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Anhydride desymmetrization

Desymmetrization and Kinetic Resolution of Anhydrides Desymmetrization of meso-Epoxides and other Prochiral Substrates... [Pg.347]

Initial studies indicated that this ruthenium complex is an effective chiral catalyst for enantioselective metathesis. For example, desymmetrization of the anhydride 68 (Scheme 43) in the presence of 10 mol % of 65 and 10... [Pg.218]

For desymmetrization of diesters 3 via their hydrolysis in water, pig Hver esterase [12], o -chymotrypsin [12, 13a], and Candida antarctica Hpase (CAL-B) [14] were successfully used. However, further studies showed that respective anhydrides 5 can be used as substrates for enzyme-catalyzed desymmetrization in organic solvents [15]. The desired monoesters 4 were obtained in high yield in this way, using immobilized enzymes Novozym 435 or Chirazyme L-2 (Scheme 5.3). After the reaction, enzymes were filtered off, organic solvents were evaporated, and the crude products were crystalHzed. This was a much simpler experimental procedure in which control of the reaction progress was not necessary, and aU problems associated with extraction of products from aqueous phase and their further purification were omitted [15]. [Pg.99]

Enantioselective desymmetrization of meso-succinic anhydrides with diphenylzinc is catalyzed by Pd(OAc)2/chiral diphosphine 209 (Equation (113)).470... [Pg.468]

Verma and Ghosh [72] desymmetrized a a-symmetric 3-dimethyl(phe-nyl)silyl substituted glutaric anhydride (127) with Evans oxazolidinone 128 (Scheme 32) as one of the key steps in their synthesis of (+)-preussin. [Pg.30]

Alkylative desymmetrization of cyclic anhydrides would be an attractive alternative to this chemistry since the product would be a keto-acid and would allow elaboration of the molecular scaffold. The first catalyzed asymmetric alkylative desymmetrization of a cyclic anhydride was published from our laboratories in early 2002. The phosphinooxazoline ligand t-PrPHOX provided an effective catalyst when bound to nickel, affording keto-acid 179 in 85% yield and 79% ee ... [Pg.302]

More recently, we have discovered that Pd-JOSIPHOS complexes effectively desymmetrize a variety of succinic anhydrides in excellent yield and enantio-selectivity [Eq. (10.54)]. The reaction proceeds at ambient temperature in some cases and can deliver aryl and alkylzinc reagents with equal facility. For reasons that are unclear, the latter protocol requires a styrenic additive for high enantioselectivity ... [Pg.302]

The synthetic utility of this methodology was further demonstrated in a formal synthesis of (+)-biotin by the same authors [211], Following this work, various reusable immobilised analogues of (DHQD) AQN were reported to catalyze the desymmetrization of a number of meso-cyc ic anhydrides with good selectivities [212-214],... [Pg.267]

Scheme 6.145 Chiral hemiesters obtained from the 121-catalyzed methanolic desymmetrization of cyclic meso-anhydrides. Scheme 6.145 Chiral hemiesters obtained from the 121-catalyzed methanolic desymmetrization of cyclic meso-anhydrides.
A-Boc-leucinal may react with allyl- and alkenyhnagnesium hahdes giving syn- and awf/-products in ca 9 1 ratio. This method was used for the asymmetric synthesis of important amino acids like statine and norstatine. An enantioselective desymmetrization of anhydrides was reported. Arylmagnesium chlorides react in toluene in the presence of (—)-sparteine (1 equiv.) with 3-substituted glutaric anhydrides 215, giving aryl ketones with 87-92% ee (equation 145). ... [Pg.571]

A similar sequence was reported where the asymmetry was introduced by the reaction of weio-3-substituted glutanc anhydrides and (S)-methylbenzylamines to give diastereomeric hemiamides that could be separated by recrystallization The asymmetnc desymmetrization of certain 4-aryl substituted glutanmides has also been accomplished with high levels of selectivity (up to 97% ee) by enolization with a chiral bis-lithium amide base. The selectivity of the reaction was shown to be the result of asymmetric enolization, followed by a kinetic resolution." ... [Pg.143]

Scheme 8. Catalytic enantioselective desymmetrizations of anhydrides using cinchona alkaloid catalysts... Scheme 8. Catalytic enantioselective desymmetrizations of anhydrides using cinchona alkaloid catalysts...
Scheme 9. Desymmetrization and parallel kinetic resolution of cyclic anhydrides by (DHQD)2AQN... Scheme 9. Desymmetrization and parallel kinetic resolution of cyclic anhydrides by (DHQD)2AQN...
Narasaka et al. demonstrated the utility of titanium-ligand complexes in the resolution of chiral a-aryl esters [52]. Ti(Oi-Pr)4-ligand 56 complex resolves 2-pyridine thioesters with high selectivities (fcrei=26-42, see Scheme 13). Seebach and co-workers have examined titanium-TADDOLate complexes as reagents for the ring opening of meso anhydrides, dioxolanones, and azalactones [53]. Addition of an achiral isopropoxide source renders the desymmetrization of meso... [Pg.202]

