Mukaiyama Chiral Lewis acid catalyzed

The BINAP silver(I) complex can be further applied as a chiral catalyst in the asymmetric aldol reaction. Although numerous successful methods have been developed for catalytic asymmetric aldol reaction, most are the chiral Lewis acid-catalyzed Mukaiyama aldol reactions using silyl enol ethers or ketene silyl acetals [32] and there has been no report which includes enol stannanes. Yanagisawa, Yamamoto, and their colleagues found the first example of catalytic enantioselective aldol addition of tributyltin enolates 74 to aldehydes employing BINAP silver(I) complex as a catalyst (Sch. 19) [33]. 

Catalytic asymmetric aldol reactions provide one of the most powerful carbon-carbon bond-forming processes affording synthetically useful chiral )ff-hydroxy ketones and esters [25]. Chiral Lewis acid-catalyzed reactions of silyl enol ethers with aldehydes (the Mukaiyama reaction) [3] are among the most convenient and promising, and several successful examples have been reported since the first chiral tin(II)-cat-alyzed reactions appeared in 1990 [26]. Some common characteristics of these cat-... 

Scheme 2.8 gives some examples of chiral Lewis acids that have been used to catalyze aldol and Mukaiyama reactions. 

Asymmetric Lewis-Acid Catalyzed. Another important advance in aqueous Mukaiyama aldol reaction is the recent success of asymmetric catalysis.283 In aqueous ethanol, Kobayashi and co-workers achieved asymmetric inductions by using Cu(OTf)2/chiral >A(oxazoline) ligand,284 Pb(OTf)2/chiral crown ether,285 and Ln(OTf)3/chiral Mv-pyridino-18-crown-6 (Eq. 8.105).286... 

A chiral Lewis acid derived from Sn(OTf)2 and the proline derivative 17 has proven to catalyze the aldol reaction effectively. As Mukaiyama et al. [7J demonstrated, a high degree of enantio-selectivity was achieved (Scheme 3b). 

Transformations involving chiral catalysts most efficiently lead to optically active products. The degree of enantioselectivity rather than the efficiency of the catalytic cycle has up to now been in the center of interest. Compared to hydrogenations, catalytic oxidations or C-C bond formations are much more complex processes and still under development. In the case of catalytic additions of dialkyl zinc compounds[l], allylstan-nanes [2], allyl silanes [3], and silyl enolethers [4] to aldehydes, the degree of asymmetric induction is less of a problem than the turnover number and substrate tolerance. Chiral Lewis acids for the enantioselective Mukaiyama reaction have been known for some time [4a - 4c], and recently the binaphthol-titanium complexes 1 [2c - 2e, 2jl and 2 [2b, 2i] have been found to catalyze the addition of allyl stannanes to aldehydes quite efficiently. It has been reported recently that a more active catalyst results upon addition of Me SiSfi-Pr) [2k] or Et2BS( -Pr) [21, 2m] to bi-naphthol-Ti(IV) preparations. 

Optically active l,l -binaphthols are among the most important chiral ligands of a variety of metal species. Binaphthol-aluminum complexes have been used as chiral Lewis acid catalysts. The l,T-binaphthyl-based chiral ligands owe their success in a variety of asymmetric reactions to the chiral cavity they create around the metal center [107,108]. In contrast with the wide use of these binaphthyls, the polymer-supported variety has been less popular. The optically active and sterically regular poly(l,l -bi-naphthyls) 96 have been prepared by nickel-catalyzed dehalogenating polycondensation of dibromide monomer 95 (Sch. 7) [109] and used to prepare the polybinaphthyl aluminum(III) catalyst 97 this had much greater catalytic activity than the corresponding monomeric catalyst when used in the Mukaiyama aldol reaction (Eq. 29). Unfortunately no enantioselectivity was observed in the aldol reaction. 

