Mannich additions, asymmetric

Related catalytic enantioseiective processes Representative examples of other catalytic asymmetric Mannich additions are depicted in Scheme 6.31. In 1997, Tomioka demonstrated a Li-catalyzed synthesis of functionalized p-lactams that proceeds through a catalytic enantioseiective Mannich reaction (promoted by 103) [95], and a year later Lectka and his team published a series of reports concerning additions of silyl ketene acetals... 

The asymmetric Mannich addition of carbon nucleophiles to imines catalyzed by the cyclohexane-diamine catalysts has developed significantly in the past decade. List and co-workers reported the asymmetric acyl-cyanantion of imines catalyzed by a cyclohexane-diamine catalyst [103], Using a derivative of Jacobsen s chiral urea catalyst, the authors optimized reaction conditions and obtained chiral iV-acyl-aminonitriles in high yield and enantioselectivities (Scheme 51). The scope of the reaction was explored with both aliphatic and aromatic imines, providing good to high selectivities for a variety of substrates. 

Wenzel and Jacobsen, in 2002, identified Schiff base thiourea derivative 48 as catalyst for the asymmetric Mannich addition [72] of tert-butyldimethylsilyl ketene acetals to N-Boc-protected (hetero)aromatic aldimines (Scheme 6.49) [201]. The optimized structure of 48 was found through the construction of a small, parallel... 

Scheme 6.123 Spectrum of adducts of the 122-catalyzed asymmetric Mannich addition of dimethyl malonate to acylated aldimines.

Another catalytic application of chiral ketene enolates to [4 + 2]-type cydizations was the discovery of their use in the diastereoselective and enantioselective syntheses of disubstituted thiazinone. Nelson and coworkers described the cyclocondensations of acid chlorides and a-amido sulfones as effective surrogates for asymmetric Mannich addition reactions in the presence of catalytic system composed of O-TM S quinine lc or O-TMS quinidine Id (20mol%), LiC104, and DIPEA. These reactions provided chiral Mannich adducts masked as cis-4,5 -disubstituted thiazinone heterocycles S. It was noteworthy that the in situ formation of enolizable N-thioacyl imine electrophiles, which could be trapped by the nucleophilic ketene enolates, was crucial to the success of this reaction. As summarized in Table 10.2, the cinchona-catalyzed ketene-N-thioacyl-imine cycloadditions were generally effective for a variety of alkyl-substituted ketenes and aliphatic imine electrophiles (>95%ee, >95%cis trans) [12]. 

Chen and coworkers employed the cinchona alkaloid-derived catalyst 26 to direct Mannich additions of 3-methyloxindole 24 to the A-tosylimine 25 to afford the all-carbon quaternary center of oxindole 27 with good enantioselectivity (84% ee) [22]. The outcome of this Mannich reaction is notable in that it provided very good selectivity for the anti diastereomer (anti/syn 94 6). The mechanism of asymmetric induction has been suggested to involve a hydrogen bonding network between the cinchona alkaloid 26, the oxindole enolate of 24, and the imine electrophile 25 (Scheme 7). Asymmetric allylic alkylation of oxindoles with Morita-Baylis-Hillman carbonates has been reported by the same group [23]. 

Recently, a detailed study on the use of unprotected hydroxy-prolines in several asymmetric organocatalytic transformations was reported by Al-Momani. In the benchmark aldol addition between acetone and p-nitro-benzaldehyde, ds-3-hydroxy-proline (ds-12) afforded the best enantio-selectivity, with excellent activity (Scheme 11.13A). On the other hand, in the analogous Mannich addition, cis-12 afforded the worst enantioselectivities, albeit maintaining good catalytic activities (Scheme 11.13B). 

Recent efforts in the development of efficient routes to highly substituted yS-ami-no acids based on asymmetric Mannich reactions with enantiopure sulfmyl imine are worthy of mention. Following the pioneering work of Davis on p-tolu-enesulfmyl imines [116], Ellman and coworkers have recently developed a new and efficient approach to enantiomerically pure N-tert-butanesulfmyl imines and have reported their use as versatile intermediates for the asymmetric synthesis of amines [91]. Addition of titanium enolates to tert-butane sulfmyl aldimines and ketimines 31 proceeds in high yields and diastereoselectivities, thus providing general access to yS -amino acids 32 (Scheme 2.5)... 

Ferraris et al.108 demonstrated an asymmetric Mannich-type reaction using chiral late-transition metal phosphine complexes as the catalyst. As shown in Scheme 3-59, the enantioselective addition of enol silyl ether to a-imino esters proceeds at —80°C, providing the product with moderate yield but very high enantioselectivity (over 99%). 

In a related publication, Kobayashi and his team reported on Zr-catalyzed asymmetric Mannich reactions that utilize the more electron-rich oxygenated ketene acetals shown in Scheme 6.28 [93], A noteworthy aspect of this study was that the levels of syn/anti diaste-reocontrol proved to be dependent on the nature of the alkoxide substituent whereas the (3-TBS acetals predominantly afforded the syn isomer, the OBn derivatives afforded a larger amount of the anti isomer. As before, the presence of an additive, this time 1,2-dimeth-ylimidazole (DMI), proved to be important with regard to the level of Ti-facial selectivity. The phenol activating group can be removed by the same procedure as reported previously, with essentially identical degrees of efficiency (see Scheme 6.27). 

