Enantioselective Mannich-type reactions

Yamamoto and co-workers found that 27 is an excellent chiral promoter not only for the aza Diels-Alder reaction of aldimines [40] but also for the stereoselective aldol-type reaction of aldimines with ketene silyl acetals [55]. The reaction of (5)-benzyli-dene a-methylbenzylamine with trimethylsilyl ketene acetal derived from terf-butyl acetate in the presence of (R)-27 produces the (R) adduct in 92 % diastereomeric excess (de), whereas reaction with (5)-27 gives the adduct in 74 % de. In a similar way, (5)-butylidene a-methylbenzylamine, an aliphatic imine, can be converted to the (R)-)3-amino ester in 94 % de by use of (R)-27 (Eq. 73). 

This method can be effectively applied to the preparation of /S-lactam compounds. The ester enolate-imine condensation approach to j8-lactam formation has been developed over the past decade. Thienamycin and related carbapenems have been the focus of particular attention because of their structural uniqueness and potent antibacterial activity. 

The reaction of an acetylenic imine and silyl ketene acetal with (R)-27 as a Lewis acid catalyst produces the aldol adduct with extremely high anti selectivity anti syn = 40 1) it is converted to the /3-lactam by use of Ohno s method, which is transformed into the key intermediate for (-i-)-PS-5 (Eq. 74). 

This methodology also enables stereospecific synthesis of the side-chain of taxol [56]. The A-benzoyl-3-phenylisoserine side chain at C-13 of the taxol molecule is essential for its antitumor activity. The stereoselectivity in this reaction depends on the geometry of the silyl ketene acetal (Eq. 77). The reaction of the (E)-ketene acetal with (i )-27 produces the anti adduct with high stereoselectivity anttsyn = 98 2, 92 % de anti). In contrast, the reaction of the (Z)-silyl ketene acetal with S)-27 produces the enantiomerically pure syn adduct (symanti = 99 1, 99 % de syn). Aus, our methodology provides the first practical and efficient route for the preparation of both diastereomers of an a-hydroxy /3-amino ester. The syn adduct 52 is transformed to the desired A-benzoyl-(27 ,35)-phenylisoserine methyl ester by hydrogenolysis over a palladium catalyst then the Schotten-Baumann reaction. 

BLA 28 is very useful in the double stereodifferentiation of aldol-type reactions of chiral imines [41], Reaction of (5)-benzylidene-a-methylbenzylamine with trimethyl-silyl ketene acetal derived from tert-butyl acetate in the presence of (R)-28 at -78 °C for 12 h provides the corresponding aldol-type adduct in 94 % de (Eq. 78). Including phenol in the reaction mixture does not influence the reactivity or the diastereoselec-tivity. The aldol-type reaction using yellow crystals of (R)-28.(5)-benzylidene-a-methylbenzylamine PhOH proceeds with unprecedented ( 99.5 0.5) diastereoselec-tivity (Eq. 79). In general, 28 is a more efficient chiral Lewis acid promoter than 27. 

---

More recently, asymmetric Mannich-type reactions have been studied in aqueous conditions. Barbas and co-worker reported a direct amino acid catalyzed asymmetric aldol and Mannich-type reactions that can tolerate small amounts of water (<4 vol%).53 Kobayashi found that a diastereo- and enantioselective Mannich-type reaction of a hydrazono ester with silyl enol ethers in aqueous media has been successfully achieved with ZnF2, a chiral diamine ligand, and trifluoromethanesul-fonic acid (Eq. 11.31).54 The diastereoselective Mannich-type reaction... 

Highly enantioselective Mannich-type reactions of A-(2-hydroxyphenyl) aldi-mines with ketene trimethylsilyl acetals and of A-Boc-aldimines with acetyl acetone or furan are catalyzed by chiral phosphonic acids 9 derived from 3,3 -diaryl-(l )-BlNOL and POCI3 (Scheme 12.7). ... 

Aldol reactions of silyl enolates are promoted by a catalytic amount of transition metals through transmetallation generating transition metal enolates. In 1995, Shibasaki and Sodeoka reported an enantioselective aldol reaction of enol silyl ethers to aldehydes using a Pd-BINAP complex in wet DMF. Later, this finding was extended to a catalytic enantioselective Mannich-type reaction to a-imino esters by Sodeoka s group [Eq. (13.21)]. Detailed mechanistic studies revealed that the binuclear p-hydroxo complex 34 is the active catalyst, and the reaction proceeds through a palladium enolate. The transmetallation step would be facilitated by the hydroxo ligand transfer onto the silicon atom of enol silyl ethers ... 

In 1997, Kobayashi and colleagues reported the first truly catalytic enantioselective Mannich-type reactions of aldimines 24 with silyl enolates 37 using a novel chiral zirconium catalyst 38 prepared from zirconium (IV) fert-butoxide, 2 equivalents of (R)-6,6 -dibromo-l,l -bi-2-naphthol, and N-methylimidazole (Scheme 13) [27, 28], In addition to imines derived from aromatic aldehydes, those derived from heterocyclic aldehydes also worked well in this reaction, and good to high yields and enantiomeric excess were obtained. The hydroxy group of the 2-hydroxyphenylimine moiety, which coordinates to the zirconium as a bidentate ligand, is essential to obtain high selectivity in this method. 

