Intramolecular kinetic resolution

This methodology has been extended successfully to polymer-supported chiral (salen)Co complexes [88] and to intramolecular kinetic resolution of epoxy alcohols (with (R,R)-L Co OAc)) [82]. The ceiling of 50 % yield in kinetic resolution reactions can be extended if the starting material undergoes racemization under the reaction conditions. This has been shown to be possible with epichlorohydrin in reaction with TMSN3, the dynamic kinetic resolution process affording now a 76 % product yield (97 % ee) and 12 % each of the dichloro and diazido products [89]. 

B2.5.8 INTRAMOLECULAR KINETICS FROM HIGH-RESOLUTION SPECTROSCOPY... 

A combination of an enzymatic kinetic resolution and an intramolecular Diels-Alder has recently been described by Kita and coworkers [23]. In the first step of this domino process, the racemic alcohols ( )-8-55 are esterified in the presence of a Candida antarctica lipase (CALB) by using the functionalized alkenyl ester 8-56 to give (R)-8-57, which in the subsequent Diels-Alder reaction led to 8-58 in high enantioselectivity of 95 and 91 % ee, respectively and 81 % yield (Scheme 8.15). In-... 

In order to assess whether intramolecular cooperativity occurs, catalysis was performed with very low (dendritic) catalyst loading (0.027 mol% vs. 0.5 mol% for the monomeric catalyst). The dendritic Co complex effected complete kinetic resolution (98% ee, 50% conversion), while the unsubstituted analogue showed no measurable conversion. 

Internal DCR of Nitroaldol Libraries (Scheme 6.10) [5,6] iDCR was demonstrated by using a conceptual nitroaldol library including five benzaldehyde derivatives (24,36, and 47-49) and one nitroalkane (50, DCL-F, Scheme 6.11). The benzaldehydes, all with a unique substitution pattern, were selected in order to make analysis clear and simple. However, one of the henzaldehydes contained a cyano functionality in the 2-position (49), deliberately making it a candidate for subsequent tandem cyclization following nitroalcohol formation. 5-exo-dig type cyclizations of hydrox-ynitriles to the corresponding iminolactones are expected [40,41], albeit unexplored [42 5], intramolecular transformations, which in this case could lead to possible kinetic resolution of the library. 

An efficient kinetic resolution was also observed during the (—)-sparteine-mediated deprotonation of the piperidin-2-yhnethyl carbamate rac-112 (equation 25). By treatment of rac-112 with s-BuLi/(—)-sparteine (11), the pro-S proton in (/ )-112 is removed preferentially to form the lithium compound 113, which undergoes intramolecular cyclo-carbolithiation, and the indolizidinyl-benzyllithium intermediate 114 was trapped with several electrophiles. The mismatched combination in the deprotonation of (5 )-112, leading to cp/-113, does not significantly contribute to product formation. Under optimized conditions [0.75 equivalents of s-BuLi, 0.8 equivalents of (—)-sparteine, 22 h at —78°C in diethyl ether] the indolizidine 115 was isolated with 34% yield (based on rac-112), d.r. = 98 2, e.r. = 97 3 optically active (5 )-112 was recovered (46%, 63% ee). 

The asymmetric lithiation/substitution of Af-Boc-Af-(3-chloropropyl)-2-alkenylamines 395 by w-BuLi/(—)-sparteine (11) provides (5 )-Af-Boc-2-(alken-l-yl)pyrrolidines 397 via the allyllithium-sparteine complexes 396 (equation 106) . Similarly, the piperidine corresponding to 397 was obtained from the Af-(4-chlorobutyl)amine. Intramolecular epoxide openings gave rise to enantioenriched pyrrolidinols. Beak and coworkers conclude from further experiments that an asymmetric deprotonation takes place, but it is followed by a rapid epimerization a kinetic resolution in favour of the observed stereoisomer concludes the cyclization step. 

Kinetic resolution (enantiomer differentiation) of cycloalkenyl diazoacetates has been achieved (for example, according to Eq. 3) [34]. In these cases one enantiomer of the racemic reactant matches with the catalyst configuration to produce the intramolecular cyclopropanation product in high enantiomeric excess, whereas the mismatched enantiomer preferentially undergoes hydride abstraction from the allylic position [35] to yield the corresponding cycloalkenone. With acyclic secondary allylic diazoacetates the hydride abstraction pathway is relatively unimportant, and diastereoselection becomes the means for enantiomer differentiation [31]. 