The studies summarized above clearly bear testimony to the significance of Zr-based chiral catalysts in the important field of catalytic asymmetric synthesis. Chiral zircono-cenes promote unique reactions such as enantioselective alkene alkylations, processes that are not effectively catalyzed by any other chiral catalyst class. More recently, since about 1996, an impressive body of work has appeared that involves non-metallocene Zr catalysts. These chiral complexes are readily prepared (often in situ), easily modified, and effect a wide range of enantioselective C—C bond-forming reactions in an efficient manner (e. g. imine alkylations, Mannich reactions, aldol additions). 

Lewis acids as water-stable catalysts have been developed. Metal salts, such as rare earth metal triflates, can be used in aldol reactions of aldehydes with silyl enolates in aqueous media. These salts can be recovered after the reactions and reused. Furthermore, surfactant-aided Lewis acid catalysis, which can be used for aldol reactions in water without using any organic solvents, has been also developed. These reaction systems have been applied successfully to catalytic asymmetric aldol reactions in aqueous media. In addition, the surfactant-aided Lewis acid catalysis for Mannich-type reactions in water has been disclosed. These investigations are expected to contribute to the decrease of the use of harmful organic solvents in chemical processes, leading to environmentally friendly green chemistry. 

In addition, quite recently a direct catalytic asymmetric Mannich-type reaction has been achieved by the cooperative catalysis of ALB and La(0Tf)3-nH20. 

The Schneider group independently reported an asymmetric vinylogous Mannich reaction (Scheme 27) [47]. Addition of silyl dienolates 73 to A-PMP-protected imines 74 was promoted by phosphoric acid (R)-3g (5 mol%, R = Mes) with mesityl substituents to afford tra i -a,p-nnsatnrated 8-amino esters 75 in high yields (66-94%) together with good enantioselectivities (80-92% ee). 

Most notably, the Antilla laboratory has employed VANOL and VAPOL phosphoric acid derivatives in several novel asymmetric transformations. In addition, TADDOL and phosphordiamide phosphoric acid derivatives have been applied in several Mannich-type reactions. 

Scheme 6.126 Mannich adducts obtained from the 121- and 124-catalyzed asymmetric addition of dialkyl malonates to N-Boc aldimines. The product configurations were not determined.

Since then, efficient catalytic asymmetric methods have been developed for the addition of silyl enol ethers or silyl ketene acetals to imines with chiral metal catalysts [29-34], Recently, direct catalytic asymmetric Mannich reactions which do not require preformation of enolate equivalents have appeared. 

List gave the first examples of the proline-catalyzed direct asymmetric three-component Mannich reactions of ketones, aldehydes, and amines (Scheme 14) [35], This was the first organocatalytic asymmetric Mannich reaction. These reactions do not require enolate equivalents or preformed imine equivalent. Both a-substituted and a-unsubstituted aldehydes gave the corresponding p-amino ketones 40 in good to excellent yield and with enantiomeric excesses up to 91%. The aldol addition and condensation products were observed as side products in this reaction. The application of their reaction to the highly enantioselective synthesis of 1,2-amino alcohols was also presented [36]. A plausible mechanism of the proline-catalyzed three-component Mannich reaction is shown in Fig. 2. The ketone reacts with proline to give an enamine 41. In a second pre-equilib-... 

The catalytic asymmetric Mannich reaction of lithium enolates with imines was reported in 1997 using an external chiral ligand [36]. First, it was found that reactions of lithium enolates with imines were accelerated by addition of external chiral ligands. Then, it was revealed that reactions were in most cases accelerated in the presence of excess amounts of lithium amides. A small amount of a chiral source was then used in the asymmetric version [(Eq. (8)], and chiral ligands were optimized to achieve suitable catalytic turnover [37]. 

Several other asymmetric Mannich-type processes have been described. Propargyl alcohols (11) undergo an addition to imines (12), to give 2-acylallylic carbamates (13), using an oxovanadium catalyst.28 The reaction always gave the (Z)-enone, but a trial with a chiral propargyl alcohol showed virtually no enantioselectivity. 

An important feature of this reaction is that in contrast to most other catalytic asymmetric Mannich reactions, a-unbranched aldehydes are efficient electrophiles in the proline-catalyzed reaction. In addition, with hydroxy acetone as a donor, the corresponding syn-l, 2-aminoalcohols are furnished with high chemo-, regio-, diastereo-, and enantioselectivities. The produced ketones 14 can be further converted to 4-substituted 2-oxazolidinones 17 and /i-aminoalcohol derivatives 18 in a straightforward manner via Baeyer-Villiger oxidation (Scheme 9.4) [5]. 

Use of hydroxyacetone as donor in the asymmetric Mannich reaction led to the formation of optically active syn /i-amino alcohols bearing two stereogenic centers [22, 23], In the presence of 35 mol% L-proline as organocatalyst several types of syn / -amino alcohol syn-35 were successfully synthesized with enantioselectivity up to 99% ee and high diastereomeric ratio. For example, a high yield of 92%, a diaster-eomeric ratio of 20 1, and enantioselectivity >99% ee were observed by List et al. for formation of the syn yfi-amino alcohol 35a (Scheme 5.17) [23]. In addition to hydroxyacetone the methylated derivative methoxyacetone was also applied successfully in this reaction (93% yield, d.r. > 39 1, >99% ee). 

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