Another important means of mediation of metal-free catalytic enantioselective Mannich-type reactions is via electrophilic activation of the preformed imines by chiral Bronstedt acids [7, 8, 46], By using this strategy Terada and coworkers performed chiral phosphoric acid-catalyzed direct asymmetric Mannich-type reactions between Boc-protected imines and acetoacetone that furnished aryl /3-amino... 

Akiyama T, Itoh J, Yokota K, Fuchibe K (2004) Enantioselective Mannich-type reaction catalyzed by a chiral Brpnsted acid. Angew Chem Int Ed Engl 43 1566-1568... 

Akiyama T, Morita H, Itoh J, Fuchibe K (2005a) Chiral Brpnsted acid catalyzed enantioselective hydrophosphonylation of imines asymmetric synthesis of alpha-amino phosphonates. Qrg Lett 7 2583-2585 Akiyama T, Saitoh Y, Morita H, Fuchibe K (2005b) Enantioselective Mannich-type reaction catalyzed by a chiral Bronsted acid derived from TADDOL. Adv Synth Catal 347 1523-1526... 

Achari B, Mandal SB, Dutta PK, Chowdhury C (2004) Synlett 2004 2449 Aggarwal VK, Belfield AJ (2003) Catalytic asymmetric Nazarov reactions promoted by chiral Lewis acid complexes. Org Lett 5 5075-5078 Akiyama T, Itoh J, Fuchibe K (2006c) Adv Synth Catal 348 999 Akiyama T, Itoh J, Yokota K, Fuchibe K (2004) Enantioselective Mannich-type reaction catalyzed by a chiral Brpnsted acid. Angew Chem Int Ed Engl 43 1566-1568... 

Kobayashi and co-workers. used zirconium-based bromo-BINOL complex for the catalytic enantioselective Mannich-type reaction. The o-hydroxyphenyl imine 3.36 chelates the Zr(IV)(BrBINOL)2 to form the activated chiral Lewis acid complex A. The ketone acetal 3.37 reacts with the Lewis acid complex A to give the complex B. The silyl group is then transferred to the 3-amino ester to form the product 3.38 and the catalyst Zr(BrBINOL)2 is regenerated, which is ready for binding with another imine molecule (Scheme 3.16). 

Cationic Pd complexes can be applied to the asymmetric aldol reaction. Shibasaki and coworkers reported that (/ )-BINAP PdCP, generated from a 1 1 mixture of (i )-BINAP PdCl2 and AgOTf in wet DMF, is an effective chiral catalyst for asymmetric aldol addition of silyl enol ethers to aldehydes [63]. For instance, treatment of trimethylsi-lyl enol ether of acetophenone 49 with benzaldehyde under the influence of 5 mol % of this catalyst affords the trimethylsilyl ether of aldol adduct 113 (87 % yield, 71 % ee) and desilylated product 114 (9 % yield, 73 % ee) as shown in Sch. 31. They later prepared chiral palladium diaquo complexes 115 and 116 from (7 )-BINAP PdCl2 and (i )-p-Tol-BINAP PdCl2, respectively, by reaction with 2 equiv. AgBF4 in wet acetone [64]. These complexes are tolerant of air and moisture, and afford similar reactivity and enantioselec-tivity in the aldol condensation of 49 and benzaldehyde. Sodeoka and coworkers have recently developed enantioselective Mannich-type reactions of silyl enol ethers with imi-nes catalyzed by binuclear -hydroxo palladium(II) complexes 117 and 118 derived from the diaquo complexes 115 and 116 [65]. These reactions are believed to proceed via a chiral palladium(fl) enolate. 

Ishitani, H., Ueno, M., Kobayashi, S. Catalytic Enantioselective Mannich-Type Reactions Using a Novel Chiral Zirconium Catalyst. J. Am. Chem. Soc. 1997, 119, 7153-7154. 

The development of enantioselective Mannich-type reactions is an important subject in synthetic organic chemistry, because fhese reactions provide optically active nitrogen-containing compounds which are very valuable in syntheses of biologically active products and their derivatives. Until recently, this subject had been solved by use of chiral auxiharies [215]. In recent years, catalytic asymmetric Mannich-type reactions using chiral Lewis acids have been studied extensively [216]. This section deals wifh chiral Lewis acid-promoted reactions. 

The use of 85b as catalyst is effective in highly enantioselective Mannich-type reaction of benzoylhydrazones [224]. 

Quite recently, chiral diamine ligands have been used by Kobayashi et al. for highly enantioselective Mannich-type reactions [228, 229]. The chiral complex prepared from chiral diamine 89a and Cu(OTf)2 effects highly enantioselective addition of silyl enolates to a-N-acyhmino esters (Scheme 10.82) [228]. The first example of catalytic asymmetric Mannich-type reaction in aqueous media has been achieved by the combined use of ZnF2, diamine 89b, and TfOH in the reaction of a-hydrazono esters [229]. 

