Oxidative kinetic resolution

Recently, a cascade process for the simultaneous preparation of two enantiopure secondary alcohols by the same ADH was investigated [12]. In this work, a kinetic oxidative resolution of different secondary alcohols was coupled with the irreversible asymmetric reduction of selected prochiral activated ketones, that is, a-chloro ketones (Scheme 11.5a). The proposed strategy, named PIKAT (parallel intercoimected kinetic asymmetric transformations), represents an example of redox neutral (or self-sufficient) cascade, with no additional reducing or oxidizing reagents being required. Moreover, the reaction was catalyzed by a single enzyme in the presence of catalytic amounts of the cofactor. As the outcome of the cascade process is a mixture of two different enantioenriched products, substrates were properly selected on the basis of different physical properties. 

The use of enzymes and whole cells as catalysts in organic chemistry is described. Emphasis is put on the chemical reactions and the importance of providing enantiopure synthons. In particular kinetics of resolution is in focus. Among the topics covered are enzyme classification, structure and mechanism of action of enzymes. Examples are given on the use of hydrolytic enzymes such as esterases, proteases, lipases, epoxide hydrolases, acylases and amidases both in aqueous and low-water media. Reductions and oxidations are treated both using whole cells and pure enzymes. Moreover, use of enzymes in sngar chemistiy and to prodnce amino acids and peptides are discnssed. 

Fig. 9 Deuterium isotope effect on the kinetics of oxidation of G by 2AP(-H) radicals in the [2AP]T2GGTio duplex in oxygenated H2O/D2O buffer solutions (pH 7.0) [13]. The kinetic profiles (resolution of 0.5 us/point) of the 2AP(-H) decay (365 nm) and the G(-H) formation (320 nm) were linearized according to a semilogarithmic form of Eq. 7. The solid lines are the best linear fits to the experimental data. Reprinted with permission from the J Phys Chem, Copyright (2001) American Ghemical Society...

The general methods of preparation of phosphole oxides, sulfides, and selenides have been described in Section 3.15.5.1.3. A tentative resolution of chiral phosphole 76 under kinetic dynamic resolution conditions is noteworthy, despite only low enantioselectivities (10-20%) having been obtained (Scheme 20) <2004TA3519>. 

Kinetic hydrolytic resolution at high substrate concentration of para-bromo-a-methyl styrene oxide using an enzymatic extract of Aspergillus niger LCP 521. 

The empirical rule described above for the enantiofacial differentiation in AE of primary allylic alcohols also applies to secondary allylic alcohols. The new aspect that needs to be taken into consideration in this case is the steric hindrance arising from the presence of a substituent (R4) at the carbon bearing the hydroxy group (Figure 6.3). This substituent will interfere in the process of oxygen delivery, making the oxidation of one enantiomer much faster than the reaction of the other one. The phenomenon is so acute that in practice kinetic resolution is often achieved (Figure 6.4) [27]. 

Andersson also showed that, in addition to meso-desymmetrization, kinetic resolution of some cyclic epoxides by use of the first-generation catalyst was also possible, giving both epoxides and allylic alcohols in good yields (Scheme 7.51) [108], Kozmin reported the effective use of the same catalyst in the desymmetrization of diphenylsilacyclopentene oxide. The resulting products could be used in the ster-eocontrolled syntheses of various acyclic polyols (Scheme 7.52) [109]. 

It is concluded [634] that, so far, rate measurements have not been particularly successful in the elucidation of mechanisms of oxide dissociations and that the resolution of apparent outstanding difficulties requires further work. There is evidence that reactions yielding molecular oxygen only involve initial interaction of ions within the lattice of the reactant and kinetic indications are that such reactions are not readily reversed. For those reactions in which the products contain at least some atomic oxygen, magnitudes of E, estimated from the somewhat limited quantity of data available, are generally smaller than the dissociation enthalpies. Decompositions of these oxides are not, therefore, single-step processes and the mechanisms are probably more complicated than has sometimes been supposed. 

