Mukaiyama aldol reaction adduct

The reaction was studied in the absence, and presence, of (MeO)2AlMe as a model catalyst for the BINOL-AlMe system. The change in relative energy for the concerted hetero-Diels-Alder reaction, and formation of the hetero-Diels-Alder adduct 11 via a Mukaiyama aldol reaction, is shown in Fig. 8.13. The conclusion of the study was that in the absence of a catalyst the concerted reaction is the most... 

Using a cyclic enone 2-29b and an ester-TMS enolate 2-30 in the presence of catalytic amounts of SmI2(THF)2, the Michael addition and the Mukaiyama/aldol reaction with the added aldehyde 2-32 led to the diastereomeric adducts 2-33 and 2-34 via 2-31 with a dr =80 20 to 98 2 and 70-77% yield (Scheme 2.7) [13]. The major product is the trans-l,2-disubstituted cycloalkanone. 

The synthesis of aldehydes from alkenes known as hydroformylation using CO and hydrogen and a homogeneous catalyst is a very important industrial process [204]. Today, over seven million tons of oxoproducts are formed each year using this procedure, with the majority of butanal and butanol from propene. To further increase the efficiency of this process it can be combined with other transformations in a domino fashion. Eilbracht and coworkers [205] used a Mukaiyama aldol reaction as a second step, as shown for the substrate 6/2-63 which, after 3 days led to 6/2-65 in 91% yield via the primarily formed adduct 6/2-64 (Scheme 6/2.13). However, employing a reaction time of 20 h gave 6/2-64 as the main product. 

Although the saturated ketone can be obtained in nearly quantitative yields, the loss of synthetically valuable functionality is unfavorable and can be overcome by a modification of the tandem sequence. The use of the corresponding unsaturated silyl enol ethers in a tandem hydroformyla-tion/Mukaiyama aldol reaction gives the desired aldol adduct with complete... 

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. 

Because these asymmetric aldol reactions are ideal methods for constructing (3-hydroxy carbonyl compounds in optically active form, the development of an asymmetric aldol reaction without the use of an organostannane would be advantageous. Yamagishi and coworkers have reported the Mukaiyama aldol reaction using trimethylsilyl enol ethers in the presence of the BINAP-AgPF6 complex to afford the adducts with moderate enantioselectivities (Table 9.9).18 They have also assigned... 

In the Mukaiyama aldol reaction an aldehyde (1) reacts with a silyl enol ether (3) under Lewis-acid catalysis to yield the aldol adduct (4). The use of a chiral Lewis acid (L offers the opportunity to perform the reaction in an a.sym-metric manner (Scheme 1) [5]. 

Mukaiyama aldol reactions of silylketene acetal and pyruvate ester (eq 14) in the presence of 10 mol % Cu[(5,5)-/-Bu-box] (OTf)2 catalyst furnish the corresponding aldol product in excellent enantiomeric excess (98%). Furthermore, the addition reactions of ketene acetals derived from /-butyl thioacetate and ben-zyloxyacetaldehyde with only 5 mol % catalyst afford the aldol product in 91% ee (eq 15). It is also noteworthy that the addition of both propionate-derived (Z)- and ( )-silylketene acetals stereoselectively forms the jyn-adduct in 97% and 85% ee, respectively. 

Mukaiyama aldol reactions of various silyl enol ethers or ketene silyl acetals with aldehydes or other electrophiles proceed smoothly in the presence of 2 mol % B(CgF5)3 [151a,c]. The following characteristic features should be noted (i) the products can be isolated as j8-trimethylsilyloxy ketones when crude adducts are worked-up without exposure to acid (ii) this reaction can be conducted in aqueous media, so that the reaction of the silyl enol ether derived from propiophenone with a commercial aqueous solution of formaldehyde does not present any problems (iii) the rate of an aldol reaction is markedly increased by use of an anhydrous solution of B(C6Fs)3 in toluene under an argon atmosphere and (iv) silyl enol ethers can be reacted with chloromethyl methyl ether or trimethylorthoformate hydroxymethyl, methoxy-methyl, or dimethoxymethyl Cl groups can be introduced at the position a to the carbonyl group. These aldol-type reactions do not proceed when triphenylborane is used (Eq. 92). 

