Schiff bases asymmetric

Monoalkylation of Clycinate Schiff Base Asymmetric Synthesis of a-Amino Acids... 

Simple esters cannot be allylated with allyl acetates, but the Schiff base 109 derived from o -amino acid esters such as glycine or alanine is allylated with allyl acetate. In this way. the o-allyl-a-amino acid 110 can be prepared after hydrolysis[34]. The Q-allyl-o-aminophosphonate 112 is prepared by allylation of the Schiff base 111 of diethyl aminomethylphosphonates. [35,36]. Asymmetric synthesis in this reaction using the (+ )-A, jV-dicyclohex-ylsulfamoylisobornyl alcohol ester of glycine and DIOP as a chiral ligand achieved 99% ec[72]. 

The first example of asymmetric catalytic ring-opening of epoxides with sp2-hybridized carbon-centered nucleophiles was reported by Oguni, who demonstrated that phenyllithium and a chiral Schiff base ligand undergo reaction to form a stable system that can be used to catalyze the enantioselective addition of phenyllithium to meso-epoxides (Scheme 7.24) [48]. Oguni proposed that phenyllithium... 

The asymmetric Strecker synthesis of a-amino nitriles from Schiff bases of a-methylbenzyl-aminc is improved by the use of trimethylsilyl cyanide, instead of hydrogen cyanide and by promotion of the transformation with a Lewis acid, preferably zinc chloride43. Thus, from the butyraldimine 2, the amino nitrile is synthesized with a yield of 98.5% and an ee of 68.5%. 

The modified Sharpless reagent was also successfully applied288 for the asymmetric oxidation of a series of 1,3-dithiolanes 248 to their S-monooxides 249 (equation 134). It was observed that the optical induction on sulphur (e.e. from 68 to 83%) is not significantly affected by the substituents R1 and R2. Asymmetric oxidation of a few aryl methyl sulphides by organic hydroperoxides in the presence of a catalytic amount of the optically active Schiff base-oxovanadium(IV) complexes gave the corresponding sulphoxides with e.e. lower than 40%289. 

More recently, catalytic asymmetric allylations of imines and imine derivatives in aqueous media have been studied. An /V-spiro C2-symmetrical chiral quaternary ammonium salt (5,5)-I-Br (,S, .S )-()-Np-NAS-Br] has been evaluated in the allylation of glycine tert-Bu ester benzophenone Schiff base [Ph2C=NCH2COOCMe3] for synthesis of both natural and unnatural a-amino acids (Eq. 11,45).76... 

Interaction of Ni11 ions with amino acids is also important for asymmetric synthesis of amino acids. A convenient large-scale asymmetric synthesis of enantiometrically pure trans-cinnamyl-glycine and -o-alanine via reaction of cinnamyl halides with Ni11 complexes of a chiral Schiff base of glycine and alanine has been elaborated.1711 Similar procedures have been applied to other amino acids as well.1712... 

Aldolases catalyze asymmetric aldol reactions via either Schiff base formation (type I aldolase) or activation by Zn2+ (type II aldolase) (Figure 1.16). The most common natural donors of aldoalses are dihydroxyacetone phosphate (DHAP), pyruvate/phosphoenolpyruvate (PEP), acetaldehyde and glycine (Figure 1.17) [71], When acetaldehyde is used as the donor, 2-deoxyribose-5-phosphate aldolases (DERAs) are able to catalyze a sequential aldol reaction to form 2,4-didexoyhexoses [72,73]. Aldolases have been used to synthesize a variety of carbohydrates and derivatives, such as azasugars, cyclitols and densely functionalized chiral linear or cyclic molecules [74,75]. 

The Schiff bases being derivatives of aldehydes or ketones and various amines have received considerable attention because of their interesting physical and chemical properties, involvement in biologically important reactions and widespread application of their metal complexes. Increasing interest in optically active Schiff bases is connected with the discovery at the beginning of the 1990s of the so-called Jacobsen catalysts used in several asymmetric reactions showing excellent enantioselectivity. 

Tanaka et al.28 have synthesised a series of (S)-chiral Schiff bases as the highly active (yield 69-99%) and enatioselective (ee 50-96%) catalysts in the reaction of addition of dialkylzinc to aldehydes. The stereochemistry of the asymmetric addition was suggested. In a transition state when S-chiral Schiff base was used as chiral source, the alkyl nucleophile attacked Re face of the activated aldehyde and formed the R-configuration alkylated product [13]. 

In 1966, Nozaki et al. reported that the decomposition of o-diazo-esters by a copper chiral Schiff base complex in the presence of olefins gave optically active cyclopropanes (Scheme 58).220 221 Following this seminal discovery, Aratani et al. commenced an extensive study of the chiral salicylaldimine ligand and developed highly enantioselective and industrially useful cyclopropanation.222-224 Since then, various complexes have been prepared and applied to asymmetric cyclo-propanation. In this section, however, only selected examples of cyclopropanations using diazo compounds are discussed. For a more detailed discussion of asymmetric cyclopropanation and related reactions, see reviews and books.17-21,225... 

A range of L-cysteine derivatives bearing a 1,2,4-triazolyl residue on the sulfur atom has been prepared by the asymmetric Michael addition of 4,5-dialkyl-3-mercapto-l,2,4-triazoles to a nickel Schiff base complex. The enantiomeric excesses of the product aminoacids were measured and found to be greater than 98.5% in some cases <2004TA705, 2004RCB932, 2004IZV894>. 

Jacobsen and co-workers14 have shown that a tridentate Schiff base chromium complex 13 catalyzed an asymmetric carbonyl-ene reaction between a variety of aryl aldehydes (14, Equation (8)) and 2-methoxy propene 15 or 2-trimethylsiloxypropene. The highest yields were afforded when the aryl ring was substituted with an electron-withdrawing group however, the substituent did not seem to affect the enantioselectivity. 

When p-chlorobenzophenone dichloride reacts with methylamine there results an oil consisting of similar amounts of the syn and anti Schiff base 19. This oil, on standing at room temperature for 2 weeks, transforms to crystals of only the syn isomer. If these crystals are heated above their melting point (125°) for a few minutes, or are dissolved in cyclohexane and allowed to stand at room temperature for 2 weeks, the syn isomer reconverts to a mixture of the two isomers (61a). [This seems to be an example of the so-called second-order or crystallization-induced asymmetric transformations (61b).] A number of systems of this series were known, from previous work, to be dimorphic however, Curtin and Hausser found no case in which it was established that two crystal forms correspond to different isomers (61a). 

Asymmetric ring-opening of saturated epoxides by organocuprates has been studied, but only low enantioselectivities (< 15% ee) have so far been obtained [49, 50]. Muller et al., for example, have reported that the reaction between cyclohexene oxide and MeMgBr, catalyzed by 10% of a chiral Schiff base copper complex, gave trans-2-methylcyclohexanol in 50% yield and with 10% ee [50]. 

Scheme 2.55 The combinatorial preparation of schiff bases as ligands for asymmetric catalysis.

Belokon, Y. N. Chusov, D. Borkin, D. A. Yashkina, L. V. Dmitriev, A. V. Katayeva, D. North, M. (2006) Chiral Ti(lV) complexes of hexadentate Schiff bases as precatalysts for the asymmetric addition of TMSCN to aldehydes and the ring opening of cyclohexane oxide.. Tetrahedron Asymmetry, 17, 2328-2333. 

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