Mukaiyama aldol reaction examples

For example in the so-called Mukaiyama aldol reaction of an aldehyde R -CHO and a trimethylsilyl enol ether 8, which is catalyzed by Lewis acids, the required asymmetric environment in the carbon-carbon bond forming step can be created by employing an asymmetric Lewis acid L in catalytic amounts. 

Another SBU with open metal sites is the tri-p-oxo carboxylate cluster (see Section 4.2.2 and Figure 4.2). The tri-p-oxo Fe " clusters in MIL-100 are able to catalyze Friedel-Crafts benzylation reactions [44]. The tri-p-oxo Cr " clusters of MIL-101 are active for the cyanosilylation of benzaldehyde. This reaction is a popular test reaction in the MOF Hterature as a probe for catalytic activity an example has already been given above for [Cu3(BTC)2] [15]. In fact, the very first demonstration of the catalytic potential of MOFs had aheady been given in 1994 for a two-dimensional Cd bipyridine lattice that catalyzes the cyanosilylation of aldehydes [56]. A continuation of this work in 2004 for reactions with imines showed that the hydrophobic surroundings of the framework enhance the reaction in comparison with homogeneous Cd(pyridine) complexes [57]. The activity of MIL-lOl(Cr) is much higher than that of the Cd lattices, but in subsequent reaction rans the activity decreases [58]. A MOF with two different types of open Mn sites with pores of 7 and 10 A catalyzes the cyanosilylation of aromatic aldehydes and ketones with a remarkable reactant shape selectivity. This MOF also catalyzes the more demanding Mukaiyama-aldol reaction [59]. 

Scheme 2.2 illustrates several examples of the Mukaiyama aldol reaction. Entries 1 to 3 are cases of addition reactions with silyl enol ethers as the nucleophile and TiCl4 as the Lewis acid. Entry 2 demonstrates steric approach control with respect to the silyl enol ether, but in this case the relative configuration of the hydroxyl group was not assigned. Entry 4 shows a fully substituted silyl enol ether. The favored product places the larger C(2) substituent syn to the hydroxy group. Entry 5 uses a silyl ketene thioacetal. This reaction proceeds through an open TS and favors the anti product. 

In aldol reactions, especially Mukaiyama aldol reactions, TiIV compounds are widely employed as efficient promoters. The reactions of aldehydes or ketones with reactive enolates, such as silyl enol ethers derived from ketones, proceed smoothly to afford /3-hydroxycarbonyl compounds in the presence of a stoichiometric amount of TiCl4 (Scheme 17).6, 66 Many examples have been reported in addition to silyl enol ethers derived from ketones, ketene silyl acetals derived from ester derivatives and vinyl ethers can also serve as enolate components.67-69... 

Mukaiyama aldol reactions of aldehydes with silyl enol ethers are amongst the most widely used Lewis-acid-mediated or -catalyzed reactions. However, trimethylsilyl triflate is not active enough to promote these reactions,66 and more active silicon-based Lewis acids have been developed. One example is the species generated by mixing trimethylsilyl triflate (or chloride) and B(OTf)3,319,320 for which the formulation R3Si + [B(OTf)4] is suggested by NMR experiments. Only a catalytic amount of this was needed to complete Mukaiyama aldol reactions of... 

Scheme 8.50. Examples of catalytic Mukaiyama aldol reactions.

Lewis acids are quite often used as catalysts in organic synthesis. Although most Lewis acids decompose in water, it was found that rare earth triflates such as Sc(OTf)3, Yb(OTf)3, etc. can be used as Lewis acid catalysts in water or water-containing solvents (water-compatible Lewis acids) [6-9]. For example, the Mukaiyama aldol reactions of aldehydes with silyl enol ethers were catalyzed by Yb(OTf)3 in water-THF (1 4) to give the corresponding aldol adducts in high yields [10, 11]. Interestingly, when the reactions were carried out in dry THF (without water), the yield of the aldol adducts was very low (ca. 10%). Thus, this catalyst is not only compatible with water but also is activated by water, probably due to dissociation of the counteranions from the Lewis acidic metal. Furthermore, the catalyst can be easily recovered and reused. 

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]. 

The directed aldol reaction in the presence of TiC found many applications in natural product synthesis. Equation (7) shows an example of the aldol reaction utilized in the synthesis of tautomycin [46], in which many sensitive functional groups survived the reaction conditions. The production of the depicted single isomer after the titanium-mediated aldol reaction could be rationalized in terms of the chelation-controlled (anft-Felkin) reaction path [37]. A stereochemical model has been presented for merged 1,2- and 1,3-asymmetric induction in diastereoselective Mukaiyama aldol reaction and related processes [47]. 

