Enantioselective oxidation sulfides

The synthesis of a series of chiral organophosphine oxide/sulfide-substituted binaphtholate ligands has recently been reported by Marks and Yu and their corresponding lanthanide complexes characterized. These complexes, generated in situ from Ln[N(TMS)2]3, cleanly catalysed enantioselective intramolecular hydroamination/cyclisation of 1-amino-2,2-dimethyl-4-pentene albeit with a low enantioselectivity of 7% ee (Scheme 10.82). 

As shown in Table 12,H202 and fBuOOH have been used frequently as oxygen donors in peroxidase-catalyzed sulfoxidations. Other achiral oxidants, e.g. iodo-sobenzene and peracids, are not accepted by enzymes and, therefore, only racemic sulfoxides were found (c.f. entries 34-36). Interestingly, racemic hydroperoxides oxidize sulfides to sulfoxides enantioselectively under CPO catalysis [68]. In this reaction, not only the sulfoxides but also the hydroperoxide and the corresponding alcohol were produced in optically active form by enzyme-catalyzed kinetic resolution (cf. Eq. 3 and Table 3 in Sect. 3.1). 

In the case of the oxidation of methyl alkyl sulfides, enantioselectivity remains in the range of 50-60% ee (Table 6C.2). Disufides R-S-S-R, sulfenamides R-S-NR 2, and sulfenates R-S-O-R were oxidized to the corresponding chiral thiosulfinates, sulfinamides, and sulfinates, respectively (<52% ee, Table 6C.3) [21]. 

An interesting behavior of the Padua reagent (Ti(0-i-Pr)4/(/ ,i )-DET = 1 4) was described by Scretti et al. [42,43], who used racemic furylhydroperoxides 1 instead of cumyl hydroperoxide as oxidant. The enantioselectivities in the oxidation of methyl aryl sulfides are very good. For example, methyl p-tolyl sulfoxide was obtained in 75% yield and >95% ee together with about 15% of sulfone by using hydroperoxide 1(R =OEt,R = /-PrandR3 = Me) Simultaneously there is a kinetic resolution of the racemic hydroperoxide takes place is used in excess (2 mol equiv. with respect to sulfide). Thus in the example mentioned above, the enantiopurity of the residual hydroperoxide was 81% ee. It has also been established that some kinetic resolution of... 

Pseudomonas oleovorans contains P. oleovorans monooxygenase (POM), which is a typical co-hydroxylase for hydroxylation of the terminal methyl of alkanes as well as epoxidation of terminal olefins. The co-hydroxylation system of P. oleovorans was reconstituted from purified components, POM, rubredoxin, and a flavoprotein reductase [122], In the presence of NADH and oxygen, it oxidizes a wide range of aliphatic methyl alkyl sulfides. Enantioselectivities are very much dependent of the length of the alkyl chain of Me-S(0)-R, as exemplified by the following results ... 

In addition, these iron(salen) catalysts can oxidize sulfides using other oxidants such as H202, TBHP or m-CPBA with notable chemical selectivity (75-98%) however, no enantioselectivity was observed. 

Chloroperoxidase Enantioselective oxidation of sulfides Enantioselective oxidation of racemic epoxyalcohols Oxidation of benzyl alcohol Epoxidation of styrene Asymmetric oxidations Halogenation reactions [11, 15,77] [15, 48] [14] [78] [79] [80]... 

The general methods of preparation of phosphole oxides, sulfides, and selenides have been described in Section 3.15.5.1.3. A tentative resolution of chiral phosphole 76 under kinetic dynamic resolution conditions is noteworthy, despite only low enantioselectivities (10-20%) having been obtained (Scheme 20) <2004TA3519>. 

Sulfides are oxidized to sulfoxides. One application of this reaction is the removal of a benzylthioethyl group from protected oligosaccharides. The oxidation makes the group base-labile. When the sulfide is coordinated to a metal that also bears chiral ligands, the oxidation becomes enantioselective. ... 

Fujita et al. used a catalytic amount of a binuclear titanium(IV) complex in an attempt to find an efficient system to oxidize sulfides with high enantioselectivity [102]. Prior to this study, they investigated other systems with several transition metals. A similar asymmetric sulfoxidation was discovered [105] using a catalytic amount of nonracemic Schiff base oxovanadium complex (Table 1.4) under atmospheric conditions at room temperature in dichloromethane. With 0.1 mol% of catalyst and cumene hydroperoxide as oxidant, oxidation produces sulfoxides in excellent yields. However, the reaction is limited to alkyl aryl sulfide substrates, and the best enantioselectivity obtained was 40% ee, for (S)-methyl p-methoxy phenyl sulfoxide. 

Katsuki and Saito reported that di-p-oxo titanium complexes of chiral salen ligands serve as efficient catalysts for asymmetric oxidation of a range of sulfides using H 2O2 or UHP as terminal oxidants [149]. Enantioselectivities as high as 94% were achieved [149]. A monomeric peroxo titanium species was proposed as the active oxidant based on MS and NMR studies [150]. 

SIBX is a non-explosive formulation of the X -iodane 2-iodoxybenzoic acid (IBX) stabilized by benzoic acid. This reagent combination can be used as a suspension in various organic solvents to oxidize sulfides to sulfoxides. Most yields were comparable to those obtained using IBX or other iodanes such as PhlO and Phl02. The use of a chiral tartaric acid-based source in addition to SIBX gave asymmetric sulfoxide formation with moderate enantioselectivities [81]. 

Unfortunately, the highest enantioselectivity so far obtained for the synthesis of styrene oxide by this route is only 57 % ee with Goodman s sulfide 30 [21]. Thus methylidene transfer is not yet an effective strategy for the synthesis of terminal epoxides. 

Encapsulation in Y zeohte was also the method chosen to immobihze Mn complexes of C2-symmetric tetradentate hgands (Fig. 24) [75]. These materials were used as catalysts for the enantioselective oxidation of sulfides to sulfoxides with NaOCl. The lack of activity when the larger io-dosylbenzene was used as an oxidant was interpreted as an indication that the reaction took place inside the zeolite microporous system. Both the chemo- and enantioselectivity were dependent on the structure of the sulfide. (2-Ethylbutyl)phenylsulfide led to better results than methylphenylsulfide, although in all cases the enantioselectivity was low (up to 21% ee). 

Ohta and coworkers used a bacterium, Corynebacterium equi IFO 3730, rather than a fungus, to oxidize eight alkyl phenyl and p-tolyl sulfides to their respective sulfoxides (119, 120) of configuration R. Virtually all of the sulfur compounds were accounted for as the sum of uncreacted sulfide, sulfoxide and sulfone. The enantiomeric purities of the sulfoxides obtained were quite good and are shown below in parentheses. The formation of the allyl sulfoxides in high optical purity is noteworthy. The authors believe that the sulfoxides were formed by enantioselective oxidation of the sulfides rather than by enantioselective oxidation of racemic sulfoxides, since the yield of sulfoxides was greater than 50% in five of the ten oxidations reported (see also Reference 34). 

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