Asymmetric induction Mukaiyama aldols

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... 

Chiral sulfoximines liganded to copper(II) give highly enantioselective vinylogous Mukaiyama-type aldol reactions under mild conditions.137 A chiral sulfinyl group has been used to achieve 1,5- and 1,6-asymmetric induction in Mukaiyama aldols, using Yb(OTf)3 catalysis.138... 

Asymmetric aldol reactions.4 The borane complex 3 can also serve as the Lewis acid catalyst for the aldol reaction of enol silyl ethers with aldehydes (Mukaiyama reactions).5 Asymmetric induction is modest (80-85% ee) in reactions of enol ethers of methyl ketones, but can be as high as 96% ee in reactions of enol ethers of ethyl ketones. Moreover, the reaction is syn-selective, regardless of the geometry of the enol. However, the asymmetric induction is solvent-dependent, being higher in nitroethane than in dichloromethane. 

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]. 

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). 

Silyl enol ethers react with aldehydes in the presence of chiral boranes or other additives " to give aldols with good asymmetric induction (see the Mukaiyama aldol reaction in 16-35). Chiral boron enolates have been used. Since both new stereogenic centers are formed enantioselectively, this kind of process is called double asymmetric synthesis Where both the enolate derivative and substrate were achiral, carrying out the reaction in the presence of an optically active boron compound ° or a diamine coordinated with a tin compound ° gives the aldol product with excellent enantioselectivity for one stereoisomer. Formation of the magnesium enolate anion of a chiral amide, adds to aldehydes to give the alcohol enantioselectively. 

Aldol reactions. The Mukaiyama aldol reaction employing 1-triisopropoxy-l-r-butylthioethene as donor displays exceptional Cram-type selectivity, thus the bulk of the silyl group has a crucial effect on the level of 1,2-asymmetric induction. Bicyclic lactones are formed by treatment of a hydroxyalkylalkyne substituted with tungsten and also carrying an acetal side chain. ... 

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. 

The utility of BF3-OEt2, a monodentate Lewis acid, for acyclic stereocontrol in the Mukaiyama aldol reaction has been demonstrated by Evans et al. (Scheme 10.3) [27, 28]. The BF3-OEt2-mediated reaction of silyl enol ethers (SEE, ketone silyl enolates) with a-unsubstituted, /falkoxy aldehydes affords good 1,3-anti induction in the absence of internal aldehyde chelation. The 1,3-asymmetric induction can be reasonably explained by consideration of energetically favorable conformation 5 minimizing internal electrostatic and steric repulsion between the aldehyde carbonyl moiety and the /i-substituents. In the reaction with anti-substituted a-methyl-/ -alkoxy aldehydes, the additional stereocontrol (Felkin control) imparted by the a-substituent achieves uniformly high levels of 1,3-anti-diastereofacial selectivity. 

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... 

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. 

Aldol and imino-aldol reactions. A Yb complex prepared from YbfOTflj and a C -symmetric a,a -bistriflamidobibenzyl has been used in the Mukaiyama aldol reaction," resulting in moderate asymmetric induction. Imines are activated toward enol derivatives, such as ketene silyl ethers. iV-(a-aminoalkyl)benzotriazoles are suitable surrogates of imines. One-pot syntheses of p-amino esters and ketones can also be achieved. 

The concept developed for the asymmetric Sn-catalyzed aldol reaction with chiral Ar,AT-ligand by Mukaiyama and co-workers was further extended by Evans and co-workers with bidentate bis(oxazoline) and tridentate pyridylbis(oxazoline) ligands (186). After a survey of ligand architecture, the best level of asymmetric induction was exhibited by [Sn(S,S)-pybox](OTf)2 138 for the Mukaiyamai aldol reaction of substituted silylketene acetal and methyl pyruvate. Noteworthy, the... 

Remote asymmetric induction can be obtained through the use of chiral auxiliaries, such as valine derived oxazolidinones, within the framework of the vinylogous Mukaiyama aldol reaction. During the synthesis of khafrefungin, an antifungal agent, Kobayashi and coworkers reacted the vinylketene silyl A. O-acetal 56 with the aldehyde 57 to yield the a r/-aldol adduct 58 in excellent yield (98%) and high diastereoselectivity (> 20 1). ... 

A remarkable case of remote asymmetric induction was observed by Kobayashi and coworkers when they extended the Evans method to protocol for a vinylogous aldol addition (Scheme 4.59). For this purpose, the alkenoic imides 251 and 254 were converted into vmylketene sUyl N,0-acetals 252 and 255, respectively. When these silicon enolates, whose fr 5-configuration was assigned based upon NOE experiments, were submitted to a vinylogous Mukaiyama reaction, the adducts 253 and 256 were obtained with excellent diastereoselectivity [131]. 

Because the products of 1,7- and 1,6,7-asymmetric induction reactions have structures frequently found in polyketide compounds and multifunctional groups to be manipulated, these reactions have been applied to synthesize polyketide in short steps. For example, the saii-Helicobacter pylori agent actinopyrone A 313 was synthesized in nine steps from ent -305 (Scheme 8.52). The total synthesis started from the vinylogous Mukaiyama aldol reaction to give the C11-C18 moiety 311 as a single isomer. Protection of the secondary alcohol was followed by DIBAL reduction to give aldehyde 312. As mentioned, the methodology makes it possible to synthesize polyketide compounds in short steps. 

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. 

---