The synthesis of the C1-C9 fragment 120 began with an auxiliary controlled aldol reaction of the chloroacetimide 121, where chlorine is present as a removable group to ensure high diastereoselectivity in what would otherwise have been a non-selective addition (Scheme 9-39). The Lewis acid-catalyzed, Mukaiyama aldol reaction of dienyl silyl ether 122 with / -chiral aldehyde 123 proceeded with 94%ds, giving the 3-anti product 124, as predicted by the opposed dipoles model [3]. Anti reduction of the aldol product and further manipulation then provided the C1-C9 fragment 120 of the bryostatins. 

In recent years, catalytic asymmetric Mukaiyama aldol reactions have emerged as one of the most important C—C bond-forming reactions [35]. Among the various types of chiral Lewis acid catalysts used for the Mukaiyama aldol reactions, chirally modified boron derived from N-sulfonyl-fS)-tryptophan was effective for the reaction between aldehyde and silyl enol ether [36, 37]. By using polymer-supported N-sulfonyl-fS)-tryptophan synthesized by polymerization of the chiral monomer, the polymeric version of Yamamoto s oxazaborohdinone catalyst was prepared by treatment with 3,5-bis(trifluoromethyl)phenyl boron dichloride ]38]. The polymeric chiral Lewis acid catalyst 55 worked well in the asymmetric aldol reaction of benzaldehyde with silyl enol ether derived from acetophenone to give [i-hydroxyketone with up to 95% ee, as shown in Scheme 3.16. In addition to the Mukaiyama aldol reaction, a Mannich-type reaction and an allylation reaction of imine 58 were also asymmetrically catalyzed by the same polymeric catalyst ]38]. 

The catalytic, enantioselective, vinylogous Mannich reaction has recently emerged as a very powerful tool in organic synthesis for the assembly of highly functionalized and optically enriched 6 amino carbonyl compounds. Two distinctly different strategies have been developed. The first approach calls for the reaction of preformed silyl dienolates as latent metal dienolates that react in a chiral Lewis acid or Bronsted acid catalyzed Mukaiyama type reaction with imines. Alternatively, unmodified CH acidic substrates such as a,a dicyanoalkenes or 7 butenolides were used in vinylo gous Mannich reactions that upon deprotonation with a basic residue in the catalytic system generate chiral dienolates in situ. 

In all of the examples considered so far, the chiral element has been employed in stoichiometric quantities. Ultimately, it would be desirable to require only a small investment from the chirality pool. This is only possible if the chiral species responsible for enantioselectivity is catalytic. It is worth stating explicitly that, in order to achieve asymmetric induction with a chiral catalyst, the catalyzed reaction must proceed faster than the uncatalyzed reaction. One example of an asymmetric aldol addition that has been studied is variations of the Mukaiyama aldol reaction [110] whereby silyl enol ethers react with aldehydes with the aid of a chiral Lewis acid. These reactions proceed via open transition structures such as those shown in Figure... 

Reports of the use of chiral aluminum Lewis acids in the asymmetric aldol reaction are quite limited. The first enantioselective aluminum-catalyzed Mukaiyama aldol reaction was reported about 10 years ago (158). In this asymmetric version, /5-hydroxy ester was formed in high enantiomeric excess by the ketene silyl acetal with aldehyde in the presence of a chiral Lewis acid prepared from diethylaluminum chloride (Et2AlCl) and chiral diol derived from... 

Enantioselective Mukaiyama-aldol and Sakurai-Hosomi allylation reactions catalyzed by chiral Lewis acid are currently of great interest because of their utility for the introduction of asymmetric centers and functional groups. 

In 1986, Reetz et al. provided the first indication that asymmetry in catalyzed Mukaiyama aldol reactions could be induced by substoichiometric quantities of chiral Lewis acid complexes. The Ti(IV)-BINOL complex 71 and the Al(III)-based Lewis acids 72 and 73 were evaluated as... 

The sense of asymmetric induction was the same as observed in BINOL-H-catalyzed asymmetric reactions such as carbonyl-ene reaction (55-57,59) and Mukaiyama-aldol reaction (40,41) regardless of the preparative procedure of the catalysts (/ )-BINOL-Ti catalyst produces an (/ )-alcohol product. This F-C reaction would not proceed through a six-membered transition state (A) involving a chiral Lewis acid, which has been reported to preferentially produce an orrAo-F-C-product in the reaction of phenol (19,24) or 1-naphthol (25). In sharp contrast, the para-isomer was obtained as the major product in our case. 