Lanthanide Lewis acids catalyze many of the reactions catalyzed by other Lewis acids, for example, the Mukaiyama-aldol reaction [14], Diels-Alder reactions [15], epoxide opening by TMSCN and thiols [14,10], and the cyanosilylation of aldehydes and ketones [17]. For most of these reactions, however, lanthanide Lewis acids have no advantages over other Lewis acids. The enantioselective hetero Diels-Alder reactions reported by Danishefsky et al. exploited one of the characteristic properties of lanthanides—mild Lewis acidity. This mildness enables the use of substrates unstable to common Lewis acids, for example Danishefsky s diene. It was recently reported by Shull and Koreeda that Eu(fod)3 catalyzed the allylic 1,3-transposition of methoxyace-tates (Table 7) [18]. This rearrangement did not proceed with acetates or benzoates, and seemed selective to a-alkoxyacetates. This suggested that the methoxy group could act as an additional coordination site for the Eu catalyst, and that this stabilized the complex of the Eu catalyst and the ester. The reaction proceeded even when the substrate contained an alkynyl group (entry 7), or when proximal alkenyl carbons of the allylic acetate were fully substituted (entries 10, 11 and 13). In these cases, the Pd(II) catalyzed allylic 1,3-transposition of allylic acetates was not efficient. 

Mukaiyama aldol reactions are useful means of constructing complex molecules for the total synthesis of natural products. Although catalytic asymmetric Mukaiyama aldol reactions have been achieved by use of a variety of chiral Lewis acids [42], no report of the use of chiral lanthanide catalysts was available until recently, despite the potency of these catalysts. Shibasaki and co-workers reported the first examples of chiral induction with chiral lanthanide complexes (Sch. 7) [43]. Catalysts prepared from lanthanide triflates and a chiral sulfonamide ligand afforded the corresponding aldol products in moderate enantiomeric excess (up to 49% ee). 

The Mukaiyama aldol reaction of ethyl ketones can lead to the controlled introduction of two adjacent stereocenters. While enolate geometry may not be trans-fened faithfully to the relative stereochemistry of the aldol product syn versus anti), stereoconvergent reactions are possible. In the example shown in Scheme 9-5, it should be noted that 7i-facial control from the chiral aldehyde is strong as both products 7 and 8 arise from Felkin selectivity [5]. 

As mentioned previously, it can be more difficult to predict syn anti diastereoselectivity in Mukaiyama aldol reactions of substituted ketones. However, the reward of high stereocontrol in these reactions is attainable as shown in Scheme 9-12. While the second example shows disappointing aldehyde face selectivity, there is strong enolate facial bias 5-anti in both 32 and 33). Therefore,... 

Mukaiyama aldol reactions. Catalyst 69 has been used in the synthesis of bryosta-tin and epothilone segments and, for example, using silyl enol ether 70 high levels of stereocontrol are possible (Scheme 9-23) [48]. This methodology has recently been used in an approach to acutiphycin [49]. 

Given this problem, the attachment of the butanone synthon to aldehyde 74 prior to the methyl ketone aldol reaction was then addressed. To ovenide the unexpected. vTface preference of aldehyde 74, a chiral reagent was required and an asymmetric. syn crotylboration followed by Wacker oxidation proved effective for generating methyl ketone 87. Based on the previous results, it was considered unlikely that a boron enolate would now add selectively to aldehyde 73. However, a Mukaiyama aldol reaction should favour the desired isomer based on induction from the aldehyde partner. In practice, reaction of the silyl enol ether derived from 87 with aldehyde 73, in the presence of BF3-OEt2, afforded the required Felkin adduct 88 with >97%ds (Scheme 9-29). This provides an excellent example of a stereoselective Mukaiyama aldol reaction uniting a complex ketone and aldehyde, and this key step then enabled the successful first synthesis of swinholide A. 

Asymmetric Aldol Reaction Although several examples showed that reaction rates with aluminum reagents exceed those with silyl cations, direct reflection on this basis to the corresponding asymmetric reaction remains challenging [8]. Apart from the Mukaiyama aldol reaction, an alternative reaction candidate was oxazole... 

