Quinine derivatives

For a similar series of chalcone derivatives the use of aqueous sodium hypochlorite in a two phase system (with toluene as the organic solvent) and the quinine derivative (32) as a chiral phase-transfer catalyst, produces epoxides with very good enantiomeric excesses and yields1981. 

Quinine Derived from the bark of the Cinchona tree, quinine was used to treat malaria. 

FIGURE 1.35 SLM process using O-9-(l-adamantylcarbamoyl)-10,ll-dihydro-ll-octadecylsulfinylquinme and corresponding quinidine derivative as chiral carriers for the preparative separation of enantiomers of Al-derivatized amino acids (e.g., DNB-Leu). (a) ftinciple of the carrier SLM process with carrier-mediated transport (top) and (nonstereoselective) nonspecific transport processes (bottom), (b) General experimental setup of the SLM production unit with two membrane modules, (c) Multistage SLM purification process. P, permeate QD/QN, membrane modnles snpported with quinidine-derived and quinine-derived chiral carriers. R, S, D, L refers to the respective enantiomers of the selectand (DNB-Leu). (Reproduced from A. Maximini et al., J. Membr. ScL, 276 221 (2006). With permission.)... 

New brush-type phases (donor-acceptor interactions) are appearing all the time. " Examples are stationary phases comprising quinine derivatives and trichloro-dicyanophenyl-L-a-amino acids as chiral selectors. Quinine carbamates, which are suitable for the separation of acidic molecules through an ionic interaction with the basic quinine group, are also commonly used but in general they are classified with the anion-exchange type of chiral selectors (see further) because of their interaction mechanism, even though r-donor, r-acceptor properties occur. (Some separations on Pirkle-type CSPs are shown in Table 2.)... 

A further example of the use of a chiral anion in conjunction with a chiral amine was recently reported by Melchiorre and co-workers who described the asymmetric alkylation of indoles with a,P-unsaturated ketones (Scheme 65) [212]. The quinine derived amine salt of phenyl glycine (159) (10-20 mol%) provided the best platform with which to perform these reactions. Addition of a series of indole derivatives to a range of a,P-unsaturated ketones provided access to the adducts with excellent efficiency (56-99% yield 70-96% ee). The substrates adopted within these reactions is particularly noteworthy. For example, use of aryl ketones (R = Ph), significantly widens the scope of substrates accessible to iminium ion activation. Expansion of the scope of nucleophiles to thiols [213] and oximes [214] with similar high levels of selectivity suggests further discoveries will be made. 

Some structure-activity relationship (SAR) studies have been performed on specific ciasses of ciiemicals, including fluoroquinolones, quinine derivatives, pyrroles, thiophenes and polycyclic aromatic hydrocarbons (PAHs). 

The intramolecular aldol reaction can also proceed with high enantioselectivity. Daniel Romo of Texas A M University has shown (/ Org. Chem. 2005, 70,2835) that a quinine-derived organocatalyst Q works well for the cyclization of aldehyde acids such as 6 to the bicyclic p-lactone 8. Both 5- and 6-... 

Tandem intramolecular Michael addition - intramolecular alkylation can lead to cyclopropanes. Matthew J. Gaunt of the University of Cambridge has shown (Angew. Chem. Int. Ed. 2004,43, 2681) that this intramolecular Michael addition also responds to organocatalysis. In this case, the catalyst, a quinine-derived amine, covalently binds to the substrate, then is released at the end of the reaction. 

Karl Anker Jorgensen of Aarhus University, Denmark has found (J. Am. Chem. Soc. 2005, /27, 3670) that face-selective addition can also be carried out on an activated aromatic ring. In this work, the chirality is delivered by a quinine-derived organocatalyst. 

Michael additions of C-nudeophiles such as the indanone 1 have been the subject of numerous further studies For example, the reaction between the indanone 1 and methyl vinyl ketone was effected by a solid-phase-bound quinine derivative in 85% yield and with remarkable 87% ee by d Angelo, Cave et al. [5], Co-polymers of cinchona alkaloids with acrylonitrile effected the same transformation Kobaya-shi and Iwai [6a] achieved 92% yield and 42% ee and Oda et al. [6b] achieved almost quantitative yield and up to 65% ee. Similarly, partially resolved 2-(hydroxy-methyl)quinudidine was found to catalyze the reaction between 1 and acrolein and a-isopropyl acrolein with induction of asymmetry, but no enantiomeric excesses were determined [7]. As shown in Scheme 4.4, the indanone 7 could be added to MVK with up to 80% ee under phase-transfer conditions, by use of the Cinchona-derived PT-catalysts 9a and 9b, affording the Michael-product 8 or enf-8, respectively [8]. The adducts 8 or ent-8 were intermediates in the stereoselective Robinson anellation of a cydohexenone ring to the indanone 7 [8],... 

