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Enantiomers kinetic resolution

The above procedure can be exploited for the asymmetric oxidation of racemic sulfoxide1 1, and high stereoselection can be frequently observed. Moreover unreacted / -sulfoxides were always recovered as the most abundant enantiomers, kinetic resolution and asymmetric oxidation being two enantioconvergent processes. Thus, by the combined routes, higher enantioselectivity can be observed with dialkyl sulfoxides, usually obtained with poor to moderate e.e.s. [Pg.112]

In the epoxidation of racemic secondary alcohols, there are two stereochemical problems to be considered (i) differentiation of enantiomers (kinetic resolution) and (ii) diastereoface selection in epoxidation. [Pg.607]

Sharpless epoxidations can also be used to separate enantiomers of chiral allylic alcohols by kinetic resolution (V.S. Martin, 1981 K.B. Sharpless, 1983 B). In this procedure the epoxidation of the allylic alcohol is stopped at 50% conversion, and the desired alcohol is either enriched in the epoxide fraction or in the non-reacted allylic alcohol fraction. Examples are given in section 4.8.3. [Pg.126]

In the Sharpless epoxidation of divinylmethanols only one of four possible stereoisomers is selectively formed. In this special case the diastereotopic face selectivity of the Shaipless reagent may result in diastereomeric by-products rather than the enantiomeric one, e.g., for the L -(-(-)-DIPT-catalyzed epoxidation of (E)-a-(l-propenyl)cyclohexaneraethanol to [S(S)-, [R(S)-, [S(R)- and [R(R)-trans]-arate constants is 971 19 6 4 (see above S.L. Schreiber, 1987). This effect may strongly enhance the e.e. in addition to the kinetic resolution effect mentioned above, which finally reduces further the amount of the enantiomer formed. [Pg.126]

EinaHy, kinetic resolution of racemic olefins and aHenes can be achieved by hydroboration. The reaction of an olefin or aHene racemate with a deficient amount of an asymmetric hydroborating agent results in the preferential conversion of the more reactive enantiomer into the organoborane. The remaining unreacted substrate is enriched in the less reactive enantiomer. Optical purities in the range of 1—65% have been reported (471). [Pg.323]

Quantitative Analysis of Selectivity. One of the principal synthetic values of enzymes stems from their unique enantioselectivity, ie, abihty to discriminate between enantiomers of a racemic pair. Detailed quantitative analysis of kinetic resolutions of enantiomers relating the extent of conversion of racemic substrate (c), enantiomeric excess (ee), and the enantiomeric ratio (E) has been described in an excellent series of articles (7,15,16). [Pg.331]

Enzyme-Catalyzed Asymmetric Synthesis. The extent of kinetic resolution of racemates is determined by differences in the reaction rates for the two enantiomers. At the end of the reaction the faster reacting enantiomer is transformed, leaving the slower reacting enantiomer unchanged. It is apparent that the maximum product yield of any kinetic resolution caimot exceed 50%. [Pg.332]

Kinetic Resolutions. From a practical standpoint the principal difference between formation of a chiral molecule by kinetic resolution of a racemate and formation by asymmetric synthesis is that in the former case the maximum theoretical yield of the chiral product is 50% based on a racemic starting material. In the latter case a maximum yield of 100% is possible. If the reactivity of two enantiomers is substantially different the reaction virtually stops at 50% conversion, and enantiomericaHy pure substrate and product may be obtained ia close to 50% yield. Convenientiy, the enantiomeric purity of the substrate and the product depends strongly on the degree of conversion so that even ia those instances where reactivity of enantiomers is not substantially different, a high purity material may be obtained by sacrificing the overall yield. [Pg.337]

The variety of enzyme-catalyzed kinetic resolutions of enantiomers reported ia recent years is enormous. Similar to asymmetric synthesis, enantioselective resolutions are carried out ia either hydrolytic or esterification—transesterification modes. Both modes have advantages and disadvantages. Hydrolytic resolutions that are carried out ia a predominantiy aqueous medium are usually faster and, as a consequence, require smaller quantities of enzymes. On the other hand, esterifications ia organic solvents are experimentally simpler procedures, aHowiag easy product isolation and reuse of the enzyme without immobilization. [Pg.337]

