Cinchona alkaloids asymmetric hydrogenations

Azirines can be prepared in optically enriched form by the asymmetric Neber reaction mediated by Cinchona alkaloids. Thus, ketoxime tosylates 173, derived from 3-oxocarhoxylic esters, are converted to the azirine carboxylic esters 174 in the presence of a large excess of potassium carbonate and a catalytic amount of quinidine. The asymmetric bias is believed to be conferred on the substrate by strong hydrogen bonding via the catalyst hydroxyl group <96JA8491>. 

Catalytic asymmetric hydrogenation is a relatively developed process compared to other asymmetric processes practised today. Efforts in this direction have already been made. The first report in this respect is the use of Pd on natural silk for hydrogenating oximes and oxazolones with optical yields of about 36%. Izumi and Sachtler have shown that a Ni catalyst modified with (i ,.R)-tartaric acid can be used for the hydrogenation of methylacetoacetate to methyl-3-hydroxybutyrate. The group of Orito in Japan (1979) and Blaser and co-workers at Ciba-Geigy (1988) have reported the use of a cinchona alkaloid modified Pt/AlaO.i catalyst for the enantioselective hydrogenation of a-keto-esters such as methylpyruvate and ethylpyruvate to optically active (/f)-methylacetate and (7 )-ethylacetate. 

The enantioselective hydrogenation of prochiral substances bearing an activated group, such as an ester, an acid or an amide, is often an important step in the industrial synthesis of fine and pharmaceutical products. In addition to the hydrogenation of /5-ketoesters into optically pure products with Raney nickel modified by tartaric acid [117], the asymmetric reduction of a-ketoesters on heterogeneous platinum catalysts modified by cinchona alkaloids (cinchonidine and cinchonine) was reported for the first time by Orito and coworkers [118-121]. Asymmetric catalysis on solid surfaces remains a very important research area for a better mechanistic understanding of the interaction between the substrate, the modifier and the catalyst [122-125], although excellent results in terms of enantiomeric excesses (up to 97%) have been obtained in the reduction of ethyl pyruvate under optimum reaction conditions with these Pt/cinchona systems [126-128],... 

While this manuscript was under preparation, a considerable number of examples of sohd-phase-attached catalysts appeared in the literature which is a clear indication for the dynamic character of this field. These include catalysts based on palladium [131, 132], nickel [133] and rhodium [134] as well applications in hydrogenations including transfer hydrogenations [135, 136] and oxidations [137]. In addition various articles have appeared that are dedicated to immobilized chiral h-gands for asymmetric synthesis such as chiral binol [138], salen [139], and bisoxa-zoline [140] cinchona alkaloid derived [141] complexes. 

Another useful method is the modification of Pt black by cinchona alkaloids, initially developed by Orito, which permits the asymmetric hydrogenation of a-keto esters in up to 90% optical yield (Scheme 17) (43). The reaction with Pt-Al203 modified by cinchonidine can be carried out on 10-200-kg scale in greater than 98% chemical yield and in... 

Further reports on asymmetric synthesis in the presence of Cinchona alkaloids have been made.142 " For example, hydrogenation of methyl pyruvate with a platinum-alumina catalyst containing quinine gives (+)-(/ )-methyl lactate in 87% optical yield.1426 Asymmetric induction with optical yields up to 36 and 26% has been observed in the Michael addition of thiols and nitro-alkanes to ct/ -unsaturated ketones in the presence of quaternary salts derived from the Cinchona alkaloids.142"... 

The presence of the quinuclidine base functionality makes them effective ligands for a variety of metal-catalyzed processes (Chapters 2-4). The most representative example is the osmium-catalyzed asymmetric dihydroxylation of olefins [9]. The metal binding properties of the quinuclidine nitrogen also allow to use cinchona alkaloids as metal surface modifiers, for example, in the highly enantioselective heterogeneous asymmetric hydrogenation of a-keto esters (Chapter 2). Both... 

Apart from acting as effective Lewis base catalysts, the quinuclidine structure of cinchona alkaloids can also participate in the other cycloaddition reaction by a different catalytic mechanism. Calter et al. described an interesting asymmetric interrupted Feist-Benary reaction between ethyl bromopyruvates and cyclohexadione. They proposed that the protonated cinchona alkaloid would perform as a Bronsted acid to form hydrogen-bonding interaction with a-ketoester moiety, rendering it more electrophilic toward attack by either the enol or enolate of cydohexandione. Then intramolecular alkylation would afford the formal [3 + 2] cycloadduct (Scheme 10.12) [16]. 

In contrast to Raney nickel catalysts ( 3.4.1), heterogeneous hydrogenation catalysts based on Pt, Rh or Pd do not induce asymmetry in the presence of tartaric acid [113, 578], Platinum catalysts modified by cinchona alkaloids 3.1 and 3.2 cause asymmetric hydrogenation of the carbonyl group of a-ketoesters with a high enantiomeric excess (> 90%). From other types of ketones, the enantioselectivities are lower. 

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]. 

---