The asymmetric aldol reaction is one of the most important topics in modern catalytic synthesis [54]. The products, namely />-hydroxy carbonyl compounds, have a broad range of applications and play a key role in the production of pharmaceuticals [55], Since the discovery of the catalytic asymmetric aldol reaction with enolsi-lanes by Mukaiyama et al. [56], steady improvements of the metal-catalyzed asymmetric aldol reaction have been made by many groups [57]. For this type of aldol reaction a series of chiral metal catalysts which act as Lewis acids activating the aldol acceptor have been shown to be quite efficient. It was recently shown by the Shibasaki group that the asymmetric metal-catalyzed aldol reaction can be also performed with unmodified ketones [57a], During the last few years, several new concepts have been developed which are based on use of organocatalysts [58], Enolates and unmodified ketones can be used as aldol donors. 

Catalyzed enantioselective Mukaiyama-aldol reactions have been developed extensively [101] and chiral polymer-supported Lewis acids are the catalysts of choice. Polymer-supported chiral A(-sulfonyloxazaborohdinones 86 and 87, prepared by copolymerization of styrene, divinylbenzene, and chiral monomers derived from L-valine and L-glutamic acid, respectively, have been used for aldol reactions [102]. The rates of reaction using the polymeric catalysts were slow and enantioselectivity was lower than was obtained by use of the low-molecular-weight counterpart (88). The best ee obtained by use of the polymeric catalyst was 90 % ee with 28 % isolated yield in the asymmetric aldol reaction of benzaldehyde with 89 (Eq. 27). 

Catalysts formed from Me2Zn and binaphthol 3.7 (R = H) have been used for asymmetric ene-reactions [778]. Enantioselective ring opening of meso-epoxides by n-BuSH is catalyzed by a potassium tartrate/ZnCl2 complex [559, 778, 805]. Mukaiyama and coworkers have shown that reaction of Et2Zn with chiral sulfamides 3.15 (R = PI1CH2, r-Pr) generates Lewis acids [806] that catalyze asymmetric reactions of aldehydes with ketene acetals. 

In analogy t 0 the Cu(II) complex systems, the silver(I) -catalyzed aldol reaction is also proposed to proceed smoothly through a Lewis acidic activation of carbonyl compounds. Since Ito and co-workers reported the first example of the asymmetric aldol reaction of tosylmethyl isocyanide and aldehydes in the presence of a chiral silver(I)-phosphine complex (99,100), the catalyst systems of sil-ver(I) and chiral phosphines have been applied successfully in the aldol reaction of tin enolates and aldehydes (101), Mukaiyama aldol reaction (102), and aldol reaction of alkenyl trichloroacetates and aldehydes (103). In the Ag(I)-disphosphine complex catalyzed aldol reaction, Momiyama and Yamamoto have also examined an aldol-type reaction of tin enolates and nitrosobenzene with different silver-phosphine complexes (Scheme 15). The catalytic activity and enantioselectivity of AgOTfi(f )-BINAP (2 1) complex that a metal center coordinated to one phosphine and triflate were relay on solvent effect dramatically (Scheme) (104). One catalyst system solves two problems for the synthesis of different O- and AT-nitroso aldol adducts under controlled conditions. 

The use of chiral copper Lewis acids in enantioselective aldol processes has seen rapid development over the past 10 years. In particular, copper-catalyzed variants of the Mukaiyama aldol reaction received considerable attention in the years leading up to the new millennium. Evans and coworkers first demonstrated Cu(II)/pybox complex (59) as an efficient catalyst for highly enantioselective addition of a variety of silylketene acetals to aldehydes capable ofbidentate coordination (Scheme 17.12) [17]. In reactions utilizing silylketene acetals (61) and (63) with an additional stereoelement, diastereoselectivities and enantioselectivities were also high. A square pyramidal model (65), which has been further supported by a crystal structure of the complex, with the a-alkoxy aldehyde bound in a bidentate fashion accounts for the observed selectivity. 

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