Secondary alcohols, oxidative kinetic

SCHEME 34.35. Structure of (—(-aurantioclavine 133 and details of the secondary alcohol oxidation kinetic resolution step. 

SCHEME 34.37. Structure of (-l-)-amurensinine 141 and details of the asymmetric secondary alcohol oxidative kinetic resolution step. 

SCHEME 34.41. Asymmetric secondary alcohol oxidation kinetic resolution step in the synthesis of human neurokinin receptor antagonist h-NKl 156. 

The kinetics of secondary alcohol oxidation has been investigated with various reactants. When 2-octanol is oxidized with acetone solvent in the presence of excess reactant, the reaction is first-order with respect to H2O2 and zero-order with respect to the alcohol. Typical results are presented in Fig. 21. 

Asymmetric secondary alcohol oxidation can also be performed with other metal complexes, in particular Toste showed that traditional Schiff based V catalysts prepared in situ from the corresponding ligand and VO(0-/Pr)3 allowed the kinetic resolution of a-hydroxy esters in acetone under mild experimental conditions and with 1 atm of O2 (Scheme 23.36). The reaction works well for both henzyUc and... 

The complex Pd-(-)-sparteine was also used as catalyst in an important reaction. Two groups have simultaneously and independently reported a closely related aerobic oxidative kinetic resolution of secondary alcohols. The oxidation of secondary alcohols is one of the most common and well-studied reactions in chemistry. Although excellent catalytic enantioselective methods exist for a variety of oxidation processes, such as epoxidation, dihydroxy-lation, and aziridination, there are relatively few catalytic enantioselective examples of alcohol oxidation. The two research teams were interested in the metal-catalyzed aerobic oxidation of alcohols to aldehydes and ketones and became involved in extending the scopes of these oxidations to asymmetric catalysis. 

In 2003, Sigman et al. reported the use of a chiral carbene ligand in conjunction with the chiral base (-)-sparteine in the palladium(II) catalyzed oxidative kinetic resolution of secondary alcohols [26]. The dimeric palladium complexes 51a-b used in this reaction were obtained in two steps from N,N -diaryl chiral imidazolinium salts derived from (S, S) or (R,R) diphenylethane diamine (Scheme 28). The carbenes were generated by deprotonation of the salts with t-BuOK in THF and reacted in situ with dimeric palladium al-lyl chloride. The intermediate NHC - Pd(allyl)Cl complexes 52 are air-stable and were isolated in 92-95% yield after silica gel chromatography. Two diaster corners in a ratio of approximately 2 1 are present in solution (CDCI3). 

All the oxidants convert primary and secondary alcohols to aldehydes and ketones respectively, albeit with a great range of velocities. Co(III) attacks even tertiary alcohols readily but the other oxidants generally require the presence of a hydrogen atom on the hydroxylated carbon atom. Spectroscopic evidence indicates the formation of complexes between oxidant and substrate in some instances and this is supported by the frequence occurrence of Michaelis-Menten kinetics. Carbon-carbon bond fission occurs in certain cases. 

Discussion of ketone oxidation has centred around the identity of the molecule undergoing oxidation. This has been clearly resolved in some, but not all, cases, the evidence resting on (i), the relative rates of enolisation and oxidation, (ii) kinetic orders and (ih) isotope effects. A general feature of the oxidations of ketones by one-equivalent reagents is that the rate for a given oxidant exceeds that for oxidation of a secondary alcohol by the same oxidant. The most attractive explanation is that the radical formed from a ketone is stabilised by delocalisation, viz. 

The oxidations of formic acid by Co(III) and V(V) are straightforward, being first-order with respect to both oxidant and substrate and acid-inverse and slightly acid-catalysed respectively. The primary kinetic isotope effects are l.Sj (25°C)forCo(IU)and4.1 (61.5 C°)for V(V). The low value for Co(lII) is analogous to those for Co(IIl) oxidations of secondary alcohols, formaldehyde and m-nitrobenzaldehyde vide supra). A djo/ h20 for the Co(III) oxidation is about 1.0, which is curiously high for an acid-inverse reaction . The mechanisms clearly parallel those for oxidation of alcohols (p. 376) where Rj and R2 become doubly bonded oxygen. 

The kinetics of the initial stages of the oxidation of some a-hydroxy-carboxylic such as lactic, malic and mandelic acids by chromic acid have been studied by Bakore and Narain . The initial reaction resembles the oxidation of a secondary alcohol to ketone. The authors concluded that the rate determining step involves C-H bond rupture at the a-carbon atom. The rate of oxidation of these acids is reduced to one-half by the addition of manganous ions, when the concentration of the latter is commensurable with that of the acids. 

