Chiral compounds allylic amination

A novel procedure for the synthesis of an indole skeleton 81 was developed by Mori s group (Scheme 13).16e,16f Enantioselective allylic amination of 78 with A-sulfonated < r/ < -bromoaniline 79 followed by Heck cyclization of 80 provided chiral indoline 81. The treatment of a cyclohexenol derivative 78 with 79 in the presence of Pd2(dba)3-GHGl3 and ( )-BINAPO gave compound 80 with 84% ee in 75% yield. Total syntheses of (—)-tubifoline, (—)-dehydrotubifoline, and (—)-strychnine were achieved from compound 80. 

Despite the similarity between compound 1 and (-)-swainsonine, a different retrosynthetic strategy was devised for the synthesis of (-)-swainsonine (Scheme 3).19 The ring rearrangement yielded the hydropyrrolidine 5, which was prepared from the precursor 6. The enantiometrically pure oxazolidine derivative 7 was a suitable chiral starting material, as it was efficiently synthesised from the diol 8. As with the synthesis of 1, a palladium (0) catalysed allylic amination was carried out in the presence of ligand L (Scheme 2)14 to give 7 with an ee of 97%, which was increased to >99% on recrystallisation with dichloromethane/hexane. 

Heathcook et al. have performed a diastereoselective aza-ene reaction using chiral di-(+)-menthyl diazenedicarboxylate 91 as the nitrogen source [54]. Compound 91 was found to react with various alkenes in the presence of 2 equiv. SnCl4, and the corresponding allylic aminated product was obtained in good yield and with de up to 42 %. The problem with this approach was the removal of the chiral menthyl ester auxiliary, which was found to be rather difficult. 

As discussed above the kinetic stability of allylic sulfoximines prevents them from going downhill to the thermodynamically favored sulfinamides, which in turn is a precondition for their successful application as solutions for asymmetric d -synthons [ 13-15,20-32]. On the other hand, if it would be possible to make them rearrange to allylic amines with 1,3-chirality transfer, this would be an interesting entry to this class of compounds (Scheme 6). ... 

An asymmetric variant of this kind of allylic amination, based on their phenylcyclohexanol-derived chiral N-sulfinyl carbamates, was developed by Whitesell et al. (see also Sect. 3.2) (Scheme 34) [85]. After the asymmetric ene reaction with Z-configured olefins (not shown) had occurred, nearly di-astereomerically pure sulfinamides 127 were obtained which were found to be prone to epimerization. Their rapid conversion via O silylation and [2,3]-a rearrangement dehvered the carbamoylated allyhc amines 128 with around 7 1 diastereoselectivity as crystalline compounds that can be recrystallized to enhance their isomeric purity to 95 5. Obviously the imiform absolute configuration at Cl in the ene products 127 was difficult to transfer completely due to the already mentioned ease of epimerization. Unhke the sulfonamides of Delerit (Scheme 33) [84], the carbonyl moiety can easily be cleaved by base treatment. 

Azo-ene reactions. The ene reaction provides a powerful method for C-C bond formation with concomitant activation of an allylic C-H bond. A variety of functionalized carbon skeletons can be constructed due to the range of enophiles which can be used. For example, carbonyl compounds give homoallylic alcohols and imino derivatives of aldehydes afford homoallylic amines. The azo-ene reaction offers a method for effecting allylic amination by treatment of an alkene with an azo-diester to afford a diacyl hydrazine which upon N-N cleavage furnishes a carbamate. Subsequent hydrolysis of the carbamate provides an allylic amine. Use of chiral diazenedicarboxylates provides a method for effecting stereoselective electrophilic amination. 

Titanium-alkyne complexes Ti(Me3SiC=CC6Hi3)(OR)2, as well as the chiral complex derived from chloro-tris[(—)-menthoxo]titanium/2MgClPr1 and alkynes, react with carbonyl compounds to afford optically active allylic alcohols in up to 38% ee (Scheme 127).184 Introduction of two different electrophiles at each of the acetylenic terminal carbon atoms was possible in a regio- and stereoselective manner.45 Similarly, the titanacyclopentene compounds react with imines, metalloimines, or hydrazones under mild conditions to afford allylic amines or their derivatives in good to excellent yields (Scheme 128).258... 

Asymmetric allylic amination of allylic carbonates, prepared from racemic MBH adducts, proceeds in the presence of the Pd catalyst chiral diamino-phosphine oxide (DIAPHOX) (292) and BSA to afford the corresponding chiral aza-MBH adduct derivatives 293 in excellent yield with up to 99% ee. The cyclic reaction products could be converted into various synthetically useful compounds, such as chiral cyclic p-amino acids (Scheme 3.119). ... 

Organophosphine-catalyzed allylic amination of MBH adducts has also been applied for the synthesis of a-alkylidene-(3-amino carbonyl compounds. The first catalytic asymmetric example of this reaction was reported by Krische and coworkers [122] in 2004 (Scheme 11.41), who showed the addition of phthalimide to MBH acetate in the presence of 20mol% of commercially available chiral phosphine catalyst (7 )-Cl-MeO-BlPHEP 54. The reaction was carried out at 50°C however, a long reaction time (62 h) was required. The substitution product was produced in 80% isolated chemical yield and with only 56% of... 

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