Another means of resolution depends on the difference in rates of reaction of two enantiomers with a chiral reagent. The transition-state energies for reaction of each enantiomer with one enantiomer of a chiral reagent will be different. This is because the transition states and intermediates (f -substrate... f -reactant) and (5-substrate... R-reactant) are diastereomeric. Kinetic resolution is the term used to describe the separation of enantiomers based on different reaction rates with an enantiomerically pure reagent. [Pg.89]

As was the case for kinetic resolution of enantiomers, enzymes typically exhibit a high degree of selectivity toward enantiotopic reaction sites. Selective reactions of enaiitiotopic groups provide enantiomerically enriched products. Thus, the treatment of an achiral material containing two enantiotopic functional groups is a means of obtaining enantiomerically enriched material. Most successful examples reported to date have involved hydrolysis. Several examples are outlined in Scheme 2.11. [Pg.107]

A noteworthy feature of the Sharpless Asymmetric Epoxidation (SAE) is that kinetic resolution of racemic mixtures of chiral secondary allylic alcohols can be achieved, because the chiral catalyst reacts much faster with one enantiomer than with the other. A mixture of resolved product and resolved starting material results which can usually be separated chromatographically. Unfortunately, for reasons that are not yet fully understood, the AD is much less effective at kinetic resolution than the SAE. [Pg.686]

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]. [Pg.191]

Two recent reports described addition of nitrogen-centered nucleophiles in usefully protected fonn. Jacobsen reported that N-Boc-protected sulfonamides undergo poorly selective (salen) Co-catalyzed addition to racemic epoxides. However, by performing a one-pot, indirect kinetic resolution with water first (HKR, vide infra, Table 7.1) and then sulfonamide, it was possible to obtain highly enantiomer-ically enriched addition products (Scheme 7.39) [71]. These products were transformed into enantioenriched terminal aziridines in straightforward manner. [Pg.254]

Pineschi and Feringa reported that chiral copper phosphoramidite catalysts mediate a regiodivergent kinetic resolution (RKR) of cyclic unsaturated epoxides with dialkylzinc reagents, in which epoxide enantiomers are selectively transformed into different regioisomers (allylic and homoallylic alcohols) [90]. The method was also applied to both s-cis and s-trans cyclic allylic epoxides (Schemes 7.45 and 7.46,... [Pg.261]

One way of overcoming these problems is by kinetic resolution of racemic epoxides. Jacobsen has been very successful in applying chiral Co-salen catalysts, such as 21, in the kinetic resolution of terminal epoxides (Scheme 9.18) [83]. One enantiomer of the epoxide is converted into the corresponding diol, whereas the other enantiomer can be recovered intact, usually with excellent ee. The strategy works for a variety of epoxides, including vinylepoxides. The major limitation of this strategy is that the maximum theoretical yield is 50%. [Pg.328]

Since the addition of dialkylzinc reagents to aldehydes can be performed enantioselectively in the presence of a chiral amino alcohol catalyst, such as (-)-(1S,2/ )-Ar,A -dibutylnorephedrine (see Section 1.3.1.7.1.), this reaction is suitable for the kinetic resolution of racemic aldehydes127 and/or the enantioselective synthesis of optically active alcohols with two stereogenic centers starting from racemic aldehydes128 129. Thus, addition of diethylzinc to racemic 2-phenylpropanal in the presence of (-)-(lS,2/ )-Ar,W-dibutylnorephedrine gave a 75 25 mixture of the diastereomeric alcohols syn-4 and anti-4 with 65% ee and 93% ee, respectively, and 60% total yield. In the case of the syn-diastereomer, the (2.S, 3S)-enantiomer predominated, whereas with the twtf-diastereomer, the (2f ,3S)-enantiomer was formed preferentially. [Pg.23]

An efficient kinetic resolution of racemic secondary allyl carbamates was accomplished by the jw-butyllithium-(-)-sparteine complex76 131. Whereas the R-enantiomer (80% ee) is recovered unchanged, the 5-enantiomer is deprotonated preferentially. [Pg.237]

These results reveal a high level of kinetic resolution between the respective chiral reactants. This is also indicated in the reaction between equimolar amounts of the anion of enantiomer-ically pure 3-[(/ M4-methylphenyl)sulfmyl]-l-propene and racemic 4-alkoxy-2-cyclopentenones. [Pg.931]

