-position (Scheme 43).47a... 

Tandem 1,4-addition to cycloalkenones constitutes an extremely versatile and elegant methodology for the synthesis of 2,3-disubstituted cycloalkanones, as is evident from its application in areas such as prostaglandin synthesis. Noyori et al. have reported the use of organozinc reagents in copper-catalyzed tandem additions [64]. The zinc enolate resulting from the catalytic enantioselective 1,4-addition of Et2Zn to cyclohexenone reacts readily with an aldehyde in a subsequent aldol condensation. 

Since the pioneering studies of asymmetric catalysis with core-functionalized dendrimers reported by Brunner (88) and Bolm (89), several noteworthy investigations have been described in this field. Some examples of the dendritic effects observed in enantioselective catalysis with dendrimers having active sites in the core were discussed in Section II, such as the catalytic experiments with TADDOL-cored dendrimers described by Seebach et al. (59) the asymmetric addition of Et2Zn to aldehydes catalyzed by core-functionalized phenylacetylene-containing dendrimers reported by Hu et al (42)-, the asymmetric hydrogenation investigations with (R)-BINAP core-functionalized dendrimers synthesized by Fan et al. (36) or the results... 

Ti TG, PS-micro sulfonamide asymmetric addition of Et2Zn to aldehydes [64]... 

The synthesis of a new enantiopure, conformationally constrained 1,4-amino alcohol (25) has been reported, starting from commercially available reagents from the chiral pool.107 This 1,4-amino alcohol has been used as a chiral ligand in the addition of Et2Zn to aldehydes (best ee 98%) and in the synthesis of chiral propargylic alcohols (best ee 70%) by alkynylzinc species. 

A series of chiral (3i ,5 RHlihvdroxypiperidine derivatives have been conveniently prepared from trans -4-hvdrox v- r.-proline and applied to the catalytic enantioselective addition of diethylzinc to benzaldehyde and heptanal.110 The compound (31) has been found to show the best asymmetric induction in promoting the addition of Et2Zn to various aldehydes, providing (R)-secondary alcohols in up to 98% ee. 

The addition of Ph2Zn to aldehydes has been investigated by DFT calculations.103 The experimentally observed increase in enantioselectivity upon addition of Et2Zn to the reaction mixture was rationalized from calculations of all isomeric transition states. 

The direct hydrozincation of olefins14 is possible using Et2Zn in the presence of catalytic amount of Ni(acac)2 and 1,5-cyclooctadiene (COD). The resulting diorganozincs can be used for asymmetric additions to aldehydes. The best hydrozincation reactions are obtained with allylic alcohols or amines. In these cases the raction is driven to completion by the formation of a zinc-heterocycle of type 7 (Scheme 5.10). 

A different method for the catalytic asymmetric addition of a dialkylzinc compound—Et2Zn and aromatic aldehydes have almost always been used—is shown in Figure 8.31. With regard to stereoselective synthesis, this method has an importance... 

Diorganozincs can also be prepared by a nickel-catalyzed hydrozincation. The reaction of Et2Zn with Ni(acac)2 may produce a nickel hydride that adds to an alkene leading after transmetallation with Et2Zn to a diakylzinc (Scheme 9). This reaction proceeds in the absence of solvent and at temperatures of 50-60 °C. A number of functionalized olefins like allylic alcohols or amines can be directly used. This method is especially well suited for the preparation of functionalized diorganozincs for the asymmetric addition to aldehydes (Equation (45)).108,50... 

In accessing chiral allyl vinyl ethers for Claisen rearrangement reactions, Nelson et al. employed the iridium-mediated isomerization strategy. Thus, the requisite enantioenriched diallyl ether substrate 28 was synthesized via a highly enantioselective diethylzinc-aldehyde addition protocol10 (Scheme 1.1k). The enantioselective addition of Et2Zn to cinnamaldehyde catalyzed by (—)-3-exo-morpholinoisobomeol (MIB 26)11 provided an intermediate zinc alkoxide (27). Treatment of 27 with acetic acid followed by 0-allylation in the presence of palladium acetate delivered the 28 in 73% yield and 93% ee. Isomerization of 28 with a catalytic amount of the iridium complex afforded the allyl vinyl ether... 

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