Cinnamyl amines

Other radical cyclization approaches to the synthesis of piperidines include a CAN-mediated stereoselective cyclization of epoxypropyl cinnamyl amines <06TL705> and a cyclization of (-trimethylsilylmethylamine radical cation, generated via a photoinduced electron transfer reaction to a tethered -functionality <06JOC8481>. 

The Stille adduct of 2-bromothiophene and l-ethoxy-2-tributyl-n-stannylethene or 1-ethoxy-l-tri-n-butylstannylethene is a masked thienyl aldehyde or a masked ketone, respectively [77-80]. Vinylstannane 93, derived exclusively as the -isomer from hydrostannation of bis(trimethyl-silyl)propargyl amine (92), was coupled with 2-bromothiophene to form ( )-cinnamyl amine 94 upon acidic hydrolysis [81, 82], In another case, stereoisomerically pure phenyl ( )-2-tributylstannyl-2-alkenoate 95, arising from Pd-mediated hydrostannation of phenyl ( )-2-alkynoate, was joined with 2-iodothiophene to deliver the stereodefmed trisubstituted a,p-unsaturated ester 96 [83, 84],... 

Ahlbrecht and coworkers showed that the stereoselective alkylation of Af-cinnamyl (5 )-2-methoxymethylpyrrolidine (STdR), followed by hydrolysis, affords enantiomerically enriched 3-substituted phenylpropionaldehydes, as shown in Scheme 45. This method is analogous to the asymmetric alkylation of S AMP/RAMP hydrazones, as the anions are isoelectronic. The mechanisms of asymmetric induction for the two systems are probably similar. For the lithio cinnamyl amine, methylation can be optimized up to 97.5% ds. Most of the procedures in this paper include potassium tert-butoxide, so the cation in these examples may be potassium. Under these conditions, methyl, primary and secondary alkyl iodides typically afford the products with selectivities in the 90-93% ds range. 

Coupling of organotins with unsaturated halides. Functionalized reagents are widely applicable for the coupling such that a-fluorostyrenes, a-arylacrylic esters, and cinnamyl amines are readily obtained. 

Athyl.cinnamyl.amin 12 II640. N.N-Dimethyl-4-isopropenyl.anilin 12 II650. 

Metbyl-allyl cinnamyl-amin 12 II649. AUyb[d] tetraIyl (2)-amin] IS II663. a-[4 DiinethyIamino[Pg.2347]

Unusual cyclocarbonylation of allylic acetates proceeds in the presence of acetic anhydride and an amine to afford acetates of phenol derivatives. The cinnamyl acetate derivative 408 undergoes carbonylation and Friedel-Crafts-type cyclization to form the a-naphthyl acetate 410 under severe condi-tions[263,264]. The reaction proceeds at 140-170 under 50-70 atm of CO in the presence of acetic anhydride and Et N. Addition of acetic anhydride is essential for the cyclization. The key step seems to be the Friedel-Crafts-type cyclization of an acylpalladium complex as shown by 409. When MeOH is added instead of acetic anhydride, /3,7-unsaturated esters such as 388 are... 

Pd(Ph3P)4, RS02Na, CH2CI2 or THF/MeOH, 70-99% yield. These conditions were shown to be superior to the use of sodium 2-ethylhexanoate. Methallyl, allyl, crotyl, and cinnamyl ethers, the Alloc group, and allyl-amines are all efficiently cleaved by this method. ... 

Iminium ions, generated in aqueous solution from secondary amines and formaldehyde, undergo a Barbier-type allylation mediated by tin, aluminum, and zinc. The reaction is catalyzed by copper and produces tertiary homoallylamines in up to 85% yield.67 The imines generated in situ from 2-pyridinecarboxaldehyde/2-quinolinecarboxaldehyde and aryl amines undergo indium-mediated Barbier allylation in aqueous media to provide homoallylic amines.68 Crotyl and cinnamyl bromides... 

Aryl alcohol oxidase from the ligninolytic fungus Pleurotus eryngii had a strong preference for benzylic and allylic alcohols, showing activity on phenyl-substituted benzyl, cinnamyl, naphthyl and 2,4-hexadien-l-ol [103,104]. Another aryl alcohol oxidase, vanillyl alcohol oxidase (VAO) from the ascomycete Penicillium simplicissimum catalyzed the oxidation of vanillyl alcohol and the demethylation of 4-(methoxymethyl)phenol to vanillin and 4-hydro-xybenzaldehyde. In addition, VAO also catalyzed deamination of vanillyl amine to vanillin, and hydroxylation and dehydrogenation of 4-alkylphenols. For the oxidation of 4-alkylphenol, the ratio between the alcohol and alkene product depended on the length and bulkiness of the alkyl side-chain [105,106]. 4-Ethylphenol and 4-propylphenol, were mainly converted to (R)-l-(4 -hydroxyphenyl) alcohols, whereas medium-chain 4-alkylphenols such as 4-butylphenol were converted to l-(4 -hydroxyphenyl)alkenes. 

