Racemization chiral substrate

When racemic chiral substrates are used in combination with chiral ligands, diastereomeric Mo-allyl complexes are formed. The difference in the relative reaction rates of the enantiomers is occasionally high enough to permit a kinetic resolution and isolation of a highly enantioenriched product [175]. If equilibration... 

Oxiranecarboxylic acids 41 (glycidic acids) can be converted into a,P epoxy diazomethyl ketones 42 via mixed anhydrides. It was found that photolysis of these compounds in the presence of alcohols gave yhyunsaturated esters 44. It is thought that nucleophilic attack of the alcohol on the ketene 43 results in epoxide ring opening. The E olefin isomer is predominately formed, although small quantities of Z esters are also isolated (< 10%). Conveniently non-racemic, chiral substrates are readily prepared via Sharpless asymmetric epoxidation of allylic alcohol 39, followed by... 

C-chiral hydroxy phosphorus derivatives, which have been described so far in the literature, are secondary alcohols. Thus, the syntheses of non-racemic compounds of this type comprise two main approaches (cf. C-chiral hydroxyalkyl sulfones. Section 2.2) asymmetric reduction of the corresponding keto derivatives and resolution of racemic hydroxyalkanephosphorus substrates. 

Similar catalytic reactions allowed stereocontrol at either of the olefin carbons (Scheme 5-13, Eqs. 2 and 3). As in related catalysis with achiral diphosphine ligands (Scheme 5-7), these reactions proceeded more quickly for smaller phosphine substrates. These processes are not yet synthetically useful, since the enantiomeric excesses (ee s) were low (0-27%) and selectivity for the illustrated phosphine products ranged from 60 to 100%. However, this work demonstrated that asymmetric hydrophosphination can produce non-racemic chiral phosphines [13]. 

The racemization of chiral substrate or the exchange of bridging and nonbridging oxygens during solvolysis (Scheme 8) may occur through an ion-pair reaction... 

Another historically important reaction is the reorganization of chiral ion pair intermediates of solvolysis of a chiral substrate that leads to racemization of substrate during solvolysis. This reorganization competes with other reactions of the ion pair intermediate of solvolysis of a chiral substrate, so that the relative rate constant for ion-pair racemization can be obtained by determining the relative rates of formation of products from partitioning of the ion pair reaction intermediate, including the enantiomer of substrate (Scheme 14). 

The situation is different for solvolysis reactions in most other solvents, where the intermolecular interactions between ions at an ion pair are stronger than the compensating interactions with solvent that develop when the ion pair separates to free ions. This favors the observation of racemization during solvolysis. There are numerous reports from studies on solvolysis in solvents with relatively low dielectric constant such as acetic acid, of polarimetric rate constants (fe , s ) for racemization of chiral substrates that greatly exceed the titrimetric rate constant (fet, s ) for formation of acid from the solvolysis reaction. ... 

A number of different equilibria may be present in the solution of a chiral substrate and the added chiral auxiliary compound. When all equilibrium processes are fast on the NMR timescale at ambient temperature, an averaged spectrum of shifts is observed. This is also the reason why peak coalescence of the anisochronous nuclei is observed when a racemic auxiliary compound is used5,81. The observed anisochrony of the enantiomers AR sS is highest when the chiral auxiliary compound is enantiomerically pure. AR sS decreases as the enantiomeric purity of the chiral auxiliary compound is reduced. AR sS changes its sign when the chirality of the chiral auxiliary compound is inverted (peak reversal). 

Stepwise solvolysis of chiral substrates through a planar achiral carbocation reaction intermediate normally results in the formation of racemic products. However, the solvolysis of chiral tertiary derivatives 6-Y proceeds with either... 

Scheme 2.1.4.1 Mechanistic scheme for the Pd(0)-catalyzed reaction of symmetrical racemic allylic substrates (X = leaving group) with nucleophiles (Nu) in the presence of a chiral C2-symmetric ligand L. ...

Asymmetric synthesis is any synthesis that produces enantiomerically or diastereomeri-cally enriched products. This is the expected result if enantiomerically enriched chiral substrates are employed. Of interest here are asymmetric syntheses where the reactants are either achiral or chiral but racemic. Many examples of this type are collected in volumes edited by Morrison [33]. The first example of an asymmetric synthesis involved use of the chiral, optically pure base brucine in a stereoselective decarboxylation of a diacid with enantiotopic carboxyl groups [34] ... 

These results, obtained with chiral substrates, agree with the general sense of enantioselective hydrogenation of prochiral 3-oxo carboxylic esters. Obviously, the chirality of the BINAP ligand controls the facial selectivity at the carbonyl function, whereas cyclic constraints determine the relative reactivities of the enantiomeric substrates. Sterically restricted transition states that lead to the major stereoisomers are shown in Scheme 66. Overall, one of four possible diastereomeric transition states is selected to afford high stereoselectivity by dynamic kinetic resolution that involves in situ racemization of the substrates. 

