Asymmetric catalysis kinetic resolutions

Henin, E, Muzart, J., Pete, J.P. and Rau, H., Asymmetric catalysis kinetic resolution of the pho-tochemicaUy-produced trans-1-acetylcyclooctene, Tetrahedron Lett., 31,1015-1016, 1990. 

Vongvilai P, Larsson R, Ramstrom O (2008) Direct asymmetric dynamic kinetic resolution by combined lipase catalysis and nitroaldol (Henry) reaction. Adv Synth Catal 350 448 152... 

Clearly, there is a need for techniques which provide access to enantiomerically pure compounds. There are a number of methods by which this goal can be achieved . One can start from naturally occurring enantiomerically pure compounds (the chiral pool). Alternatively, racemic mixtures can be separated via kinetic resolutions or via conversion into diastereomers which can be separated by crystallisation. Finally, enantiomerically pure compounds can be obtained through asymmetric synthesis. One possibility is the use of chiral auxiliaries derived from the chiral pool. The most elegant metliod, however, is enantioselective catalysis. In this method only a catalytic quantity of enantiomerically pure material suffices to convert achiral starting materials into, ideally, enantiomerically pure products. This approach has found application in a large number of organic... 

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. 

M. Tokunaga, J. F. Larrow, F. Kakiuchi, E. N. Jacobsen, Asymmetric Catalysis with Water Efficient Kinetic Resolution of Terminal Epoxides by Means of Catalytic Hydrolysis, Science 1997, 2T7, 936-938, and references cited therein. 

Pellissier, H., Recent developments in dynamic kinetic resolution. Tetrahedron, 2008, 64, 1563-1601 Turner, N.J., Enzyme catalysed deracemisation and dynamic kinetic resolution reactions. Curr. Opin. Chem. Biol., 2004, 8, 114-119 Gmber, C.C., Lavandera, I., Faber, K. and Kroutil, W., From a racemate to a single enantiomer deracemisation by stereoinversion. Adv. Synth. Catal., 2006, 348, 1789-1805 Pellissier, H., Dynamic kinetic resolution. Tetrahedron, 2003, 59, 8291-8327 Pmnies, O. and Backvall, J.-E., Combination of enzymes and metal catalysts. A powerful approach in asymmetric catalysis. Chem. Rev., 2003, 103, 3247-3261. 

A very successful example for the use of dendritic polymeric supports in asymmetric synthesis was recently described by Breinbauer and Jacobsen [76]. PA-MAM-dendrimers with [Co(salen)]complexes were used for the hydrolytic kinetic resolution (HKR) of terminal epoxides. For such asymmetric ring opening reactions catalyzed by [Co(salen)]complexes, the proposed mechanism involves cooperative, bimetallic catalysis. For the study of this hypothesis, PAMAM dendrimers of different generation [G1-G3] were derivatized with a covalent salen Hgand through an amide bond (Fig. 7.22). The separation was achieved by precipitation and SEC. The catalytically active [Co "(salen)]dendrimer was subsequently obtained by quantitative oxidation with elemental iodine (Fig. 7.22). 

Tokimaga, M. Larrow, J. F. Kakiuchi, F. Jacobsen E. N. (1997) Asymmetric catalysis with water Efficient kinetic resolution of terminal epoxides by means of catalytic hydrolysis., Science, 111 936-938. 

Asymmetric Transformations by Coupled Enzyme and Metal Catalysis Dynamic Kinetic Resolution... 

In order to extend the comparison of enzymatic kinetic resolution and asymmetric catalysis of chapter 2 and identify the potential improvements of these processes, the derivation of the equations that determine the enantiomeric excess and yield are given in detail. 

For examples of dynamic kinetic resolution, see Ohkuma T, Noyori R (1999) Hydrogenation of carbonyl groups. In Jacobsen EN, Pfaltz A, Yamamoto H (eds) Comprehensive asymmetric catalysis. Springer, Berlin Heidelberg New York, chap 6.1 Huerta FF.Minidis ABE, Backvall J-E (2001) Chem Soc Rev 30 321-331... 