SE.3.1.2. Desymmetrization of gem-Dwarboxylates An equivalent of asymmetric carbonyl addition can be achieved by the alkylation of gem-dicarboxylates (Scheme 8E.17). The alkylation of gem-dicarboxylates, which are easily prepared by the Lewis acid-catalyzed addition of acid anhydrides to an aldehyde, converts the problem of differentiating the two enantiotopic 7t-faces of a carbonyl group into that of asymmetric substitution of either enantiotopic C-O bond of the gem-dicarboxylate. Although asymmetric induction may be derived from enantio-discrimination in the ionization step or in the alkene coordination step, the fast and reversible nature of alkene coordination suggests that the ionization step is more likely to be the source of enantio-discrimination. [Pg.610]

This chapter covers the kinetic resolution of racemic alcohols by formation of esters and the kinetic resolution of racemic amines by formation of amides [1]. The desymmetrization of meso diols is discussed in Section 13.3. The acyl donors employed are usually either acid chlorides or acid anhydrides. In principle, acylation reactions of this type are equally suitable for resolving or desymmetrizing the acyl donor (e.g. a meso-anhydride or a prochiral ketene). Transformations of the latter type are discussed in Section 13.1, Desymmetrization and Kinetic Resolution of Cyclic Anhydrides, and Section 13.2, Additions to Prochiral Ketenes. [Pg.323]

Most work on this subject is based on the use of alcohols as reagents in the presence of enantiomerically pure nucleophilic catalysts [1, 2]. This section is subdivided into four parts on the basis of classes of anhydride substrate and types of reaction performed (Scheme 13.1) - desymmetrization of prochiral cyclic anhydrides (Section 13.1.1) kinetic resolution of chiral, racemic anhydrides (Section 13.1.2) parallel kinetic resolution of chiral, racemic anhydrides (Section 13.1.3) and dynamic kinetic resolution of racemic anhydrides (Section 13.1.4). [Pg.347]

Desymmetrization of prochiral cyclic anhydrides In the presence of the chiral nucleophilic catalyst (e.g. A, Scheme 13.1, top) one of the enantiotopic carbonyl groups of the prochiral (usually meso) cyclic anhydride substrate is selectively converted into an ester. Application of catalyst B (usually the enantiomer or a pseudoenantiomer of A) results in generation of the enantiomeric product ester. Ideally, 100% of one enantiomerically pure product can be generated from the starting anhydride. No reports of desymmetrizing alcoholyses of acyclic meso anhydrides appear to exist in the literature. [Pg.347]

In the mid-1980s Oda et al. reported that of a series of alkaloids screened for catalytic desymmetrization of cyclic meso-anhydrides with methanol, (+)-cinchonine (1) performed best [4-6]. As shown in Scheme 13.2, 10 mol% of this catalyst was... [Pg.349]

A very efficient and practical process for desymmetrization of meso-anhydrides was reported by Bolm et al. in 1999 and in subsequent publications (Scheme 13.3) [9, 10]. In their approach, which is a further development and improvement in the use of alkaloids as catalysts, (—)-quinine (2) or (+)-quinidine (3) in this case, low reaction temperature and solvent optimization proved crucial to achieving optimum enantioselectivity. Under their conditions methanolysis of several meso anhydrides (8a-g, 9a-g, Scheme 13.3) can be achieved in good yields and with excellent enantiomeric excesses in the presence of equimolar amounts of the inexpensive and readily available alkaloids 2 and 3 [9, 10]. [Pg.351]

The non-alkaloid derived organocatalysts 13a-e - readily accessible from proline and hydroxyproline, respectively - were reported by Uozomi et al. (Scheme 13.7) [17]. Of the five compounds, 13b and 13e performed best. In the presence of 100 mol% 13e, the methanolytic desymmetrization of cyclic meso anhydrides was found to proceed with up to 89% ee. [Pg.352]

See other pages where Anhydride desymmetrization is mentioned: [Pg.300]    [Pg.301]    [Pg.78]    [Pg.300]    [Pg.301]    [Pg.78]    [Pg.68]    [Pg.99]    [Pg.462]    [Pg.79]    [Pg.275]    [Pg.285]    [Pg.106]    [Pg.177]    [Pg.198]    [Pg.198]    [Pg.9]    [Pg.347]    [Pg.348]    [Pg.349]    [Pg.349]    [Pg.351]    [Pg.351]    [Pg.352]    [Pg.353]   
See also in sourсe #XX -- [ Pg.285 ]



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Desymmetrization

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Meso-anhydrides desymmetrization

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