Lewis acids chiral nonracemic

To accelerate aUylation with aUylstaimanes, addition of a Lewis acid is often required, because coordination of the Lewis acid to the carbonyl can enhance the electrophilicity of the substrate and facilitate the couphng reaction. Since Yamamoto showed that a nonracemic Lewis acid, chiral (acyloxy)borane (CAB), catalyzed enantioselective allylation [73], chiral Lewis acid catalysts have been extensively developed. Above all, easily available chiral compounds such as BINOL and BINAP have been most frequently used as chiral auxiliaries [74], and enantioselective allylations of C-N double bonds and of carbonyl groups have been achieved [48a, 75]. 

Lewis acid catalyzed carbonyl addition reactions of nonracemic chiral allylsilanes34 were shown to proceed with anti-S E attack, thus also enabling 1,3-chirality transfer in an opposite direction (Section D.l. 3.3.3.5.2.3.). 

An alternative route to nonracemic a-alkoxy stannanes entails the reduction of acyl stannanes with chiral hydrides61 62. Accordingly, conjugated stannyl enones yield (S)-a-alkoxy allylic stannanes by reduction with (J )-(+)-BINAL-H. As expected, (S)-(—)-BINAL-H gives rise to the enantiomeric (7 )-a-alkoxy allylic stannanes (equation 29)61. Upon treatment with Lewis acids, these stannanes undergo a stereospecific anti 1,3-isomerization to the (Z)-y-alkoxy allylic stannanes61. 

This Diels-Alder reaction proceeds in an enantioselective fashion in the presence of chiral, nonracemic Lewis acid catalysts. 2-Pyridinecarbaldehyde and 3-pyridinecarbaldehyde undergo high-yielding addition with Danishefsky s diene in the presence of [(f )-BINOL]2-Ti(OPr )4 complex in 99% and 98% ee, respectively <2005T5822>. 

The effectiveness of various substituted BINOL ligands 12-16 in the Zr(IV)-or Ti(IV)-catalyzed enantioselective addition of allyltributyltin to aldehydes was also investigated by Spada and Umani-Ronchi [21], The number of noteworthy examples of asymmetric allylation of carbonyl compounds utilizing optically active catalysts of late transition metal complexes has increased since 1999. Chiral bis(oxazolinyl)phenyl rhodium(III) complex 17, developed by Mo-toyama and Nishiyama, is an air-stable and water-tolerant asymmetric Lewis acid catalyst [23,24]. Condensation of allylic stannanes with aldehydes under the influence of this catalyst results in formation of nonracemic allylated adducts with up to 80% ee (Scheme 3). In the case of the 2-butenyl addition reac-... 

Jorgensen et al. reported that C2-symmetric bis(oxazoline)-copper(II) complex 25 also acts as chiral Lewis acid catalyst for a reaction of allylic stannane with ethyl glyoxylate [37]. Meanwhile, p-Tol-BINAP-CuCl complex 26 was shown to be a promising chiral catalyst for a catalytic enantioselective allylation of ketones with allyltrimethoxysilane under the influence of the TBAT catalyst [38]. Evans and coworkers have developed (S,S)-Ph-pybox-Sc(OTf)3 complex 27 as a new chiral Lewis acid catalyst and shown that this scandium catalyst promotes enantioselective addition reactions of allenyltrimethylsilanes to ethyl glyoxylate [39]. But, when the silicon substituents become bulkier, nonracemic dihydrofurans are predominantly obtained as products of [3+2] cycloaddition. 

P, P] An enantioselective version of the foregoing reaction has been reported by Mukaiyama and co-workers (71). In this procedure, a tin(II) enolate prepared in an analogous manner to the above was complexed with chiral, nonracemic diamines 42.1 and 42.2 (Scheme 42). Addition of the resulting undefined complexes to benzalacetone in the presence of a Lewis acid results in exclusive formation of the anti diastereomer. Although the absolute configuration of the products has not been established, products with optical purities of 80% when amine 42.1 and 93% when 42.2 are used are constructed. 

