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Kinetic resolution aldol reactions

Acyliron complexes with central chirality at the metal are obtained by substitution of a carbon monoxide with a phosphine ligand. Kinetic resolution of the racemic acyliron complex can be achieved by aldol reaction with (1 R)-( I (-camphor (Scheme 1.14) [41], Along with the enantiopure (R, c)-acyliron complex, the (Spe)-acyliron-camphor adduct is formed, which on treatment with base (NaH or NaOMe) is converted to the initial (SFe)-acyliron complex. Enantiopure acyliron complexes represent excellent chiral auxiliaries, which by reaction of the acyliron enolates with electrophiles provide high asymmetric inductions due to the proximity of the chiral metal center. Finally, demetallation releases the enantiopure organic products. [Pg.10]

Racemic resolution of a-hydroxy esters was achieved with Pseudomonas cepacia lipase (PCL) and a ruthenium catalyst (for a list, see Figure 18.13) as well as 4-chlorophenyl acetate as an acyl donor in cyclohexane, with high yields and excellent enantiomeric excesses (Huerta, 2000) (Figure 18.14). Combining dynamic kinetic resolution with an aldol reaction yielded jS-hydroxy ester derivatives in very high enantiomeric excesses (< 99% e.e.) in a one-pot synthesis (Huerta, 2001). [Pg.532]

F. F. Huerta and J. E. Backvall, Enantio-selective synthesis of beta-hydroxy acid derivatives via a one-pot aldol reaction -dynamic kinetic resolution, Org. Lett. 2001, 3(8), 1209-1212. [Pg.536]

S )-3-hydroxy-2-methoxypropanal was successfully converted with acetaldehyde, with the primary open chain aldol product forming the lactol. The aldehyde needed as starting material for the northern part was generated in situ from the acetal a DERA-catalyzed kinetic resolution led to conversion of the (R)-enantiomer in the aldol reaction, only. [Pg.31]

Direct intermolecular aldol reactions, catalysed by proline, between tetrahydro-4H-thiopyranone (25) and racemic aldehydes exhibit enantiotopic group selectivity and dynamic kinetic resolution, with ee% of >98% in some cases.109... [Pg.12]

Scheme 5.14 The aldol cycloisomerization by pipecolinic acid and NMI-catalyzed asymmetric intramolecular MBH reaction followed by a kinetic resolution quench . Scheme 5.14 The aldol cycloisomerization by pipecolinic acid and NMI-catalyzed asymmetric intramolecular MBH reaction followed by a kinetic resolution quench .
A modification of this system was also used in intramolecular MBH reactions (also called as aldol cycloisomerization) [71, 74]. In this reaction, optically active pipecolinic acid 61 was found to be a better co-catalyst than proline, and allowed ee-values of up to 80% to be obtained, without a peptide catalyst. The inter-molecular aldol dimerization, which is an important competing side-reaction of the basic amine-mediated intramolecular MBH reaction, was efficiently suppressed in a THF H20 (3 1) mixture at room temperature, allowing the formation of six-membered carbocycles (Scheme 5.14). The enantioselectivity of the reaction could be improved via a kinetic resolution quench by adding acetic anhydride as an acylating agent to the reaction mixture and a peptide-based asymmetric catalyst such as 64 that mediates a subsequent asymmetric acylation reaction. The non-acylated product 65 was recovered in 50% isolated yield with ee >98%. [Pg.166]

Because an equilibrium constant is not affected by catalysis, an enzyme that accelerates a forward reaction must also accelerate the reverse or retro-reaction. Furthermore, the enantioselectivity for both reactions will be identical. Antibody 38C2 catalyzes both the forward and retro-aldol reaction, and we envisioned that it may be useful in the kinetic resolution of aldols. Because the product enantiomer from the forward aldol reaction is the substrate in the retro-aldol reaction, the opposite... [Pg.335]

Two examples of this are shown below (Hoffmann et al., 1998 Zhong et al., 1998). In the first case, both the forward and retro-aldol reactions furnished the product in high optical purity. In the second case, the forward aldol reaction gave the product with only modest ee (58%). However, the retro-aldol reaction provided its corresponding enantiomer in >99% rafter 67% conversion. These experiments demonstrate the power of kinetic resolution to provide high ee values in cases in which the forward aldol reaction provides only moderate ee values. [Pg.336]