In contradistinction to the alkylation result in the crotyl system described in the previous section (cf. Eq. 8E.9), a rare example depicted in Scheme 8E.33 demonstrates that chiral recognition in the first step of the catalytic cycle can be a source of enantioselectivity [171]. The alkylations of ( )- and (Z)-crotyl carbonate with a sulfur nucleophile generate the branched product in 92% and 29% ee s, respectively. On the other hand, the same reaction using the chiral substrate gives a nearly racemic product with a similar 5 1 regioselectivity. These results clearly indicate that the nucleophilic addition occurs more rapidly than the enantioface exchange process. 

Enantioselective enzymatic transesterifications have been used as a complementary method to enantioselective enzymatic ester hydrolyses. The first example of this particular type of biotransformation is the synthesis of the optically active 2-acetoxy-l-silacyclohexane (5 )-78 (Scheme 19). This compound was obtained by an enantioselective transesterification of the racemic l-silacyclohexan-2-ol rac-43 with triacetin (acetate source) in isooctane, catalyzed by a crude lipase preparation from Candida cylindracea (CCL, E.C. 3.1.1.3)62. After terminating the reaction at 52% conversion (relative to total amount of substrate rac-43), the product (S)-78 was separated from the nonreacted substrate by column chromatography on silica gel and isolated in 92% yield (relative to total amount of converted rac-43) with an enantiomeric purity of 95% ee. The remaining l-silacyclohexan-2-ol (/ )-43 was obtained in 76% yield (relative to total amount of nonconverted rac-43) with an enantiomeric purity of 96% ee. Repeated recrystallization of (R)-43 led to an improvement of enantiomeric purity by up to >98% ee. Compound (R)-43 has already earlier been prepared by an enantioselective microbial reduction of the l-silacyclohexan-2-one 42 (see Scheme 8)53. The l-silacyclohexan-2-ol (R)-43 is the antipode of compound (.S j-43 which was obtained by a kinetic enzymatic resolution of the racemic 2-acetoxy-l-silacyclohexane rac-78 (see Scheme 15)62. For further enantioselective enzymatic transesterifications of racemic organosilicon substrates, with a carbon atom as the center of chirality, see References 64 and 70-72. 

Dehydration of formamides. This reagent converts formamides to isocyanides in 75-90% yield. It was developed particularly for use with chiral substrates that racemize readily in the presence of basic reagents. Thus it converts 2 into the isocyanide 3 with no significant racemization. 

The enantioselective complexation technique can also be applied as one step in the reaction sequence, providing chiral substrates for the next step. We will now discuss the example of Gabriel synthesis between potassium phthalimide 41 and alkyl bromide 42, which leads to optically active amines (Scheme 1) [51], Instead of the complicated preparation of chiral alkyl bromides (halides), imides (43), which are reaction intermediates, have been resolved. Upon treatment with hydrazine and KOH, these gave optically active amines. The chiral host (S,S)-(-)-6 or the chiral biaryl host (,S>(-j-40 was used for the effective resolution of the intermediates 43. Racemic mixtures 43a-d were resolved by complex formation with the host (S,S)-(-)-6 in a mixture of diethyl ether and light petroleum. 

A detailed and elegant study of the SnI solvolysis reactions of several substituted 1-phenylethyl tosylates in 50% aqueous TEE has enabled the rates of (1) separation of the carbocation-ion pair to the free carbocation, (2) internal return with the scrambling of oxygen isotopes in the leaving group, (3) racemization of the chiral substrate that formed the carbocation-ion pair, and (4) attack by solvent to be determined.122... 

Substituted aliphatic and aromatic a-keto ethers (Scheme 18.5) are also amenable to enantioselective hydrogenation catalyzed by cinchona-modified Pt catalysts.25 However, as opposed to the prochiral ketones discussed earlier, kinetic resolution is observed for these chiral substrates. At conversions of 20A2%, ee s of 91-98% were obtained when starting with a racemic substrate (see Table 18.5). It is somewhat surprising that a-keto ethers without substituent in the a-position, such as methoxy acetone, reacted very slowly or not at all and led to very low enantioselectivities,6 and from the results described earlier for a-ketoacetals, the same is expected if 2 substituents are present. 

Asymmetric amplification is the direct consequence of species of racemic composition being stable and of low reactivity. It should be found in all reactions dealing with chiral auxiliaries. One can expect such a phenomenon in diastereo-selective reactions performed on chiral substrates (e.g., reduction of a keto steroid by a chiral catalyst) or kinetic resolution, a hypothesis that has just recently been confirmed.82-83... 

Fig. 3.31. Thought experiment I products from the addition of a racemic chiral dialkylborane to a racemic chiral alkene. Rectangular boxes previously discussed reference reactions for the effect of substrate control (top box reaction from Figure 3.26) or reagent control of stereoselectivity [leftmost box reaction from Figure 3.30 (rewritten for racemic instead of enantiomer-ically pure reagent)]. Solid reaction arrows, reagent control of stereoselectivity dashed reaction arrows, substrate control of stereoselectivity red reaction arrows (kinetically favored reactions), reactions proceeding with substrate control (solid lines) or reagent control (dashed lines) of stereoselectivity black reaction arrows (kinetically disfavored reactions), reactions proceeding opposite to substrate control (solid lines) or reagent control (dashed lines) of stereoselectivity.

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