Keck also investigated asymmetric catalysis with a BINOL-derived titanium complex [102,103] for the Mukaiyama aldol reaction. The reaction of a-benzyloxyalde-hyde with Danishefsky s dienes as functionalized silyl enol ethers gave aldol products instead of hetero Diels-Alder cycloadducts (Sch. 40) [103], The aldol product can be transformed into hetero Diels-Alder type adducts by acid-catalyzed cyclization. The catalyst was prepared from BINOL and Ti(OPr )4, in 1 1 or 2 1 stoichiometry, and oven-dried MS 4A, in ether under reflux. They reported the catalyst to be of BINOL-Ti(OPr% structure. 

One of the most powerful catalysts of the Mukaiyama aldol reaction is a chiral Ti(IV)-Schiff base complex 91 prepared from Ti(0 Pr)4 and enantiomerically pure salicylaldimine reported by Carreira [103-105]. This catalyst furnished aldol adducts in good yields and with excellent enantioselectivity. The Ti(IV)-Schiff base catalyst system is unique among the aldol catalysts yet reported in terms of operational simplicity, catalyst efficiency, chirality transfer, and substrate generality. Because the Ti(IV)-Schiff base complexes are remarkably efficient catalysts for the addition of ketene acetals to a wide variety of aldehydes, the polymeric version of catalyst 92 was prepared [106]. The activity and enantioselectivity of the polymer-supported chiral Ti(IV)-Schiff base complex were, however, much lower than were obtained from the low-molecular-weight catalyst (Eq. 28). 

Azaborolyl complex (- -)-218 has been used in a stereoselective Mukaiyama aldol reaction as illustrated in Scheme 32 <2005JA15352>. Complex (- -)-218 reacts with electron rich aromatic aldehydes and silyl ketene acetals to generate adduct 220. X-ray structures indicate the stereochemistry is as illustrated. This stereochemistry is... 

Mukaiyama aldol reaction The addition of a bulky aluminum cocatalyst (with MCjSiOTf) greatly enhances the yields of the adducts. 

Mukaiyama aldol reaction Good yields of adducts are obtained in the Zr-catalyzed process. However, due to operation of two possible competing reaction pathways, low diastereoselectivities are generally observed. 

The use of a coordinating Lewis acid allows the exploitation of chelation con trol in Mukaiyama aldol reactions. The aldol coupling shown in Scheme 9-4 led to the r/nr/-Felkin adduct 6 as the only ob.served product and was a key step in the synthesis of tautomycin [4],... 

Boron-mediated aldol reactions of -oxygenated methyl ketones are normally unselective, and chiral ligands are needed to achieve useful levels of control. However, as shown in Scheme 9-6, a Mukaiyama aldol reaction can be used where induction from silyl enol ether 13 is high, favouring adduct 14 [7, 8]. 

Mukaiyama aldol reactions catalyzed by the pybox-copper complex 65 lead to high enantiocontrol with a range of nucleophiles adding to benzyloxy acetaldehyde [44]. As shown in Scheme 9-22, catalyst 66 also led to high enantioselectiv-ities (up to 99% ee) on addition to various pyruvate esters to generate adducts 67 [45]. 

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. 

TiCl4 is used extensively as a Lewis acid in numerous organic transformations, forming adducts that mediate reactivity. Such reactions include Diels Alder, 54,355 hetero Diels Alder,356 cyclization of olefinic aldehydes,357 Flosomi Sakurai allylic coupling reactions,358 cyclopropanations,359 chal-cogen-Baylis Flillman,360 Mukaiyama Aldol reactions,36 363 reductions of ketones to alcohols 364 and stereoselective nucleophilic additions to aldehydes.365... 