Indeed, we have found antibody 38C2 to be an efficient catalyst for the retro-aldol reaction of tertiary aldols. Aldols (R) —19 through (S)— 26 were synthesized via kinetic resolution with 38C2 (List et al., 1999). The resolution of aldols (S) — 24, (R)— 25, and (5)—26 demonstrates the potential of aldehyde aldols. Aldehyde aldols provide facile access to acetate aldols that are otherwise difficult to obtain by more traditional techniques (Saito et al., 1999). [Pg.338]

Scheme 4.9 Kinetic resolution of 19, a precursor to the natural product epothilone C, was accomplished by degrading the unwanted stereoisomer by an antibody-catalyzed retro-aldol reaction. Scheme 4.9 Kinetic resolution of 19, a precursor to the natural product epothilone C, was accomplished by degrading the unwanted stereoisomer by an antibody-catalyzed retro-aldol reaction.
A particularly successful synthesis of Epothilone A is based on two DERA-cata-lyzed steps. In these two of the seven stereocentres of Epothilone A were established. When a racemic aldehyde was released in situ from its acetal, DERA converted only the R-enantiomer into the stable cyclic hemiacetal. This is a combined kinetic resolution and carbon-carbon bond formation yielding a building block with two chiral centers. Since the alcohol function was oxidized, the optical information obtained from the kinetic resolution was lost. Thus, for the overall yield it would have been better if DERA had displayed no stereoselectivity towards the acceptor (Scheme 5.32). In the DERA-catalyzed synthesis of another part of Epothilone A DERA is again highly stereoselective. Fortunately its preference is for the S-enan-tiomer of the acceptor aldehyde, the enantiomer that has to be submitted to the carbon-carbon bond formation in order to obtain the desired building block, again a stable hemiacetal (Scheme 5.32). Indeed, both DERA-catalyzed reactions yield open chain products that form stable cyclic hemiacetals. This ensures that the equilibria of these aldol reactions are shifted towards the desired products. Further synthetic manipulations converted these intermediates into Epothilone A [55]. [Pg.243]

The aldehyde substrates may be used as racemic mixtures in many cases, as the aldolase catalyzed reactions can concomitantly accomplish kinetic resolution. For example, when DHAP was combined with d- and L-glyceraldehyde in the presence of FDP aldolase, the reaction proceeded 20 times faster with the D-enantiomer. Fuc 1-P aldolase and Rha 1-P aldolase show kinetic preferences (greater than 19/1) for the L-enantiomer of 2-hydroxy-aldehydes. Alternatively, these reactions may be allowed to equilibrate to the more thermodynamically favored products. This thermodynamic approach is particularly useful when the aldol products can cyclize to the pyranose form. Since the reaction is reversible under thermodynamic conditions, the product with the fewest 1,3-diaxial interactions will predominate. This was demonstrated in the formation of 5-deoxy-5-methyl-fructose-l-phosphate as a minor product (Scheme 5.5).20a 25 The major product, which is thermodynamically more stable, arises from the kinetically less reaction acceptor. [Pg.274]

The aldol reaction catalyzed by Ab33F12 is outlined in Scheme 5.65. Regardless of the stereochemistry at C(2) of the aldehyde substrate shown (Scheme 5.65), its antibody catalyzed reaction with acetone resulted in a diastereoselective addition of acetone to the S/ -facc of the aldehyde. The products were formed with similar yields, and thus kinetic resolution was observed. However, the degree of facial stereochemical control of the reaction is surprising, since no stereochemical information was built into the hapten. For the... [Pg.328]

Since the preparation of enantiomerically pure tertiary aldols remains a challenge, aldolase antibody 38C2 was investigated as a catalyst for the kinetic resolution of racemic tertiary aldols. Ab38C2 was demonstrated to be an efficient catalyst for the retro-aldol reaction of the fluorogenic tertiary aldol /m-methodol (Scheme 5.68) and exhibited an E value of >159 50. At 50% conversion, (R)-terMnethodol is obtained with an enantiomeric excess of >99% ee. Consequently the ability of Ab38C2 to resolve tertiary alcohol was exploited in the enantioselective synthesis of ( )-frontalin (Scheme 5.69).125... [Pg.331]