By a similar but solvent-free method Plaquevent et al. produced the Michael adduct 30 from 2-pentyl-2-cyclopentenone in 91% yield and with 90% ee, by use of the quinine-derived catalyst 31 (Scheme 4.10) [16], When the quinidine-derived ammonium salt 32 was employed, 80% of the enantiomeric product ent-30 was ob-... 

Lammerhofer and Lindner [62] reported on the enantiomer separation of deriva-tized amino acids on an ODS-packed capillary with a chiral quinine-derived selector as buffer additive in two different modes (i) in an electrophoretically dominated mode at high electrolyte concentration and (ii) in an electroosmotically dominated mode at a low electrolyte concentration. Enantiomer separation in the electrophoretically dominated mode (i) leads to high efficieny (about two to three times higher than in LC) but to a moderate enantioselectivity (about the same as in LC). In the electroosmotically dominated mode (ii) a higher enantioselectivity but a lower efficiency (even inferior to LC) occurs. The separations can also been performed in a non-aque-ous buffered mobile phase. Pressurization (8-10 bar) of the flow system on both ends of the separation capillary was applied. 

A series of (1-lactams (64) have been synthesized through the use of an immobilized cinchona alkaloid catalyst. This is postulated to proceed via the cycloaddition of an imine, and a ketene formed in situ through deprotonation of an acid chloride (Scheme 4.81). Different system configurations were described in the paper however, a column filled with a 5 1 mixture of solid K2C03 and immobilized-quinine derivative 65 cooled to —45 °C was found to be the most practical. The solution of the acid chloride and imine was dripped through the column and then directed... 

The same principle applies to other easily made symmetrical dichloro derivatives of these rings and their benzo-analogues. The nitrogen atoms can be related 1,2,1,3, or 1,4 as in the examples alongside. The first two are used to link the quinine-derived ligands required for the Sharpless asymmetric dihydroxylation, which will be described in Chapter 45. 

A somewhat more successful approach to asymmetric Darzens reactions has been observed in the reaction of a-halosulfones with aldehydes under phase-transfer conditions <07T8099>. The reaction of an a-chlorosulfone with benzaldehyde in the presence of quinine derived phase-transfer catalyst 11, provides the epoxide in excellent yield with very good enantioselectivity. The use of RbOH as the base was crucial to both yield and enantioselectivity. 

Benzylquininium chloride has been studied as a catalyst for the asymmetric Michael reaction. Reaction of amidoma-lonate (5) and chalcone (4) with catalytic base and a variety of chiral, nonracemic ammonium salts in the absence of solvent produced (6) in yields of 41-68% and 20-68% ee (eq 2). The quinine-derived salt (1) was of intermediate effectiveness (38% ee, 47% yield) when compared to ephedrine-based catalysts. Although (1) was not specifically tested with regard to solvation effects, it is suggested that increased aggregation of reactive species under solid-liquid PTC conditions leads to enhanced organization and selec-... 

To explore the possibility of recycling alkaloid-Os04 complexes, several polymer-bound alkaloid derivatives have been used for heterogeneous catalytic asymmetric dihydroxylations. As chiral ligands, polymerized cinchona alkaloids or copolymers of quinine derivatives with acrylonitrile or styrene were studied [46]. In general, lower select vities and decreased rates were observed. 

Equation 12.16 is an example of the Sharpless-Katsuki asymmetric epoxi-dation of allylic alcohols, which is catalyzed by a Ti complex bound to a chiral tartrate ligand.38 A Mn-salen39 complex serves as catalyst for asymmetric epoxi-dation (Jacobsen-Katsuki reaction) of a wide variety of unfunctionalized alkenes, shown in equation 12.17.40 0s04 complexed with chiral alkaloids, such as quinine derivatives (equation 12.18), catalyzes asymmetric 1,2-dihydroxylation of alkenes (known as the Sharpless asymmetric dihydroxylation).41 The key step of all these transformations is the transfer of metal-bound oxygen, either as a single atom or as a pair, to one face of the alkene. 

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