Reactions with Cinnamic Esters

Cinnamic acid ethyl ester is a carbonyl compound, which like ben/.ophenone has the ability to accept an electron to form a rather stable anion radical. As tin t. /hunsaturated ester it may produce 1.2- and 

4- addition products in the reaction with alkvl-magnesium halides. The use of /-btiiylmagnesiiiin chloride, however, was found to produce up to 50 7r of a 1,3-addilion product [100). 

The mechanism of this reaction was studied 11011 and was found to involve the production of a r-butyl radical and a magnesium ester hcniikctal radical, which could recombine to form the normal 

The product of addition to cinnamic ester is an obvious abnormal product formed by llte reaction of a Grignard rcagenl. Such products are formed by the reaction ol Iree radicals, which since they tire uncharged kx k for radical stabilization rather titan lor charge stabilization. The following types of abnormal products are considered as being formed by radical recombination even if the direct proof of the radical mechanism has not been given for all eases. 

1) Prod nets resulting from dimerization of the substrate. 

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The reactivity of phenylacetic esters with electron-deficient alkenes is generally fairly poor, even under phase-transfer catalytic conditions. The reaction with cinnamic esters is often accompanied by hydrolysis and the yield of the adduct with chalcone is generally <60% [10]. The activity of the methylene group towards alkylation has been enhanced by the initial complexation of the phenyl ring with chromium tricarbonyl (see Section 6.2), but this procedure has not been applied to the Michael reaction. 

Sulphinylacetic esters are converted in a one-pot reaction into cinnamic esters, when alkylated with benzyl halides [50],... 

Evans and co-workers were the first to report that 4,4 -disubstituted bisoxazolines 29 are excellent chiral ligands for enantioselective aziridination (Scheme 6B.30) [74,75]. Aryl-substi-tuted olefins, especially cinnamate esters, are good substrates for this aziridination. The best reaction conditions, however, vary with the substrates used. For the reactions of cinnamate esters, bisoxazoline 29a and benzene are the ligand and solvent of choice. Under these conditions, enantioselectivity up to 97% ee is observed. For the aziridination of styrene, bisoxazoline 29b and acetonitrile are the appropriate ligand and solvent. 

Cinnamic esters 691 react with aryl halides via a domino Heck reaction-lactonization process in molten //-Iki () c///-B111 hr to yield 4-arylcoumarins (Scheme 170) <2005ASC308>. Likewise, the palladium(n)-cata-lyzed reaction of cinnamic esters with vinyl triflates yields 4-vinyl coumarins <1996SL568>. 

The addition of benzonitrile oxide to acrylic acid gave only the 4-carboxylic acid (441) (59MI41601), while addition to cis- and trans-cinnamic esters gave cis and trans diastereomeric pairs of 4-carboxylic acids (442) (Scheme 100) (59MI41600). Arbisono repeated the experiment and, when methyl c/s-cinnamate was used, in addition to the 4-carboxylic acid some 5-carboxylic acid (442) was isolated (66MI41600). The reaction of vinyl bromides with benzonitrile oxide yielded only an isoxazole and not a bromoisoxazoline (Scheme 101) (78JCR(S)192). 

Recently, Scott et al. have reported that a Cu complex bearing an axially chiral ligand (49) is an excellent catalyst for aziridination of 2,2-dimethylchromene and cinnamate esters (Scheme 36), though it is also less efficient for the reactions of simple olefins.157,158 On the basis of DFT investigation of the nitrenoid intermediate (50), one of the oxygen atoms of the A -sulfonyl group has been proposed to be interacting with the nitrene N-atom.158... 

The Heck reaction on polymer-bound iodoarenes is assisted by the addition of a catalytic amount of tetra-n-butylammonium bromide and has been employed in the synthesis of 4-carboxycinnamic esters and amides [33], and 4-aminosulphonyl-cinnamic esters [34], It has also been reported that the presence of an equimolar equivalent of benzyltriethylammonium chloride aids the Pd(II)-mediated reaction of A -acyl-2-iodoanilines with vinylidene carbonate, which leads to A -acyl-2-hydroxy-indolines providing a convenient route to the indoles (80-90%) [35], The catalysed reaction of 2-hydroxy- and 2-tosylaminoiodobenzene with 1,2-dienes produces 1,2-dihydrobenzofurans and 1,2-dihydroindoles, respectively [36]. 