The well-known fact that enantiomers exhibit different reactivity towards chiral reagents has been used to obtain optically active sulphoxides in a process which is called kinetic resolution. Kinetic resolution of sulphoxides usually involves either oxidation to the corresponding sulphones or reduction to sulphides by means of proper chiral oxidizing or reducing agents. 

Enantiomers, preferential crystallization of 59 Endo selectivity 798 Ene reactions 808, 809 Enones, synthesis of 732 Enthalpies of formation 102, 103 Enynes, synthesis of 956 Enzymatic kinetic resolution 829 Epimerization 399 Episulphides, oxidation of 237 Episulphones 650, 775 Episulphoxides, photolysis of 742 a,/J-Epoxysulphones reactions of 811, 812 rearrangement of 685 synthesis of 612 / ,y-Epoxysulphones 781 y,<5-Epoxysulphones 627, 628 Epoxysulphoxides reactions of 613 rearrangement of 744 synthesis of 327, 612 Erythronolides 831... 

Scheme 9.4 Kinetic resolution by alcohol oxidation toward chiral products.

The classical kinetic resolution of racemic substrate precursors allows only access to a theoretical 50% yield of the chiral ladone product, while the antipodal starting material remains unchanged in enantiomerically pure form. The regioseledivity for the enzymatic oxidation correlates to the chemical readion with preferred and exclusive migration of the more nucleophilic center (usually the higher substituted a-carbon). The majority of cydoketone converting BVMOs (in particular CHMOAdneto)... 

The identification of a novel BVMO from Mycobacterium tuberculosis (BVMOMtbs) complements this toolbox, as this particular biocatalyst performs a classical kinetic resolution instead of a regiodivergent oxidation vith complete consumption of substrate [140]. Notably, this enzyme accepts only one ketone enantiomer and converts it selectively to the abnormal lactone while the antipodal substrate remains unchanged (Scheme 9.24) [141]. 

This mechanism is the same as that of 19-23 the products differ only because tertiary amine oxides cannot be further oxidized. The mechanism with other peroxyacids is probably the same. Racemic (3-hydroxy tertiary amines have been resolved by oxidizing them with t-BuOOH and a chiral catalyst one enantiomer reacts faster than the other.This kinetic resolution gives products with enantiomeric excesses of > 90%. 

The complex Pd-(-)-sparteine was also used as catalyst in an important reaction. Two groups have simultaneously and independently reported a closely related aerobic oxidative kinetic resolution of secondary alcohols. The oxidation of secondary alcohols is one of the most common and well-studied reactions in chemistry. Although excellent catalytic enantioselective methods exist for a variety of oxidation processes, such as epoxidation, dihydroxy-lation, and aziridination, there are relatively few catalytic enantioselective examples of alcohol oxidation. The two research teams were interested in the metal-catalyzed aerobic oxidation of alcohols to aldehydes and ketones and became involved in extending the scopes of these oxidations to asymmetric catalysis. 

In an effort to develop more active catalyst systems for the oxidative kinetic resolution of non-activated alcohols, Stoltz et al. discovered a modified set of conditions that accomplishes similar resolutions in a fraction of the time [43]. 

Sigman et al. have optimized their system too [45]. A study of different solvents showed that the best solvent was f-BuOH instead of 1,2-dichloroethane, which increased the conversion and the ee. To ensure that the best conditions were selected, several other reaction variables were evaluated. Reducing the catalyst loading to 2.5 mol % led to a slower conversion, and varying temperature from 50 °C to 70 °C had little effect on the selectivity factor s. Overall, the optimal conditions for this oxidative kinetic resolution were 5 mol % of Pd[(-)-sparteine]Cl2, 20 mol % of (-)-sparteine, 0.25 M alcohol in f-BuOH, molecular sieves (3 A) at 65 °C under a balloon pressure of O2. 

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