Amine oxides kinetic resolution

Tertiary alkylamines can be converted into the corresponding N-oxides with hydrogen peroxide or with peroxy acids." r-Butyl hydroperoxide has also been used in the presence of a catalyst such as VO(acac)2. Sharpless and coworkers have carried out the oxidative kinetic resolution of several p-hy-droxy tertiary amines such as (41) with r-butyl hydroperoxide, titanium(rv) isoprcqtoxide and (-i-)-diiso-propyl tartrate, the titanium(rv) tartrate ratio being ateut 2 1." After 60% conversion, one enantiomer was selectively oxidized, and the other enantiomer could be recovered in good optical purity (Scheme... 

Starting from a racemic mixture of 1-phenylethyl amine derivatives, the MAO-N-mediated oxidative kinetic resolution of the (S)-enantiomer affords the ketone (after hydrolysis of the imine) besides the nonconverted (R)-enantiomer of the amine. 

Uemura s discovery also opened the door to direct 02-coupled asymmetric catalytic oxidative kinetic resolution (OKR) of alcohols with catalytic amounts of chiral ligands. Simultaneously both Stoltz and Sigman reported the aerobic OKR of secondary alcohols using catalytic Pd[(-)-sparteine]Q2 with the addition of catalytic (-)sparteine, 36 (Scheme 5.18E) [66]. Mechanistic studies on this system performed by Sigman and coworkers have found the chiral amine to have a dual role as a hgand and an exogenous base [66e,hj. This system has been further apphed to asymmetric Wacker-type cyclizations [2 c, 22a,bj. 

This mechanism is the same as that of 19-23 the products differ only because tertiary amine oxides cannot be further oxidized. The mechanism with other peroxyacids is probably the same. Racemic (3-hydroxy tertiary amines have been resolved by oxidizing them with t-BuOOH and a chiral catalyst one enantiomer reacts faster than the other.This kinetic resolution gives products with enantiomeric excesses of > 90%. 

Mikolajczyk and coworkers have summarized other methods which lead to the desired sulfmate esters These are asymmetric oxidation of sulfenamides, kinetic resolution of racemic sulfmates in transesterification with chiral alcohols, kinetic resolution of racemic sulfinates upon treatment with chiral Grignard reagents, optical resolution via cyclodextrin complexes, and esterification of sulfinyl chlorides with chiral alcohols in the presence of optically active amines. None of these methods is very satisfactory since the esters produced are of low enantiomeric purity. However, the reaction of dialkyl sulfites (33) with t-butylmagnesium chloride in the presence of quinine gave the corresponding methyl, ethyl, n-propyl, isopropyl and n-butyl 2,2-dimethylpropane-l-yl sulfinates (34) of 43 to 73% enantiomeric purity in 50 to 84% yield. This made available sulfinate esters for the synthesis of t-butyl sulfoxides (35). 

Scheme 6 Kinetic resolution in the oxidation of a rac-sec amine with a non racemic nitroxyl mediator.

The vinyloxirane reaction was later extended to methylidene cyclohexene oxide and to related meso derivatives [53]. The effects of the diastereomeric ligands 42 and 43 (Fig. 8.5), derived from (S)-binaphthol and (S, S)- or (R, R)-feis-phenylethyl-amine respectively, were investigated. In the case of kinetic resolution of racemic methylidene cyclohexane epoxide 45 with Et2Zn, ligand 42 produced better yields, regioselectivity, and enantioselectivity than 43 (Scheme 8.27). 

The [3-hydroxy amines are a class of compounds falling within the generic definition of Eq. 6A.6. When the alcohol is secondary, the possibility for kinetic resolution exists if the Ti-tartrate complex is capable of catalyzing the enantioselective oxidation of the amine to an amine oxide (or other oxidation product). The use of the standard asymmetric epoxidation complex (i.e., T2(tartrate)2) to achieve such an enantioselective oxidation was unsuccessful. However, modification of the complex so that the stoichiometry lies between Ti2 (tartrate) j and Ti2(tartrate)1 5 leads to very successful kinetic resolutions of [3-hydroxyamines. A representative example is shown in Eq. 6A.11 [141b,c]. The oxidation and kinetic resolution of more than 20 secondary [3-hydroxyamines [141,145a] provides an indication of the scope of the reaction and of some... 

This possibility of intimate association of rhodium with the aromatic ring suggests further experiments. A logical extension of asymmetric syntheses involving prochir-al reactants is a kinetic resolution with related chiral reactants under similar conditions. In the one case of hydroboration-amination where this has been applied, it has proved to be very effective. The reactant was prepared directly by a Heck reaction on 1,2-dihydronaphthalene, and under the standard conditions of catalytic hydrobora-tion gave >45% of both enantiomerically pure recovered alkene with (after oxidative work-up) the alcohol of opposite hand, mainly as the trans-isomer. This procedure forms a simple and potentially useful route to pharmacologically active substances, demonstrated by the racemic synthesis shown [105] (Scheme 34). 

Resolution of -hydroxy t-amines. These amines can undergo kinetic resolution by partial oxidation of one enantiomer to the N-o[Pg.92]

Chromium(salen) catalysts are excellent reagents for the desymmetrization of OT to-epoxides. Thus, tfr-stilbene oxide is converted to the (3, 3 )-aminoalcohol in the presence of catalytic quantities of chromium-salen complex in methylene chloride solution open to the atmosphere. The addition of small quantities of triethylamine was found to dramatically increase enantioselectivities (by almost 25%). This catalytic system also promotes an efficient aminolytic kinetic resolution (AKR) of racemic epoxides with 2-type symmetry (Equation 18) <20040L2173, 1999TL7303>. W fo-Epoxides can be opened with aromatic amines in water in the presence of 1 mol% of an Sc(ni) catalyst ligated to 1.2mol% of a chiral bipyridine ligand <2005OL4593>. 

In addition to stereoselective metalation, other methods have been applied for the synthesis of enantiomerically pure planar chiral compounds. Many racemic planar chiral amines and acids can be resolved by both classical and chromatographic techniques (see Sect. 4.3.1.1 for references on resolution procedures). Some enzymes have the remarkable ability to differentiate planar chiral compounds. For example, horse liver alcohol dehydrogenase (HLADH) catalyzes the oxidation of achiral ferrocene-1,2-dimethanol by NAD to (S)-2-hydroxymethyl-ferrocenealdehyde with 86% ee (Fig. 4-2la) and the reduction of ferrocene-1,2-dialdehyde by NADH to (I )-2-hydroxymethyl-ferrocenealdehyde with 94% ee (Fig. 4-2lb) [14]. Fermenting baker s yeast also reduces ferrocene-1,2-dialdehyde to (I )-2-hydroxymethyl-ferro-cenealdehyde [17]. HLADH has been used for a kinetic resolution of 2-methyl-ferrocenemethanol, giving 64% ee in the product, (S)-2-methyl-ferrocenealdehyde... 

Kinetic resolution with racemisation Enzymes versus whole organisms Desymmetrisation with lipases Immobilised enzymes in desymmetrisation Polymer-supported reagents and enzymes Effects of amines on lipases and esterases Other acylating enzymes Enzymatic Oxidation... 

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