Metal cinchona alkaloid-modified

The main features of the cinchona alkaloid-modified metal system are illustrated in Scheme 14.9. 

Figure 16. Main features in enantioselective hydrogenation of a-ketoesters on cinchona alkaloid-modified metal catalysts [ 143]. [Reproduced with permission of Elsevier from Baiker, A. J. Mol. Catal. A 1997,115, 473-493.]...

In addition to metal catalysts, organocatalysts could also be used in asymmetric cyanation reactions. Chiral Lewis bases, modified cinchona alkaloids, catalyzed asymmetric cyanation of ketones by using ethyl cyanoformate as the cyanide source (Scheme 5.34)." Similar to metal-catalyzed reactions, ethyl cyanoformate was first activated by chiral Lewis bases to form active nucleophiles. Various acyclic and cyclic dialkyl ketones were transformed into the desired products. Because of using... 

The modification of platinum-group metals by adsorbed chiral organic modifiers has emerged as an efficient method to make catalytic metal surfaces chiral. The method is used to prepare highly efficient catalysts for enantioselective hydrogenation of reactants with activated C = O and C = C groups. The adsorption mode of the chiral modifier is crucial for proper chiral modification of the active metal surfaces. The most efficient chiral modifiers known today are cinchona alkaloids, particularly CD, which yields more than 90% enantiomeric excess in the hydrogenation of various reactants. 

Finally, metal colloids can adsorb chiral molecules such surface-modified particles can catalyze hydrogenations in high optical yields. An example is platinum colloids treated with cinchona alkaloids.18... 

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... 

In contrast to asymmetric oxidation chemistry, cinchona-catalyzed asymmetric reduction reactions have been explored very little, despite the importance of this reaction. Previous reports on this topic are restricted to the reduction of aromatic ketones, and the enantioselectivities achieved to date remain far from satisfactory when compared with metal catalysis. Moreover, Hantsch esters, another type of useful organic hydrides, have not yet been studied in combination with cinchona catalysts. However, as is well known, the structures of cinchona alkaloids are easily modifiable, thus permitting the easy tuning of the reaction course. The successful use of cinchona catalysts for this reaction will therefore likely be reported in the very near future. 

In addition to the enantioselective effect, cinchona alkaloids also produce a rate acceleration, i.e. this is an example of ligand accelerated catalysis [14]. The model of a non-closepacked ordered array of cinchonidine molecules adsorbed on platinum, proposed by Wells and co-workers, was abandoned in their later study [15]. Augustine [16] deduced from the behaviour of this system at low modifier concentrations that the chiral sites are formed at the edge and comer platinum atoms, which involve the adsorbed cinchonidine and a metal adatom. The different authors agreed that the quinoline ring of the modifier is responsible for the adsorption on platinum, the quinuclidine part, through the nitrogen atom, interacts with... 

Platinum and palladium dominate the enantioselective catalysis scene as far as alkaloid modifiers are concerned. Of the other platinum group metals, Ir follows Pt in cinchona-modified pyruvate ester hydrogenation,132 the fact that Rh can hydrogenolyse alkaloids adsorbed at its surface133 makes it unlikely to function successfully and Ru tends to be too easily oxidised by adventitious oxygen in these reactions. 

Other transition metal catalysts modified with tartaric acid have been used. Tartaric acid is not a good modifier with Pt. Cinchona alkaloids efficiently modify Pt, Pd, Rh, and reduce the carbonyl group of a-ketoesters ... 

Alternatively, the surface of a metal can be modified with an enantiomerically pure additive. For example, in 1956 palladium metal/silk fibroin was used for the hydrogenation of alkenes with moderate enantioselectivity. However, most success with modified metal siufaces has been achieved in the hydrogenation of ketones. The reduction of 3-keto esters with a Raney nickel/tartaric acid/sodium bromide catalyst provides good enantioselectivities. For example, P-keto ester (3.108) affords the P-hydroxy ester (3.109). Platinum metal modified with cinchona alkaloids has been successfully used with a-keto esters. The reaction yields product with up to 90% ee in the reduction of a-keto ester (3.110). ... 

The development of the first highly enantioselective cyanocarbonation of prochiral ketones promoted by a chiral base catalyst, such as a cinchona alkaloid derivative, was reported by Tian and Deng in 2006. " Importantly, the reaction complemented known enzyme- and transition metal based methods in substrate scope via its unique ability to promote highly enantioselective cyanocarbonation of sterically hindered simple dialkyl ketones. Mechanistic studies provided experimental evidence to shed significant light on the asymmetric induction step in which the modified cinchona alkaloid acted as a chiral nucleophilic catalyst. Moreover, experimental evidence supported the mechanistic proposal that the enantioselectivity determination step in the cyanocarbonation was a DKR of the putative intermediates G and H via asymmetric transfer of the alkoxycarbonyl group (Scheme 2.105). 

The influence of pressure on organic reactions catalyzed by chiral metal-free organic molecules was studied for selected asymmetric Michael, Baylis-Hillman, aldol, Mannich, Friedel-Crafls, and Diels-Alder reactions-the essential part of this work was done in Japan. In the early stages of those investigations the high-pressure technique was applied to reactions catalyzed by cinchona alkaloids and in most cases low or moderate enantioselectivities were observed. Since 2002 some examples of high-pressure reactions catalyzed by proUne, thioureas, and modified cinchona alkaloids have appeared. 

One of the simplest approaches to the creation of an enantioselective catalyst is the adsorption of a chiral molecule (often referred to as a modifier) onto the surface of a metal catalyst. The metals most commonly employed for this type of catalysis have been the Pt group metals and Ni [29]. The most successful chiral modifiers have been naturally occurring alkaloids (Pt) and tartaric acid (Ni) (Scheme 5.2). Each system has primarily been used for hydrogenation reactions with Pt/cinchona producing ee values of greater than 90% for the hydrogenation of a-ketoesters [42, 43] ... 

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