The development of a catalytic, enantioselective Mannich-type reaction of si-lyl ketene acetals lagged far behind the now-well-established enantioselective Mukaiyama directed aldol addition. The major consideration for the invention of such a transformation is obviously the selection of an appropriate Lewis acid activator. This is a challenging problem in view of the basicity of the imine nitrogen, the ambiguity in complexation geometry, and most importantly the release of the catalyst to effect turnover. Thus, it is not surprising that the first successful catalytic, enantioselective Mannich reaction was reported only in 1997. 

Kobayashi and co-workers discovered catalytic enantioselective Mannich-type reactions of silyl enol ethers of thiol esters with aldimines using a novel zirconium catalyst. For example, in the presence of 10 mol% of catalyst 28, the silyl enol ether 20 was treated with aldimine 26 in CH2CI2 at -45 °C in the co-existence of N-methylimidazole (NMl) as an additive to afford the adduct 27 in 78% yield with 88% ee (Scheme 6) [36]. 

Scheme 9.24 Highly enantioselective Mannich-type reaction using a chiral niobium complex, reported by Kobayashi. ...

SCHEME 4.5. Acyclic amino acid- and primary amine-catalyzed one-pot three-component enantioselective Mannich-type reaction. 

While I have focused on the developments of direct Mannich-type reactions when using aminocatalysis, there are several other important metal-free activation modes for achieving these types of transformations. In this context, an important way of accomplishing the metal-free catalytic enantioselective Mannich-type reaction is by use of chiral Brpnsted acids as catalysts [7, 8, 74]. Here, Uraguchi and Terada disclosed chiral-phosporic acid-catalyzed Mannich-type reactions using acetoacetone as nucleophile and Boc-protected imines as acceptors (Scheme 4.15) [74]. 

ESI Mechanistic study of palladium complex-catalyzed enantioselective Mannich-type reaction Fujii et al. [238]... 

Fujii, A., Hagiwara, E., Sodeoka, M. (1999) Mechanism of Palladium Complex-catalyzed Enantioselective Mannich-type Reaction Characterization of a Novel Bin-uclear Palladium Enolate Complex. J. Am. Chem. Soc. 121 5450-5458. 

Ricci and coworkers [64] studied oxazoline moiety fused with a cyclopenta[P]thio-phene as ligands on the copper-catalyzed enantioselective addition of Et2Zn to chalcone. The structure of the active Cu species was determined by ESI-MS. Evans and coworkers [65] studied C2-symmetric copper(II) complexes as chiral Lewis acids. The catalyst-substrate species were probed using electrospray ionization mass spectrometry. Comelles and coworkers studied Cu(II)-catalyzed Michael additions of P-dicarbonyl compounds to 2-butenone in neutral media [66]. ESI-MS studies suggested that copper enolates of the a-dicarbonyl formed in situ are the active nucleophilic species. Schwarz and coworkers investigated by ESI-MS iron enolates formed in solutions of iron(III) salts and [3-ketoesters [67]. Studying the mechanism of palladium complex-catalyzed enantioselective Mannich-type reactions, Fujii and coworkers characterized a novel binuclear palladium enolate complex as intermediate by ESI-MS [68]. 

Carretero and coworkers have successfully employed a copper(I)-Fesulphos complex as a Lewis acid for enantioselective Mannich-type reactions of N-sulfonyl imines [43]. A combination of [151 CuBr]2 and AgCl04 does efficiently catalyze the addition of silyl enol ethers of ketones, esters, and thioesters (150) to N-(2-thienyl)sulfonyl aldimines (Scheme 17.30). The corresponding P-amino carbonyl derivatives (152) were isolated in good yields with generally good enan-tioselectivity. 

Completely different reaction conditions for the synthesis of enantiopure quinazolines 1153 relied on Lewis acid catalysis. In particular, treatment of quinazoline 1163 with cyclopropyl acetylene and Zn(OTf)2 in the presence of chiral additive 1164 (Scheme 247) [706] was extended to enantioselective diynylation of quinazolines [707]. An example of using organocatalysis included enantioselective Mannich-type reaction of 1166 or its analogues with ketones in the presence of chiral diamine 1167 and L-dibenzoyltartaric acid (L-DBT) (Scheme 248) [708]. In the latter case, the enantioselectivity was moderate, it might be improved to >99 % by a single recrystallization of the product. 

A new type of Bronsted acid-assisted chiral Bronsted acid (chiral BBA) catalyst (30) possessing a bis(triflyl)methyl group was developed for enantioselective Mannich-type reaction by Yamamoto, Ishihara and coworkers [35]. The authors proposed the two possible chiral BBA form generated through intramolecular hydrogen bonding as shown in Scheme 1.34. 

Scheme 1.35 Enantioselective Mannich-type reactions catalyzed by chiral BBA (30).

---