Enantioselective support -leucine

The Jacobsen group has also shown that the recycling of the resin-bounded catalyst can be successfully performed [152,154]. Moreover, they have developed an efficient method for the hydrolysis of the aminonitrile into the corresponding amino acid. This method was apphed for the commercial production of optically active K-amino acids at Rhodia ChiRex (e.g. tert-leucine) the catalyst was immobihsed on a resin support (4 mol %, 10 cycles) and the intermediate hydrocyanation adduct was trapped by simply replacing TFAA with HCOOH/AC2O, for example. Highly crystalhne formamide derivatives were thus obtained in excellent yields (97-98% per cycle) with very high enantioselectivities (92-93% per cycle) [158]. 

Ultrapurification of 50 mmolL DNB-D,L-Leucine in a Cascade of Five Stages with Two Modules and Two Enantiomeric Carrier (Quinine and Quinidine Derivative with 5 vol% Polysiloxane-supported Carrier) Transmembrane Material Stream J, Enantioselectivity a, Enantiomer Excess ee, Purity, and Yield of DNB-D-Leucine... 

In addition, minor variation of the catalyst in combination with immobilization on a resin support gave an analogous recyclable solid-supported organocatalyst. Varying the derivatization method by trapping the a-amino nitrile intermediate with formic acid and acetic anhydride gives the crystalline formamides 19 in excellent yield and with high enantioselectivity. These features of this catalytic process have been demonstrated by results from the synthesis of r-tert-leucine (Scheme 14.8) [49]. 

Similar conditions are also effective for the direct enantioselective epoxidation of a,p-unsaturated carbonyls, as exemplified by the conversion of chalcone (30) to the corresponding ft,/ -epoxide in 97% yield and 84% ee using the 4-iodophenyl cinchonine derivative 32 <02T1623>. Alternatively, the novel polyethylene glycol-supported oligo(L-leucine) catalyst... 

In the 1980s, Julia and Colonna discovered that the Weitz-Scheffer epoxidation of enones such as chalcone (4, Scheme 2) by alkaline hydrogen peroxide is catalyzed in a highly enantioselective fashion by poly-amino acids such as poly-alanine or poly-leucine (Julia et al. 1980, 1982). The poly-amino acids used for the Julia-Colonna epoxidation are statistical mixtures, the maximum length distribution being around 20-25 mers (Roberts et al. 1997). The most fundamental question to be addressed refers to the minimal structural element (i.e. the minimal peptide length) required for catalytic activity and enantioselectiv-ity. To tackle this question, we have synthesized the whole series of L-leucine oligomers from 1- to 20-mer on a solid support (Berkessel... 

Enantioselective heterogeneous catalytic hydrogenation using a chiral catalyst was pioneered by Aka-bori and Izumi, who prepared a palladium catalyst supported on silk fibroin. The oxime acetates of diethyl a-ketoglutarate or of ethyl phenylpyruvate were hydrogenated to form glutamic acid (7-15% ee) and phenylalanine (30% Similarly, a palladium-poly-L-leucine catalyst was used for the asym-... 

Recently, the use of polymer-supported chiral ligands and poly(amino acids) as enantioselective elicitors during epoxidation has become popular. Thus, poly(tartrate ester) is for the Sharpless asymmetric epoxidation,poly-L-leucine for epoxidation of enones. 

Several examples are known of the enantioselective conversion of alkenes into epoxides with the use of polymer-supported oxidation catalysts. This can be traced to the pioneering work by Julia and Colonna in 1980. They demonstrated that highly enantioselective epoxidations of chalcones and related a, 3-unsaturated ketones can be achieved with the use of insoluble poly(a-amino acids) (116, Scheme 10.20) as catalysts [298-301]. The so-called Julia-Colonna epoxidation has been the object of several excellent reviews [302-306]. The terminal oxidant is H202 in aq. NaOH. With lipophilic amino acids as the components, such as (SJ-valine or (SJ-leucine, enantioselectivities as high as 96-97% ee were obtained. The enan-tioselectivity depends of several factors, including the side-chain of the amino acid, the nature of the end groups and the degree of polymerization. Thus, for instance,... 

Liskamp has reported the synthesis and the screening in asymmetric catalysis of a library of polymer-supported peptidosulfonamide [147]. Rt) or (5 -pyrrolydines 222 prepared in six steps from D or Z-tartaric acid were anchored onto Argonaut resin (0.41 mmol/g) to afford the corresponding supported pyrrolidines 223 (Scheme 91). The polymeric peptidosulfonamides 224 and 225 were then synthesized in four steps from the immobilized pyrrolidines 223. The different chiral polymers were tested in the titanium-mediated diethylzinc addition to benzaldehyde,/ -chlorobenzaldehyde, cyclohexanecarboxaldehyde and phenylacetaldehyde. Both yield and ee were very low with all these supported-ligands for the enantioselective reaction with the two aliphatic aldehydes. With aromatic aldehydes, the best results were observed with both leucine-derived supported peptidosulfonamides 224d and 225d. 

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