Case Study (+)-Estrone 24. The Dane-style estrone synthesis provides a classic example of stereoselective access to an envisaged target molecule. The Diels-Alder reactions between 14 and 15a or 19a are chirogenic71 reaction steps or, put another way, the enantioselective access to the Diels-Alder adducts can already be set at this stage. This requires, for example, the participation of a nonracemic Lewis acid with the right sense of chirality. In the presence of a Ti-TADDOLate [42], cycloadduct 20a was thus obtained from the Dane diene 14 and the bidentate dienophile 19a and was further transformed via 23 into (+)-estrone 248) [33d]. 

The third subsection of this chapter discusses the a-funtionalisation of aldehydes and ketones. a-Oxidation, amination and halogenation have recently been achieved with high levels of enantioselectivity using enantiopure Lewis acids, or by generation of chiral nonracemic metal enolates, in the presence of a suitable electrophilic heteroatom source. Similar levels of selectivity in this transformation are obtained via the intermediacy of chiral enamines generated using organocatalysts. 

Chiral nonracemic a-hydoxylated ketones are commonly accessed by asymmetric epoxidation or dihydroxylation of enol ethers and this methodology is discussed in the relevant sections of this book. Another general method for the enantioselective a-oxygenation of ketones and aldehydes is by reaction of an electrophilic source of oxygen with chiral nonracemic enamines or enolates or in the presence of Lewis acids. 

The asymmetric fluorination of 3-ketoesters has been achieved in 62-90% ee using F-TEDA (Selectfluor) as fluorine source in the presence of 0.5 mol% of the chiral nonracemic titanium-based Lewis acid (5.108). ° A greater range of p-ketoesters are fluorinated with higher ee using catalytic quantities of the palladium-BINAP complex (5.109) and N-fluorobenzenesulfonamide (NFSI). ° In both cases the reaction proceeds through the intermediacy of a chiral enolate. 

The addition of cyanide to aldehydes and some ketones has also been achieved in a highly enantioselective manner using a wide variety of catalyst systems including chiral nonracemic Lewis acids, Lewis bases, bifunctional catalysts and even small peptides. 

The hydrophosphonylation of aldehydes can also proceed enantioselectively in the presence of chiral nonracemic Lewis acids and some bifunctional catalysts and a small subchapter discusses recent advances in this area. 

Compared with chiral nonracemic a-amino carbonyl compounds - which are not suitable substrates for MBH reaction, mainly due to their racemization under normal conditions after prolonged exposure times to catalyst or due to poor diastereoselectivity " a-keto lactams, enantiopure 3-oxo-azetidin-2-ones 168, readily react with various activated vinyl systems promoted by DABCO to afford the corresponding optically pure MBH adducts 169 without detectable epimerization (Scheme 1.69). " However, the Lewis acid-mediated reaction of electron-deficient alkynes with azetidine-2,3-diones 168 as an entry to p-halo MBH adduets was not very sueeessful the coupling product 170 was achieved with concomitant acetonide cleavage as a single ( )-isomer in low yield, in the presence of trimethylsilyl iodide under BF3 OEt2-induced catalysis (Scheme 1.69). 

The additions of chiral nonracemic allenylmetal reagents to chiral a-methyl propanal derivatives have been proven useful for the assembly of polypropionate fragments. These reagents rely on allene chirality to favor one of the two possible diastereomeric transition states in the addition and, thus, differ in a fundamental way from the aforementioned methods in which a chiral auxiliary or catalyst provides the control element. For example, a chiral allenylstannane 246 is added to a chiral aldehyde (S)-230, derived from the Roche ester, in the presence of various Lewis acid promoters to afford any of the four diastereo-mers with excellent diastereo- and enantioselectivity, depending on the reaction conditions. Representative results are depicted in Scheme 10.48. From the stereocontrol point of view, these transformations follow Cram-fike open transition state models without or with chelation, respectively. If InBr3, SnCLi, BuaSnCl, or other additives... 

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