Non-Evans Aldol Reactions. Either the syn- or onri-aldol adducts may be obtained from this family of imide-derived eno-lates, depending upon the specific conditions employed for the reaction. Although the illustrated boron enolate affords the illustrated jyn-aldol adduct in high diastereoselectivity, the addition reactions between this enolate and Lewis acid-coordinated aldehydes afford different stereochemical outcomes depending on the Lewis acid employed (eq 35). Open transition states have been proposed for the Diethylaluminum Chloride mediated, anti-selective reaction. These anfi-aldol reactions have been used in kinetic resolutions of 2-phenylthio aldehydes. ... [Pg.62]

The mechanism of the proline-catalyzed enantioselective aldol reaction has been studied. An extension of the asymmetric aldolization deals with the cyclization of diketones. Also investigated was the dehydration of racemic p-ketols in the presence of (S)-proline and a kinetic resolution was observed. ... [Pg.480]

The most impressive result of the catalytic Michael-aldol cascade is the kinetic resolution of the racemic cyclopentenone 458 shown in Sch. 64. The reaction is performed with 10 mol % (S)-ALB to give the tandem Michael-aldol adduct 459 in 97 % ee and 75 % yield based on malonate 390f. Asymmetric induction in 459 was measured after dehydration of the hydroxyl group, as was done for 451. Clearly, this demonstrates the viability of this new asymmetric strategy for the synthesis of a variety of fully functionalized prostaglandins. [Pg.350]

The aldol reaction of a silyl enol ether proceeds in a double and two-directional fashion, upon addition of an excess amount of an aldehyde, to give the silyl enol ether in 77 % isolated yield and more than 99 % ee and 99 % de (Sch. 33) [92]. This asymmetric catalytic aldol reaction is characterized by kinetic amplification of product chirality on going from the one-directional aldol intermediate to the two-directional product. Further transformation of the pseudo C2 symmetric product still protected as the silyl enol ether leads to a potent analog of an HIV protease inhibitor. Kinetic resolution of racemic silyl enol ethers by the BINOL-Ti catalyst (1) has been reported by French chemists [93]. [Pg.819]

Aldolase antibodies 38C2 and 33F12 are able to catalyze both the aldol addition and the retro-aldol reaction [99]. These catalysts have been employed to carry out the kinetic resolution of /3-hydroxyketones [100] and have been found to catalyze the asymmetric aldol reactions of 23 donors (ketones) and 16 acceptors (aldehydes) [101]. A highly efficient enantioselective... [Pg.872]

In this respect, reactions catalyzed by monoclonal antibodies have been the focus of much interest [72]. One of the first antibody-supported syntheses on a gram scale and with an enantiomeric excess of up to 99 % was the kinetic resolution of aldol adducts. The products resulting from the retro-aldol reaction served as precursors in the synthesis of epothilones A and B [73]. [Pg.886]

Keywords Ene reaction, Hetero-Diels-Alder reaction, Ene cyclization, Desymmetrization, Kinetic resolution. Non-linear effect. Asymmetric activation, Metallo-ene, Carbonyl addition reaction, Aldol-type reaction. Titanium, Aluminum, Magnesium, Palladium, Copper, Lanthanides, Binaphthol, Bisoxazoline, Diphosphine, TADDOL, Schiff base. [Pg.1077]

The stereoselectivity of the antibody-catalyzed addition of acetone to aldehyde 67 revealed that the ketone was added to the re-face of 67 regardless of the stereochemistry at C2 of this substrate. The aldol process follows a classical Cram-Felkin mode of attack on (S)-67 to generate the (4S,5S)-68 diastereomer and the anti-Cram-Felkin mode of attack on the (R)-67 to yield the (4S,5R)-69 diastereomer. The products are formed at a similar rate and yield, therefore there is no concomitant kinetic resolution of the racemic aldehyde. The two antibodies differ in their diastereofacial selectivity, reflecting the ability of the antibodies to orient the 67 on opposite sides of the prochiral faces of the nucleophilic antibody-enamine complex of acetone. Heath cock and Flippin [79] have shown that the chemical reaction of the lithium enolate of acetone with (S)-67 yields the (4S,5S)-68 diastereomer a 5% de for this Cram-Felkin product. The generation of the (4S,5R)-69 and (4R,5R)-70 products in a ratio of 11 1 by the... [Pg.1330]


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See also in sourсe #XX -- [ Pg.12 ]




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Antibody 38C2-Catalyzed Retro-aldol Reactions and their Application to Kinetic Resolution

Resolution Reaction

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