Interestingly, the scope of the reaction using this catalyst can be extended to oxidative kinetic resolution of secondary alcohols by using (-)-sparteine as a base (Table 10.2) [25]. The best enantiomeric excess of the alcohol was obtained when a chiral enantiopure base and an achiral catalyst were used. The use of chiral enantiopure catalyst bearing ligand 17 led to low enantioselectivity. 

Both pyridinium salts and pyridine A-oxides are of increased interest as chiral catalysts in organic reactions. Connon and Yamada independently designed and examined pyridinium salts as chiral catalysts in the acylation of secondary alcohols <06OBC2785 06JOC6872>. These two catalysts can be used for kinetic resolution of various sec-alcohols and uf/-diols in good to moderate enantiomeric excess. 

Chromium(III) catalyses the cerium(IV) oxidation of primary and secondary alcohols in a mixture of H2SO4 and HC104. Kinetic results have been interpreted in terms of the formation of chromium(IV) in a reversible equilibrium, which forms a complex with the alcohol. Internal oxidation-reduction occurs in a rate-determining step to give aldehyde or ketone and regenerate the catalyst in the +3 state. The oxidation of ethanol under similar conditions has also been studied. ... 

Complex (1) is a catalyst for selective oxidation of benzylic, allylic alcohols to aldehydes, and secondary alcohols to ketones using r-butyl hydroperoxide. Primary aliphatic alcohol oxidation failed. The use of cumyl hydroperoxide as radical probe discounted the involvement of i-BuO /t-BuOO. Hammett studies p = -0.47) and kinetic isotope effects kn/ku = 4.8) have been interpreted as suggesting an Ru—OO—Bu-i intermediate oxidant. 

The oxidations of secondary alcohols and sulfides by halamine polymers produce ketones and sulfoxides, respectively, with some sulfones and chlorosulfoxides produced in the latter case. A mechanism is proposed based on the oxidation kinetics. 

The enantioselective oxidative coupling of 2-naphthol itself was achieved by the aerobic oxidative reaction catalyzed by the photoactivated chiral ruthenium(II)-salen complex 73. 2 it reported that the (/ ,/ )-chloronitrosyl(salen)ruthenium complex [(/ ,/ )-(NO)Ru(II)salen complex] effectively catalyzed the aerobic oxidation of racemic secondary alcohols in a kinetic resolution manner under visible-light irradiation. The reaction mechanism is not fully understood although the electron transfer process should be involved. The solution of 2-naphthol was stirred in air under irradiation by a halogen lamp at 25°C for 24 h to afford BINOL 66 as the sole product. The screening of various chiral diamines and binaphthyl chirality revealed that the binaphthyl unit influences the enantioselection in this coupling reaction. The combination of (/f,f )-cyclohexanediamine and the (R)-binaphthyl unit was found to construct the most matched hgand to obtain the optically active BINOL 66 in 65% ee. 

The groups of Sigman and Stoltz have concurrently published the palladium-catalyzed oxidative kinetic resolution of secondary alcohols using molecular oxygen as the stoichiometric oxidant. Both communications also described a single example of a diol desymmetrization using a palladium catalyst in the presence of (—(-sparteine [Eqs. (10.42) ° and (10.43) ] ... 

Oxidative kinetic resolution of secondary alcohols mediated with a catalytic amount of optically active binaphthyl-type iV-oxyl has been performed with high selectivity". Also, it has mediated oxidative asymmetric desymmetrization of primary alcohols with good selectivity (equation 25)". ... 

The bulky tetraarylbismuthonium salts were found to oxidize primary alcohols far more rapidly than secondary alcohols (Scheme 23). The primary/secondary selectivity achieved by the mesitylbismuthonium salt increases as the bulkiness of the a-substituents of the alcohols increases (Me < Et < i-Pr). This suggests that the a-substituents of the alcohol retard the nucleophilic attack on the bismuth center kinetically. The PhCH2OH/PhCH(Et)OH selectivity observed for the mesityl- and... 

Some lactol-to-lactone oxidations were effected by TPAP/NMO/PMS/CH Clj [498, 499], or TPAP/NMO/PMS/CH3CN [159]. The system RUCI3 or RuO / Na(Br03)/aq. M Na3(C03) generates [RuO ]" in aqueous solution and oxidised secondary alcohols to ketones in high yield (Table 2.2) [213]. Kinetics of the oxidation of benzhydrol and 9-fluorenol by TPAP/NMO/CH3CN/30°C were measured. 

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