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 order to reverse the diastereoselectivity in the aldol reaction, the Lewis acid-catalyzed silyl enol ether addition (73) (Mukaiyama aldol reaction) was examined. Since the Mukaiyama aldol reaction is assumed to be proceeded via an acyclic transition state, a chelation controled aldol reaction of the a-alkoxy aldehyde should be possible (74). In the presence of TiCU, the silyl enol ether derived from 14 was reacted with aldehyde 13, followed by desilylation to afford the desired anti-Felkin product 122a as a single adduct (Scheme 21). Based on precedents for chelation-controlled Mukaiyama aldol reaction (74), the exceptional high selectivity in this reaction would be accounted for by chelation of TiCl4 with the C23-methoxy group of the aldehyde 13 (eq. 13). On the other hand, when the lithium enolate derived from 14 was treated with the aldehyde 13, followed by desilylation, it gave a 1 4 ratio of the two epimers in favour of the undesired (22S)-aldol product... 

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... 

Bidentate Lewis acid. This useful catalyst (1) with a high propensity for double coordination of the carbonyl group is prepared from the corresponding phenol and two equivalents of McjAI in CH Clj at room temperature. It catalyzes the reduction of 5-nonanone by BujSnH at -78° in 86% yield, whereas a reaction in the presence of the monodentate 0-dimethylaluminum 2,6-xylenoxide affords 5-nonanol in only 6%.. Accordingly, different catalytic efficiencies are also found in the Mukaiyama aldol reaction (e.g., 87% vs. 0% in the reaction between 1-trimethylsiloxy-l-cyclohexene and benzaldehyde) and the Claisen rearrangement of (fil-cinnamyl vinyl ether (96% vs. 0%). The contrasting ( >Zi-selectivity of the Michael adducts also reflects the different coordination states. 

After pioneering work on the Lewis base-catalysed Mukaiyama aldol reaction, Mukaiyama-Michael reaction, and Mukaiyama-Mannich-type reaction with the use of lithium acetate, Mukaiyama also demonstrated the same reactions using simple sodium salts (Scheme 2.28). For example, a catalytic Mukaiyama aldol reaction between benzaldehyde and trimethylsilyl enolate using sodium methoxide in DMF proceeded smoothly under mild conditions. Moreover, the Mukaiyama-Michael reaction between chalcone and trimethylsilyl enolates using sodium acetate in DMF provided the desired Michael adduct as the major product in 92% yield along with the 1,2-adduct in 8% yield. ... 

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. 

Other chiral zinc based Lewis acid, such as zinc(II) complex with pybox, showed good stability in aqueous media and gave syn-adducts in moderate to excellent catalytic activity and enantioselectivity for asymmetric Mukaiyama aldol reactions (113,114). A simple combination of Lewis acidic zinc salt (Zn(OTf)2) and organocatalyst is also shown to be effective catalysts for the direct aldol reaction of acetone and aldehydes in the presence of water (115). 

To overcome the problem that many Lewis acidic cations hydrolyze very easily in water, Kobayashi and co-workers (187) screened various metal cations and found Pb + as a stable Lewis acid in water. And then the authors studied the combination of lead salts and chiral ligands for the catalytic Mukaiyama aldol reaction. In their efforts, chiral BINOL-derived crown was promising chiral ligand under aqueous conditions and up to 87% ee of aldol adduct was obtained in syn-selectivity (Scheme 47). 

Fig. 15.1 Proposed transition state for the anti adduct in the Zr-BINOL-catalyzed Mukaiyama aldol reaction...

Jergensen and coworkers reported Cu(OTf)2/t-Bu-BOX (13)-catalyzed Mukaiyama aldol reactions between silylketene acetals and pyridine N-oxide aldehydes (78) and (81) (Scheme 17.16) [21]. The chemical efficiencies were high and good to excellent enantioselectivities were observed. This work further expanded the scope of aldehydes capable of bidentate coordination in aldol reactions. The authors utilized aldol adduct (83) in the synthesis of indolizine alkaloid (84). 

The Mukaiyama aldol reaction is a favorable method for the synthesis of P-hydroxy carbonyl compounds in terms of environmental friendliness because the process uses less toxic silyl enolates compared to organotin enolates [52]. Yamagishi and CO workers have examined a BI NAPAg( I)-catalyzed asymmetric Mukaiyama aldol reaction with trimethylsilyl enolates and have found that the reaction is accelerated by BINAP-AgPFe in DMF containing a small amount of water to give the aldol adduct with high enantioselectivity (Scheme 18.14) [53]. 

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