Although mechanistically different, a successful kinetic resolution of cyclic allyl ethers has recently been achieved by zirconium catalysis [2201. Other metals such as cobalt [221], ruthenium [222], and iron [2231 have been shown to catalyze allylic alkylation reactions via metal-allyl complexes. However, their catalytic systems have not been thoroughly investigated, and the corresponding asymmetric catalytic processes have not been forthcoming. Nevertheless, increasing interest in the use of alternative metals for asymmetric alkylation will undoubtedly promote further research in this area. 

M. J. Kim, Y. Ahn, and J. Park, Dynamic kinetic resolutions and asymmetric transformations by enzymes couples with metal catalysis, Curr. Opin. Biotechnol. 2002, 13, 578-587. 

It should be noted that the related imine-oxaziridine couple E-F finds application in asymmetric sulfoxidation, which is discussed in Section 10.3. Similarly, chiral oxoammonium ions G enable catalytic stereoselective oxidation of alcohols and thus, e.g., kinetic resolution of racemates. Processes of this type are discussed in Section 10.4. Whereas perhydrates, e.g. of fluorinated ketones, have several applications in oxidation catalysis [5], e.g. for the preparation of epoxides from olefins, it seems that no application of chiral perhydrates in asymmetric synthesis has yet been found. Metal-free oxidation catalysis - achiral or chiral - has, nevertheless, become a very potent method in organic synthesis, and the field is developing rapidly [6]. 

Notz W, Tanaka F, Watanabe S, Chaudari NS, Turner JM, Thayumanavan R, Barbas CF 3rd (2003) The direct organocatalytic asymmetric mannich reaction unmodified aldehydes as nucleophiles. J Org Chem 68 9624-9634 Noyori R (2002) Asymmetric catalysis science and opportunities (Nobel lecture). Angew Chem Int Ed Engl 41 2008-2022 Noyori R, Tokunaga M, Kitamura M (1995) Stereoselective organic synthesis via dynamic kinetic resolution. Bull Chem Soc Jpn 68 36-55 Ohkuma T, Kitamura M, Noyori R (2000) Asymmetric hydrogenation. In Ojima I (ed) Catalytic asymmetric synthesis, 2nd edn. Wiley-VCH, New York, p 1-110... 

Carbonyl-Ene Reaction. BINOL-TiX2 reagent exhibits a remarkable level of asymmetric catalysis in the carbonyl-ene reaction of prochiral glyoxylates, thereby providing practical access to a-hydroxy esters. These reactions exhibit a remarkable positive nonlinear effect (asymmetric amplification) that is of practical and mechanistic importance (eq 19). The desymmetrization of prochiral ene substrates with planar symmetry by the enantiofacial selective carbonyl-ene reaction provides an efficient solution to remote internal asymmetric induction (eq 20). The kinetic resolution of a racemic allylic ether by the glyoxylate-ene reaction also provides efficient access to remote but relative asymmetric induction (eq 21). Both the dibromide and dichloride catalysts provide the (2R,5S)-syn product with 97% diastereoselectivity and >95% ee. 

The transketolase (TK EC 2.2.1.1) catalyzes the reversible transfer of a hydroxy-acetyl fragment from a ketose to an aldehyde [42]. A notable feature for applications in asymmetric synthesis is that it only accepts the o-enantiomer of 2-hydroxyaldehydes with effective kinetic resolution [117, 118] and adds the nucleophile stereospecifically to the re-face of the acceptor. In effect, this allows to control the stereochemistry of two adjacent stereogenic centers in the generation of (3S,4R)-configurated ketoses by starting from racemic aldehydes thus this provides products stereochemically equivalent to those obtained by FruA catalysis. The natural donor component can be replaced by hydroxy-pyruvate from which the reactive intermediate is formed by a spontaneous decarboxylation, which for preparative purposes renders the overall addition to aldehydic substrates essentially irreversible [42]. 

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