The phosphoramidite ligands that are the focus of the remainder of this chapter have prompted the investigation of ligands containing related structures. Iridium complexes of aspartic acid-derived P-chirogenic diaminophosphine oxides (DlAPHOXs) catalyze the amination [62] and alkylation [63] of aUyhc carbonates (Scheme 6). With BSA as base and catalytic amounts of NaPFs as additive, branched amination and alkylation products were obtained from cinnamyl carbonates in excellent yields and enantioselectivities. However, the yields and enantios-electivities were lower for the reactions of alkyl-substituted aUyhc carbonates. Added LiOAc increased the enantioselectivities of aUyhc alkylation products. 

The scope of allylic electrophiles that react with amines was shown to encompass electron-neutral and electron-rich ciimamyl methyl carbonates, as well as furan-2-yl and alkyl-substituted allylic methyl carbonates. An ort/io-substituted cinnamyl carbonate was found to react with lower enantioselectivity, a trend that has been observed in later studies of reactions with other nucleophiles. The electron-poor p-nitrocinnamyl carbonate also reacted, but with reduced enantioselectivity. Allylic amination of dienyl carbonates also occur in some cases with high selectivity for formation of the product with the amino group at the y-position over the s-position of the pentadienyl unit [66]. Arylamines did not react with allylic carbonates under these conditions. However, they have been shown to react in the presence of the metalacyclic iridium-phosphoramidite catalysts that are discussed in Sect. 4. 

In addition to isolating complex 5, Markovic and Hartwig performed kinetic studies on the amination of methyl cinnamyl carbonate with aniline. The proposed mechanism involves reversible dissociation of product, reversible, endothermic oxidative addition of the allylic carbonate to form a 7i-allyliridium species, and irreversible nucleophilic attack on the 7i-allyliridium intermediate, as depicted in... 

Sulfonamides are suitable pronucleophiles, as was first established with N-tosyl-amines [59]. Particularly good results were achieved with L2 as ligand and activa-hon of the catalyst with TBD (Scheme 9.26) for example, the regioselectivity of b/l = 98 2 and an ee-value of98% were obtained in the reaction of LiN(CH2Ph)p-Ts with cinnamyl carbonate. With a substrate containing a sphsubstituent, however,... 

This tethered ferrocenyl-based Pd complex on MCM-41 (17) was then used for the catalytic amination reaction between cinnamyl acetate and benzylamine (40 °C, THF) [59]. In this case, confinement of the catalyst results in profound changes in regio- and enantioselectivity. When the homogeneous equivalent is used to catalyze the reaction, the straight chained derivative is the sole product. Similar results (only 2% of the branched product) were obtained when the catalyst was tethered to the surface of the non-porous silica Cabosil. When tethered inside the pores of MCM-41 a major change occurred in that now the branched product accounts for about 50% and a change in e.e. from 49% e.e. when anchored to the Cabosil support to +99% when anchored inside the MCM-41 pore could be observed. If the catalyst s chirality was reversed in the MCM-41 immobihzed case, so was the chirality of the product (measured at 93% e.e.) [60]. 

Since carbohthiations usually proceed as syn additions, 458 is expected to be formed first. Due to the configurationally labile benzylic centre it epimerizes to the trani-substitu-ted chelate complex epi-45S. The substitution of epi-458 is assumed to occur with inversion at the benzylic centre. Sterically more demanding reagents (t-BuLi) or the well-stabilized benzyllithium do not add. The reaction works with the same efficiency when other complexing cinnamyl derivatives, such as ethers and primary, secondary, or tertiary amines, are used as substrates . A substoichiometric amount (5 mol%) of (—)-sparteine (11) serves equally well. The appropriate (Z)-cinnamyl derivatives give rise to ewf-459, since the opposite enantiotopic face of the double bond is attacked . 

Naftifine Naftifine, (E)-N-methyl-N-(3-phenyl-2-propenyl)-1 -naphthalinmethanamine (35.3.1), is synthesized by alkylating N-methyl-(l-naphthylmethyl)-amine with cinnamyl chloride in the presence of sodium carbonate [38 3]. 

Scheme 22 (a, b) Amination of the enantiopure alcohols 26a and 24a yields racemic cinnamyl and propargyl amides 27a and 25g. (c) Bismuth-catalyzed C-N bond cleavage makes this process reversible... 

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