In this case study, an enzymatic hydrolysis reaction, the racemic ibuprofen ester, i.e. (R)-and (S)-ibuprofen esters in equimolar mixture, undergoes a kinetic resolution in a biphasic enzymatic membrane reactor (EMR). In kinetic resolution, the two enantiomers react at different rates lipase originated from Candida rugosa shows a greater stereopreference towards the (S)-enantiomer. The membrane module consisted of multiple bundles of polymeric hydrophilic hollow fibre. The membrane separated the two immiscible phases, i.e. organic in the shell side and aqueous in the lumen. Racemic substrate in the organic phase reacted with immobilised enzyme on the membrane where the hydrolysis reaction took place, and the product (S)-ibuprofen acid was extracted into the aqueous phase. [Pg.130]

The hydrolysis of seven alkyl arenesulfinylalkanoates by the bacterium Corynebacterium equi IFO 3730 studied by Ohta and coworkers34 are recent examples of kinetic resolutions which give sulfoxides of high enantiomeric purity and in reasonable yield. Compounds 16a, 16b and 16c were recovered in 30 to 43% yield and in 90 to 97% e.e. The S enantiomers underwent hydrolysis more rapidly than the R isomers. Sulfoxide 17 was isolated in 22% yield and 96% e.e., but sulfoxide 18 was completely metabolized. Esters other than methyl gave inferior results. The acids formed upon hydrolysis, although detected, were for the most part further metabolized by the bacterium. [Pg.60]

In principle, it should be possible to selectively reduce one of the enantiomers in a racemic sulfoxide mixture that is, an asymmetric kinetic resolution via reduction should... [Pg.78]

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. [Pg.295]

Enzyme-mediated hydrolysis of some racemic co-arenesulfinylalkanoic methyl esters, ArSO(CH2) COOMe, using Corynebacterium equi has led to a kinetic resolution in which the unreacted sulfinyl esters are enriched in one enantiomer at the sulfoxide center49. The enantiomeric purity of unreacted sulfinyl acetates and propionate ranges from 90 to 97%. [Pg.829]

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... [Pg.1200]

This type of procedure is referred to as a kinetic resolution since the enantiomers of the racemic substrate exhibit different rates of reaction with the optically active compound, i.e. the diastereomeric transition states that arise from differences in e.g. non-bonded interactions have different free energies. Horeau and Nouaille (1966) estimate that a rate difference corresponding to A AG of the order of 0 2 cal mol at 25°C could in principle be revealed by this method. [Pg.18]

Efforts were also made to invert the sense of enantioselectivity in the hydrolytic kinetic resolution of ester (1) using PAL with preferential formation of (R)-2 [40,411-Using epPCR and DNA shuffling, an (R)-selective mutant showing an E value of 30 was evolved by screening about 45 000 clones for the (R) enantiomer. The best mutant is characterized by 11 mutations, which are different from those of the best (S)-selective variant X [41]. [Pg.33]

A kinetic resolution depends on the fact that the two enantiomers of a racemic substrate react at different rates with the enzyme. The process is outlined in Figure 6.1, assuming that the (S) substrate is the fast-reacting enantiomer (ks > ka) and Kic = 0-In ideal cases, only one enantiomer is consumed and the reaction ceases at 50% conversion. In most cases, both enantiomers are transformed and the enantiomeric composition ofthe product and the remaining starting material varies with the extent... [Pg.134]

Despite its widespread application [31,32], the kinetic resolution has two major drawbacks (i) the maximum theoretical yield is 50% owing to the consumption of only one enantiomer, (ii) the separation of the product and the remaining starting material may be laborious. The separation is usually carried out by chromatography, which is inefficient on a large scale, and several alternative methods have been developed (Figure 6.2). For example, when a cyclic anhydride is the acyl donor in an esterification reaction, the water-soluble monoester monoacid is separable by extraction with an aqueous alkaline solution [33,34]. Also, fiuorous phase separation techniques have been combined with enzymatic kinetic resolutions [35]. To overcome the 50% yield limitation, one of the enantiomers may, in some cases, be racemized and resubmitted to the resolution procedure. [Pg.135]


See other pages where Enantiomers kinetic resolution is mentioned: [Pg.424]    [Pg.67]    [Pg.424]    [Pg.67]    [Pg.167]    [Pg.321]    [Pg.323]    [Pg.91]    [Pg.58]    [Pg.246]    [Pg.55]    [Pg.251]    [Pg.295]    [Pg.128]    [Pg.132]    [Pg.183]    [Pg.304]    [Pg.318]    [Pg.295]    [Pg.73]    [Pg.90]    [Pg.91]    [Pg.115]    [Pg.135]   
See also in sourсe #XX -- [ Pg.144 ]




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