Julia epoxidation

Nucleophilic epoxidation (Julia-Colonna epoxidation) of trans-chalcone and derivatives with hydrogen peroxide catalysed by Nagasawa-G (Scheme 23.1) was shown to proceed successfully with a biphasic system consisting of water and toluene. This is a highly atom economical reaction (92% for chalcone). 

The asymmetric epoxidation of enones with polyleucine as catalyst is called the Julia-Colonna epoxidation [27]. Although the reaction was originally performed in a triphasic solvent system [27], phase-transfer catalysis [28] or nonaqueous conditions [29] were found to increase the reaction rates considerably. The reaction can be applied to dienones, thus affording vinylepoxides with high regio- and enantio-selectivity (Scheme 9.7a) [29]. 

Bentley et al.m recently improved upon Julia s epoxidation reaction. By using urea-hydrogen peroxide complex as the oxidant, l,8-diazabicyclo[5,4,0]undec-7-ene (DBU) as the base and the Itsuno s immobilized poly-D-leucine (Figure 4.2) as the catalyst, the epoxidation of a, (3-unsaturated ketones was carried out in tetrahydrofuran solution. This process greatly reduces the time required when compared to the original reaction using the triphasic conditions. 

In the early 1980 s Julia and Colonna published a series of papers which, to some extent, filled the gap left by the natural biocatalysts. The Spanish and Italian collaborators showed that a, -unsaturated ketones of type 1 underwent asymmetric oxidation to give the epoxide 2 using a three-phase system, namely aqueous hydrogen peroxide containing sodium hydroxide, an organic solvent such as tetrachloromethane and insoluble poly-(l)-alanine, (Scheme 1) [12]. The reaction takes place via a Michael-type addition of peroxide anion (the Weitz-Scheffer reaction). 

A research team from Bloemfontein (South Africa) have also taken advantage of the Julia and Colonna oxidation in elegant research aimed at the synthesis of optically active flavonoids. Bezuidenhoudt, Ferreira et al. have oxidised a range of chalcone derivatives using poly-(L)-alanine in the three phase system to afford optically active epoxides 4 which were readily cyclised to target compounds of the dihydroflavinol type 5, (Scheme 3) [16]. 

The improved Julia-Colonna epoxidation conditions have been successfully employed for poly-(D)-leucine. 

TABLE 14. Epoxidation results obtained under Julia-Colonna and Roberts conditions... 

Gerlach, A. and Geller, T. Scale-up Studies for the Asymmetric Julia-Colonna Epoxidation Reaction. Adv. Synth. Catal. 2004, 346, 1247-1249. 

Adger, B.M., Barkley, J V. Bergeron, S., Cappi, M.W., Elowerdew, B.E., Jackson, M. R, McCague, R., Nugent, T.C. and Roberts, S.M. Improved Procedure for Julia-Colonna Asymmetric Epoxidation of a,/l-Unsaturated Ketones Total Synthesis of Diltiazem and Taxol Side-chain. J. Chem. Soc., Perkin Trans. 1 1997, 23, 3501-3507. 

The Julia - Colonna asymmetric epoxidation of electron-deficient unsaturated ketones to the corresponding epoxides with high yields and high ee is well known. This technique produces chiral chemical entities from the clean oxidant, hydrogen peroxide, without the use of a toxic or water sensitive transition metal additive. 

The Julia-Colonna epoxidation uses poly-L-leucine and hydrogen peroxide to effect enantioselective epoxidation of chalconc derivatives such as 12. In a pair of back-to-back papers (Tetrahedron Lett. 2004,45, 5065 and 5069), H.-Christian Militzer of Bayer Healthcare AG, Wuppertal, reports a detailed optimization of this procedure. In the following paper (Tetrahedron Lett. 2004,45,5073), Stanley Roberts of the University of Liverpool reports the extension of this procedure to unsaturated sulfones such as 14. 

One topic where biocatalysis has not scored big successes (yet ) is the epoxidation reaction of alkenes. Against this background, the finding that poly-L-alanine catalyzes the epoxidation of enones such as chalcone, ArjCfOjCH H Ar2, raised plenty of interest (Julia, 1980). By employing hydrogen peroxide and NaOH in a biphasic water-toluene mixture together with poly-L-alanine, 2 K,3, S -epoxychalcone was ob-... 

J. Skidmore, and J. A. Smith, beta-Peptides as catalysts poly-beta-leudne as a catalyst for the Julia-Colonna asymmetric epoxidation of enones, Chem. Commun. 2001, (22), 2330-2331. 

D. Reichert, A. Kuhnle, H.-P. Krimmer and K. Drauz, Julia-Colonna asymmetric epoxidation in a continuously operated chemzyme membrane reactor, Synlett 2002, (5), 707-710. 

Also striking was the discovery, by Julia, Colonna et al. in the early 1980s, of the poly-amino acid (15)-catalyzed epoxidation of chalcones by alkaline hydrogen peroxide [19, 20]. In this experimentally most convenient reaction, enantiomeric excesses > 90% are readily achieved (Scheme 1.6). 

In the early 1980s, Julia and Colonna reported that the Weitz-Scheffer epoxidation of chalcone (45a) can be catalyzed by poly-amino acids such as poly-L-alanine, and that the resulting epoxide is formed with enantiomeric excesses > 90% (Scheme 10.8) [66]. In the original three-phase procedure the enone is dissolved in an... 

Because the catalyst is usually prepared by the polymerization of amino acid N-carboxy anhydrides, induced by water or amines [66, 67], the Julia-Colonna epox-idation was soon recognized as a reaction of great practical value. In the course of exploration of the scope of the Julia-Colonna procedure many enone substrates were successfully epoxidized by use of the original three-phase conditions (Table 10.8). 

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