Enantioselective oxidations chiral reagents

These reagents exhibit good stereoselectivity toward chiral reactants, such as acylox-azolidinones.253 Chiral oxaziridine reagents have been developed that can achieve enantioselective oxidation of enolates to a-hydroxyketones.254... 

Optically active oxaziridines are useful reagents for the enantioselective oxidation of olefins 37 39). The following three preparative methods to make this reagent available have been reported enantioselective oxidation of an imine by (-)-peroxycam-phoric acid 37,38), photocyclization of a nitrone which has a chiral substituent39), and photocyclization of a nitrone in an optically active solvent 39). However, an... 

Uemura and coworkers utilized (R)-binaphthol 85 as chiral ligand in place of DET in association with Ti(IV)/TBHP, which not only mediated the oxidation of sulfides to (R)-configurated sulfoxides, but also promoted the kinetic resolution of sulfoxides (equation 50). In this latter process the two enantiomers of the sulfoxide are oxidized to sulfone by the chiral reagent at different rates, with decrease of the chemical yield, but increase of the ee values. Interestingly, the presence of ortho-nilro groups on the binaphthol ligand lead to the reversal of enantioselectivity with formation of the (5 )-configurated sulfoxide. Non-racemic amino triols and simple 1,2-diols have been successfully used as chiral mediators. 

More examples are found for varied oxidation processes mainly for various epoxidations carried out by metal catalysts bearing F-modified ligands, such as porphyrins,139 Ru perfluoroacetylacetonate salt,140 or salen complexes,141 142 or using the 3 selenium compound as catalyst.143 The potential for enantioselective transformations offering an easy way to recover precious chiral reagents and catalysts was demonstrated in enantioselective epoxidation using fluorous chiral salen... 

Chiral sulfoxides or selenoxides.1 This oxaziridine (1) is generally more effective than the modified Sharpless reagent of Kagan (13, 52) for enantioselective oxidation of alkyl aryl sulfides or selenides to the corresponding sulfoxides or selenoxides. The polar Cl groups of 1 improve both rate and the enantioselectivity. 

The conclusion drawn from Section 3.4.1 for the hydroborations to be discussed here is this an addition reaction of an enantiomerically pure chiral reagent to a C=X double bond with enantiotopic faces can take place via two transition states that are diastereotopic and thus generally different from one another in energy. In agreement with this statement, there are diastereoselective additions of enantiomerically pure mono- or dialkylboranes to C=C double bonds that possess enantiotopic faces. Consequently, when one subsequently oxidizes all C— B bonds to C—OH bonds, one has realized an enantioselective hydration of the respective alkene. 

The most intriguing work in the field of asymmetric oxidative aryl coupling has been directed towards finding catalytic enantioselective reactions. The main goal in these studies has been the synthesis of chiral binaphthyl units as an improvement over stoichiometric chiral reagent enantioselective syntheses. 

In the former case, almost complete stereoselective oxidation to the chiral selenoxides has been accomplished quite recently. The Davis oxidant, 3,3-di-chloro-l,7,7-trimethyl-2 -(phenylsulfonyl)spirobicyclol2.2.11heptane-2,3 -oxa-ziridine, was found to be the most efficient reagent for the enantioselective oxidation of a variety of prochiral alkyl aryl selenides [81. Asymmetric oxidation was accomplished by the treatment of the selenides with 1 molar equivalent of the Davis oxidant at 0°C to afford the corresponding chiral alkyl aryl selenoxides in quantitative yields with 91-95% ee (Scheme 1). The oxidation of methyl phenyl selenide was complete within 1 min, whereas that of triiso-propyl(a bulkier alkyl) phenyl selenide required a few hours. Typical results are... 

Preparative Methods the title reagent can be prepared from commercially available (1,2-benzenedithiol and 1,3-dichloroacetone. After condensation of these reagents in the presence of DMAP, the resulting l,5-benzodithepan-3-one is enantioselectively oxidized to the (/f)-monosulfoxide by modified Sharpless oxidation [cumene hydroperoxide, Ti(0-t-Pr)4] in the presence of (-F)-diethyl tartrate as a chiral ligand. - Subsequent dry ozonation" of the (/f)-monosulfoxide affords (lf ,5f )-bis-sulfoxide 1, having >98% optical purity. Alternative use of (—)-diethyl tartrate in the modified Shaipless oxidation makes possible convenient access to enantiomeric (15,5S)-1. ... 

Several oxaziridines related to (14) (eq 8) have been used, most notably in the enantioselective oxidation of sulfides to sulfoxides, of selenides to selenoxides, and of alkenes to oxiranes, It is also the reagent of choice for the hydroxylation of lithium and Grignard reagents and for the asymmetric oxidation of enolates to give a-hydroxy carbonyl compounds, - A similar chiral fluorinating reagent has also been developed, ... 

Enantioselective oxidation using Davis chiral oxaziridine reagents is not as well developed as its diastereoselective counterpart. However, a number of simple enolates have been... 

For the enantioselective oxidations of organic sulfides to chiral sulfoxides using iodine(V) reagents, also see Section 3.2. 

Copper(II)-amine complexes are widely used and very effective phenolic oxidative coupling reagents. Since the reaction proceeds within the copper coordinative sphere, chiral amine ligand does induce the enantioselective oxidative couplings of phenols such as 2-naphthol [39-41], or 9-phenanthrol [42,43] to form respective atropisomeric... 

The Sharpless epoxidation of allylic alcohols by hydroperoxides uses as mediator [45] or as catalyst [46] a chiral titanium complex obtained from the combination Ti(OPr )4/diethyl tartrate (DET) in 1 1 ratio. Kinetic resolution of P-hydroxysulfides was also observed, but without diastereoselectivity for the product P-hydroxysulfoxides [47]. We found that the Sharpless reagent deactivated by 1 equivalent of water allows the enantioselective oxidation of aryl methyl sulfides into sulfoxides to be performed with ee s up to 90% [4S-50]. The best reagent combination proved to be Ti(0Pr )4/DET/H20 = 1 2 1. Independently, Modena et al. obtained similar enantioselectivities with the combination Ti(OPr )4/DET in 1 4 ratio [51]. These two combinations are sometimes referred to as the Kagan reagent and the Modena reagent, respectively. They will be considered successively. 

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