Sc(() l f) ( is an effective catalyst of the Mukaiyama aldol reaction in both aqueous and non-aqueous media (vide supra). Kobayashi et al. have reported that aqueous aldehydes as well as conventional aliphatic and aromatic aldehydes are directly and efficiently converted into aldols by the scandium catalyst [69]. In the presence of a surfactant, for example sodium dodecylsulfate (SDS) or Triton X-100, the Sc(OTf)3-catalyzed aldol reactions of SEE, KSA, and ketene silyl thioacetals can be performed successfully in water wifhout using any organic solvent (Sclieme 10.23) [72]. They also designed and prepared a new type of Lewis acid catalyst, scandium trisdodecylsulfate (STDS), for use instead of bofh Sc(OTf) and SDS [73]. The Lewis acid-surfactant combined catalyst (LASC) forms stable dispersion systems wifh organic substrates in water and accelerates fhe aldol reactions much more effectively in water fhan in organic solvents. Addition of a Bronsted acid such as HCl to fhe STDS-catalyzed system dramatically increases the reaction rate [74]. 

As described in the sections above, it is well established that reactions of Lewis acid-activated aldehydes and ketones with silyl enolates afford -hydroxy or /7-sil-oxy carbonyl compounds (Mukaiyama aldol reactions). Occasionally, however, ene-type adducts, that is /-siloxy homoallyl alcohols, are the main products. The first example of the carbonyl-ene reaction of silyl enolates was reported by Snider et al. in 1983 [176]. They found that the formaldehyde-MesAl complex reacted smoothly with ketone TMS enolates to give y-trimethylsiloxy homoallyl alcohols in good yield. Yamamoto et al. reported a similar reaction of formaldehyde complexed with methylaluminum bis(2,6-diphenylphenoxide) [177]. After these early reports, Kuwajima et al. have demonstrated that the aluminum Lewis acid-promoted system is valuable for the ene reactions of several aldehydes [178] and for-maldimine [179] with silyl enolates bearing a bulky silyl group. A stepwise mechanism including nucleophihc addition via an acyclic transition structure has been proposed for the Lewis acid-promoted ene reactions. 

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... 

Another interesting example of the influence of high pressure on the regioselec-tivity in organic reactions has been observed for the Mukaiyama aldol reaction of unsaturated silyl ketene acetals (51) with aromatic aldehydes by Bellassoued, Dumas and coworkers (Scheme 8.14) [33]. The desired y-adduct 52 was the major compound up to 0.5 GPa (52 53 = 83 17) while the preference was reversed at 1.7 GPa, making the a-adduct 53 the predominant product (52 53 = 25 75). This pressure dependence of the regioselectivity may imply that the transition structure leading to the linear aldol product 52 is less compact than that in the formation of the branched aldol product 53. 

The Lewis acidic nature of these catalysts has permitted their extended use in the Mukaiyama aldol reaction. In this application of CBS reagents, one such example involved the condensation of ketene acetals 72 with aldehydes 73 to produce adducts 74.20... 

The reaction can be applied to silyl enol esters as well. Good asymmetric induction can be achieved in the Mukaiyama aldol reaction. The reaction of silyl enol thioether 246 and nonanal, for example, gave 247 in 60% yield and in 93% ee when the (/ )-BINOL-titanium catalyst shown was used. In this work, the reaction was also done in supercritical fluoroform and in supercritical carbon dioxide. A similar reaction was reported using catalysts closely related to 244 and dichloromethane as the solvent.Chiral oxazaborolidine catalysts have also been shown to be effective for enantioselective Mukaiyama aldol reactions. 

It is interesting that iron carbonyl can be used as a protecting group for dienes. Iron diene complex 491, for example, reacted with 492 in a Mukaiyama aldol reaction (sec. 9.4,C), giving an 81% yield of 493 and 494 in an 84 16 ratio.32 in a synthesis of heptitol derivatives,322 Pearson protected tropone as the iron tricarbonyl derivative (495), and prepared 496 using a multistep sequence before deprotecting the diene to give 497. 

As a result of the preliminary examples described in Sect. 3.1 and the quest for automation techniques in solution-phase synthesis, various examples of continuous flow processes appeared in the literature lately which utilized solid-phase-bound chemical catalysts. In a simple example, Yamamoto and coworkers studied the use of super Bronsted acids loaded on polystyrene beads 5 for use in a single-pass column system (Fig. 4) [30]. It was shown that these columns are suited for the acetylation of alcohols, acetalization of carbonyl compounds, Sakurai-Hosomi allylation reactions, and Mukaiyama aldol reactions. 

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