With chiral racemic oxiranes one enantiomer reacts faster than the other the degree of kinetic resolution is very high for L-valine/alanine-based dialkoxydihydropyrazines. For example, in the reaction of one equivalent of (2.S )-2,5-dihydro-2-isopropyl-3,6-dimethoxy-5-methyl-pyrazine (1, R1 = CH3) with two equivalents of fW-(//,/ )-2,3-dimethyloxirane (R2,R4 = CH3 R = H) virtually only the (2//,3/ )-oxirane enantiomer reacts with the lithiated dihydropyrazine to give exclusively the (l /, 2/, 2 / )-configuratcd adduct i.e., (2/ ,5S)-2,5-dihydro-5-isopropyl-3,6-dimethoxy-2-[(l/ ,2/ )-2-(2-methoxyethoxymethoxy)-l-methylpropyl]-2-methylpyrazine, entry 7. Likewise, kinetic resolution (intramolecular) occurs upon reaction with rac-7-oxabicy-clo[4.1.0]heptane (entry 8). 

Hydrolase-catalyzed domino reactions incorporating a resolution and a subsequent cycloaddition reaction have been described [95-97]. This constitutes an attractive approach to complex synthetic intermediates. For example, the l-(3-methyl-2-furyl)]propanol roc-93 reacts with ethoxyvinyl methyl fumarate (94) catalyzed by Lipase LIP (from Pseudomonas aeruginosa) to furnish a dienophilic fumarate ester, which spontaneously undergoes an intramolecular Diels-Alder reaction with the furan moiety furnishing exclusively the syn-adduct, the oxabicy-clohexene 95 in excellent along with the remaining alcohol S-96 (Scheme 4.31) [95]. A similar approach has been used for a procedure that includes a series of domino reactions that includes dynamic kinetic resolution of the 3-vinylcyclohex-... 

Epoxides such as 10 can be prepared in high enantiomeric purity, by, inter alia, kinetic resolution. David Hodgson of Oxford University has demonstrated (J. Am. Chem. Soc. 2004, /26,8664) that on exposure to LTMP, monosubstituted epoxides are smoothly converted into the corresponding alkoxy carbenc or alkoxy carbenoid. When an alkene is available for insertion, the cyclopropane, in this case 11, is formed with high diastereocontrol. This represents a powerful new approach to enantioselective ring construction. It is possible that in the absence of a target alkene, the intermediate alkoxy carbene could divert to intramolecular C-H insertion, which might also proceed with substantial diastereocontrol. 

This method is particularly effective with cyclic substrates, and the combined effects of intramolecular and intermolecular asymmetric induction give up to 76 1 (kf/ks) differentiation between enantiomers of a cyclic allylic alcohol. This kinetic resolution provides a practical method to resolve 4-hydroxy-2-cyclopentenone, a readily available but sensitive compound. Hydrogenation of the racemic compound at 4 atm H2 proceeds with kf/ks =11, and, at 68% conversion, gives the slow-reacting R enantiomer in 98% ee. The alcoholic product is readily convertible to its crystalline, enantiomerically pure fert-butyldimethylsilyl ether, an important building block in the three-component coupling synthesis of prostaglandins (67). 

A tandem 1,4-addition-Meerwein-Ponndorf-Verley (MPV) reduction allows the reduction of a, /i-unsaturated ketones with excellent ee and in good yield using a camphor-based thiol as reductant.274 The 1,4-addition is reversible and the high ee stems from the subsequent 1,7-hydride shift the overall process is thus one of dynamic kinetic resolution. A crossover experiment demonstrated that the shift is intramolecular. Subsequent reductive desulfurization yielded fiilly saturated compounds in an impressive overall asymmetric reductive technique with apparently wide general applicability. 

Akai S, Tanimoto K et al (2004) Lipase-catalyzed domino dynamic kinetic resolution of racemic 3-vinylcyclohex-2-en-l-ols/Intramolecular Diels-Alder reaction one-pot synthesis of optically active polysubstituted decalins. Angew Chem Int Ed 43 1407-1410... 

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%. 

Wilson RM, Jen WS, MacMillan DWC (2005) Enantioselective organocatalytic intramolecular Diels-Alder reactions. The asymmetric synthesis of solana-pyrone D. J Am Chem Soc 127 11616-11617 Xie JH, Zhou ZT, Kong WL, Zhou QL (2007) Ru-catalyzed asymmetric hydrogenation of racemic aldehydes via dynamic kinetic resolution efficient synthesis of optically active primary alcohols. J Am Chem Soc 129 1868-1869... 

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