Oxidative sparteine

Spartyrine is obtained by oxidizing sparteine with chromic-sulfuric acid. It is identical with S-diplospartyrine (LXV) which is obtained by condensation of 17 hydroxysparteine with Ji. jjghydro-sparteine at pH 7 60). The analogous condensation of 17-hydroxy-sparteine with J ii-dehydrosparteine gives rise to S-diplospartyrine (LXV). Colored by-products are also formed and possible structures are given. 

In 1931 Winterfeld and Kneuer, as a result of their observation that jS-lupinane can be obtained from lupanine, and the formation of 2-methyl-pyrrolidine by the oxidation of sparteine, combined these two features in a partial formula (II) for lupanine, which could be developed in various ways depending on the mode of attachment of the methylpyrrolidine residue. In view, however, of Ing s demonstration of the relationship of anagyrine, CJ5H20ON2, to Z-lupanine, CJ5H24ON2, and d-sparteine, C15H28N2, it was elearly neeessary to consider formul for lupanine derivable from the two alternati-ves, which Ing had proposed for anagyrine and which are shown below as (III) and (IV) with the formul for lupanine derived from them (V) by Ing and (VI) by Clemo and Raper. Sparteine would be represented by (V) or (VI) with the change CO CH2. 

Sparteine (43) is oxidized to a mixture of isomers /J -didehydro-sparteine (44) and id -dehydrosparteine (45) (57). The other two stereoisomers of sparteine, a-isosparteine (46) (3S,j9) and S-isosparteine (sparta-lupine) (47) (58,60) have been subjected to mercuric acetate oxidation, each giving Zl -didehydrosparteine (44). 

The foregoing examples do not represent useful chiral formyl anion equivalents in a direct sense since the stereoselectivity of the initial addition to aldehydes is poor, although as has been explained, the situation is salvaged by oxidation and re-reduction. On the other hand, by lithiation at the 2 position of the achiral oxazo-lidine 53 in the presence of (-)-sparteine followed by addition of benzaldehyde, useful levels of d.e. and e.e. are achieved directly (98TA3125). For example, by adding MgBr2 before the benzaldehyde, the major product obtained is 54 in 80% d.e. and 86% e.e. 

Alkyldimethylphosphine-boranes 74 underwent enantioselective deprotonation employing (-)-sparteine/s-BuLi, followed by oxidation with molecular oxygen [91, 92] in the presence of triethyl phosphite (Scheme 12) to afford moderate yields of enantiomerically enriched alkyl(hydroxymethyl)methylphosphine-bo-ranes 76, with 91-93% ee in the case of a bulky alkyl group and 75-81% ee in the case of cyclohexyl or phenyl groups [93]. Except for the adamantyl derivative (in which the ee increased to 99%), no major improvement in the ee was observed after recrystallization. 

A catalytic version of the coupling was also developed, by using 10 mol % of CuCl2 and 20 mol % of sparteine 1 (silver chloride was used as a stoichiometric oxidant to regenerate the copper (II) oxidant). This catalytic system was applied to the asymmetric cross-coupling leading to 101 in a 41% yield and 32% ee. 

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. 

Sigman et al. have optimized their system too [45]. A study of different solvents showed that the best solvent was f-BuOH instead of 1,2-dichloroethane, which increased the conversion and the ee. To ensure that the best conditions were selected, several other reaction variables were evaluated. Reducing the catalyst loading to 2.5 mol % led to a slower conversion, and varying temperature from 50 °C to 70 °C had little effect on the selectivity factor s. Overall, the optimal conditions for this oxidative kinetic resolution were 5 mol % of Pd[(-)-sparteine]Cl2, 20 mol % of (-)-sparteine, 0.25 M alcohol in f-BuOH, molecular sieves (3 A) at 65 °C under a balloon pressure of O2. 

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). 

Liaw et al. reported that conversions between the neutral sparteine [Fe(NO)2] complex 133 and the anionic Fe(NO)2 [Fe(NO)2(S2C3Hg)] 137 proceed via the cationic sparteine Fe(NO)2 -complex 135 through oxidation by NO" " and transfer of the [Fe(NO)2] -unit to the chelating ligand S-(CH2)3-S 136 (Scheme 35). The resulting anionic complex 137 is stable in contrast to the cationic complex 135. The cationic complex 135 also acts as a [Fe(NO)2] donor in the presence of the DNIC [(PhS)2Fe(NO)2] 138 to yield Roussin s red ester 139. The bidentate thiol ligand S-(CH2)3-S 136 promotes the stability of the anionic DNIC Fe(NO)2 ... 

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. 

Scheme 10.6 Mechanism of aerobic oxidation catalysed by complex 13 [23] Table 10.2 Oxidative kinetic resolution of alcohols using (-)-sparteine [25]...

Several lupin alkaloids have been derived from the unsaturated quinalozidine 433, that was obtained in the treatment of amine 431 with ortho-quinone 432. This quinone behaves as a model of topaquinone, the cofactor of copper-containing amine oxidases. The cyclization step involved a nucleophilic attack of the piperidine nitrogen of 431 onto a side-chain aldehyde function that is unmasked by the oxidative deamination. Quinolizine 433, when treated with dehydropiperidine, gave the oxime ether 434 that, on ozonolysis followed by reduction, afforded sparteine 10, presumably via the bis(iminium) system 435 (Scheme 102) <1996JOC5581>. 

Asymmetric induction has also been achieved in the cyclization of aliphatic alcohol substrates where the catalyst derived from a spirocyclic ligand differentiates enantiotopic alcohols and alkenes (Equation (114)).416 The catalyst system derived from Pd(TFA)2 and (—)-sparteine has recently been reported for a similar cyclization process (Equation (115)).417 In contrast to the previous cases, molecular oxygen was used as the stoichiometric oxidant, thereby eliminating the reliance on other co-oxidants such as GuCl or/>-benzoquinone. Additional aerobic Wacker-type cyclizations have also been reported employing a Pd(n) system supported by A-heterocyclic carbene (NHC) ligands.401,418... 

The stoichiometric oxidative coupling of various phenols proceeds with moderate selectivity (76% ee) in the presence of (-)-sparteine CuCl2, Eq. 106 (127). As mentioned above, selectivity seems to be driven by solubility issues since isolation of the product from the precipitate or from solution results in different enantiose-lectivities. Indeed, this system performs far worse under catalytic conditions. The best result involves the use of silver chloride as reoxidant the heterooxidative coupling of two naphthols 182 and 183 affords the product 184 in 41% yield and 32% ee using 10 mol% catalyst, Eq. 107. 

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