Allyl amines carbonylation

Allylamines are not easily cleaved with Pd catalysts, but the carbonylation of the allylic amine 395 proceeds at 110 C to give the /3,7-unsaturated amide 396 by using dppp as a ligand[252], Dccarboxylation-carbonylation of allyl diethyl-carbamate under severe conditions (100 C, 80 atm) affords /3,7-unsaturated amides[2531. The 3-vinylaziridine 397 is converted into the a-vinyl-J-lactam 398 under mild conditions[254]. 

Syntheses of primary ally lie amines have been reviewed183. The regiochemistry of the reaction of iron carbonyl complexes with nucleophiles such as morpholine has been investigated. The (r 3-crolyl) Fe+(CO)4 BF4- complexes 172 (R1 = H R2 = Me or R1 = Me R2 = H) undergo preferential attack at the less substituted allyl terminus to yield allylic amines 173. The (/j2-crotyl acetate) Fe(CO)4 complex 174, on the other hand, does not react with morpholine184. 

A wide range of carbon, nitrogen, and oxygen nucleophiles react with allylic esters in the presence of iridium catalysts to form branched allylic substitution products. The bulk of the recent literature on iridium-catalyzed allylic substitution has focused on catalysts derived from [Ir(COD)Cl]2 and phosphoramidite ligands. These complexes catalyze the formation of enantiomerically enriched allylic amines, allylic ethers, and (3-branched y-8 unsaturated carbonyl compounds. The latest generation and most commonly used of these catalysts (Scheme 1) consists of a cyclometalated iridium-phosphoramidite core chelated by 1,5-cyclooctadiene. A fifth coordination site is occupied in catalyst precursors by an additional -phosphoramidite or ethylene. The phosphoramidite that is used to generate the metalacyclic core typically contains one BlNOLate and one bis-arylethylamino group on phosphorus. 

Allylic amine from the three-component reaction of a vinyl boronic acid, a carbonyl and an amine. Also known as boronic acid-Mannich or Petasis boronic acid-Mannich reaction. Cf. Mannich reaction. 

This procedure illustrates a general method for the preparation of rearranged allylic amines from allylic alcohols.2,3 The method is experimentally simple and has been used to prepare a variety of allylic prim-, sec-, and tert-carbonyl amines as illustrated in Table I. The only limitation encountered so far is a competing ionic elimination reaction which becomes important for tri-chloroacetimidic esters of 3-substituted-2-cyclohexen-l-ols.3 4 The rearrangement is formulated as a concerted [3,3]-sigmatropic rearrangement on the basis of its stereo- and regiospecificity3,5 which are... 

Vinyl substitutions on alkenes not having their double bonds conjugated with carbonyl groups often proceed more rapidly and give better product yields when the reactions are conducted in the presence of an unhindered secondary amine. Conjugated and nonconjugated dienes are usually only minor products in these cases. The major products normally are allylic amines obtained by nucleophilic attack of the secondary amine upon the ir-allylpalladium intermediates. Since allylic amines may be quatemized and subjected to the Hoffmann elimination, this is a two-step alternative to the direct vinyl substitution reaction.90... 

Iron complexes can also catalyze allylic amination [31,32]. Enders et al. have demonstrated the nucleophilic addition of various acyclic and cyclic amines to the optically active l-methoxycarbonyl-3-methyl-(T)3-allyl)-tetracarbonyliron cation 49 formed in high yield from reaction of 48 with iron carbonyls. Oxidative removal of the tetracarbonyliron group by reaction with CAN gives 50 with high optical purity and retention of the stereochemistry (Eq. (12)) [31]. The reaction proceeds well for the different amines, and has been used for the synthesis of a compound showing cytotoxic activity against diverse cell lines [31b]. 

Intramolecular condensation of 197 gave 198, which then aromatized to 119. Alternatively, tautomerization of the allylic amine 195 involving the C-6 carbonyl followed by rotation of the C(5)-C(5a) bond and isomerization gave 197 (Scheme 34) <1998JOC1290>. 

ALLYLIC AMINATION Bis(methoxy-carbonyl)sulfur diimide. 

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. 

In the cobalt-catalyzed photochemical carbonylation of olefins, hydroformyla-tion can be performed easily at ambient temperature (and high pressure) with high primary aldehyde selectivities (cf. Section 2.1.1) [59]. Under comparable conditions allylic amines are carbonylated to 2-pyrrolidinone, Al,/V -diallylurea, and A -allyl-3-butenamide [60]. Photochemical methoxycarbonylation of olefins is possible at ambient conditions, i.e., at room temperature and atmospheric pressure [61]. 

The mechanism of the Petasis boronic acid-Mannich reaction is not fully understood. In the first step of the reaction, upon mixing the carbonyl and the amine components, three possible products can form iminium salt A, diamine B, and a-hydroxy amine C. It was shown that preformed iminium salts do not react with boronic acids. This observation suggests that the reaction does not go through intermediate A. Both intermediate B and C can promote the formation of the product. Most likely, the reaction proceeds through intermediate C, where the hydroxyl group attacks the electrophilic boron leading to an ate -complex. Subsequent vinyl transfer provides the allylic amine along with the boronic acid sideproduct. 

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... 

The cycHc urea moiety provides structural rigidity as well as hydrogen-bonding possibihties similar to those of the imidazoles described above. The corresponding 2-imidazolones have been prepared on a soHd phase by tandem aminoacylation of a resin-bound allylic amine with an isocyanate followed by intramolecular Michael addition [73]. However, due to the paucity of data presented on the characterized compounds and the brief experimental procedure, this synthesis is not discussed in detail. Access to cyclic ureas or thioureas has also been obtained by reaction with carbonyl- or thiocarbonyldiimidazole through a cyclo-release mechanism [74—76]. 1,3-Dihydroimidazolones have been obtained by treatment of ureido acetals with TFA and subsequent conversion in an intramolecular cyclization via an N-acyliminium ion [77]. 

The Petasis reaction is a mild multicomponent reaction that allows the conden sation of a boronic acid, an amine, and a carbonyl derivative to generate an allylic amine. Although several diastereoselective Petasis reactions have been reported [106], the first catalytic asymmetric reaction was described in 2008 (Scheme 1.29) [107]. It was shown that the condensation proceeds in high yields and enantiomeric excesses, affording the corresponding protected a vinylglycine derivatives. 

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