Heck reactions of arenediazonium salts can be conveniently carried out with [Pd(OAc)2] in ethanol. This method was extended to the one-pot sequential diazotation and allylation of aniUnes (Scheme 6.7). The latter were converted to the corresponding diazonium salts at 0 °C with NaNOa + 42 % HBF4. Ethyl acrylate and [Pd(OAc)2] were added and the reaction mixture was heated on a water bath for 1 h. The corresponding cinnamate esters were obtained in 65-80 % yield [22],... 

Cinnamic alcohol can be dehydrogenated to give cinnamaldehyde and oxidized to give cinnamic acid. Hydrogenation yields 3-phenylpropanol and/or 3-cyclo-hexylpropanol. Reaction with carboxylic acids or carboxylic acid derivatives results in the formation of cinnamyl esters, some of which are used as fragrance materials. 

Accordingly, the synthesis of novel cinnamate polymers with high functionality and performance is very important from the viewpoint of both polymer chemistry and practical use. Recently, we have reported the synthesis of polymers with pendant photosensitive moieties such as cinnamic ester and suitable photosensitizer groups by radical copolymerizations of 2-(cinnamoyloxy) ethyl methacrylate with photosensitizer monomers (9), by copolymerizations of chloromethylated styrene with the photosensitizer monomers followed by the reactions of the copolymers with salts of... 

This article reports on the synthesis of photosensitive polymers with pendant cinnamic ester moieties and suitable photosensitizer groups by cationic copolymerizations of 2-(cinnamoyloxy)ethyl vinyl ether (CEVE) (12) with other vinyl ethers containing photosensitizer groups, and by cationic polymerization of 2-chloroethyl vinyl ether (CVE) followed by substitution reactions of the resulting poly (2-chloroethyl vinyl ether) (PCVE) with salts of photosensitizer compounds and potassium cinnamate using a phase transfer catalyst in an aprotic polar solvent. The photochemical reactivity of the obtained polymers was also investigated. 

Jacobsen and co-workers have reported that chiral diimine 33a serves as an effective chiral auxiliary for the copper-catalyzed aziridination of aryl-substituted Z-olefins (Scheme 6B.35) [80], For example, the aziridination of 6-cyanochromene proceeds with high enantioselectivity (>98% ee). Comparison of ligands 33a-33c has revealed that the o-substituents in the ligands sterically and electronically influence the enantioselectivity of the reaction, that is, the introduction of chlorines at o-positions not only prolongs catalyst lifetime but also enhances enantioselectivity. The reactions of other Z-substrates and cinnamate esters catalyzed by 33a show moderate-to-high enantioselectivity, whereas that of -stilbene gave low enantioselectivity (Table 6B.3). 

The reactions of cinnamic acid derivatives with hydrazine are also in accord (56) with the above findings. The hydrazide 182 cannot, even at 200°C, be converted into the pyrazolone 185 (5-Endo-Trig process). However, the ester... 

This topological rule readily explained the reaction product 211 (>90% stereoselectivity) of open-chain nitroolefins 209 with open-chain enamines 210. Seebach and Golinski have further pointed out that several condensation reactions can also be rationalized by using this approach (a) cyclopropane formation from olefin and carbene, (b) Wittig reaction with aldehydes yielding cis olefins, (c) trans-dialkyl oxirane from alkylidene triphenylarsane and aldehydes, (d) ketenes and cyclopentadiene 2+2-addition, le) (E)-silyl-nitronate and aldehydes, (f) syn and anti-Li and B-enolates of ketones, esters, amides and aldehydes, (g) Z-allylboranes and aldehydes, (h) E-alkyl-borane or E-allylchromium derivatives and aldehydes, (i) enamine from cyclohexanone and cinnamic aldehyde, (j) E-enamines and E-nitroolefins and finally, (k) enamines from cycloalkanones and styryl sulfone. 

A recently published full account of another synthesis [69] of the same alkaloid starting from the /rans-cinnamic ester 264 represented a different approach (ACD -> ACDB) to ( )-lycorine (Scheme 42). An intramolecular Diels-Alder reaction of 264 in o-dichlorobenzene furnished the two diastereomeric lactones 265 (86%) and 266 (5%) involving the endo and exo modes of addition respectively. The transposition of the carbonyl group of 265 to 267 was achieved by reduction with lithium aluminium hydride, followed by treatment of the resulting diol with Fetizon s reagent, which selectively oxidised the less substituted alcohol to give isomeric 5-lactone 267. On exposure to iodine in alkaline medium 267 underwent iodolactonisation to afford the iodo-hydroxy y-lactone 268. The derived tetrahydropyranyl ether... 

An improved one-pot access to a-substituted cinnamate esters (165) exploiting the addition of 1,3-diketones, /3-kclo esters, and malonates to alkynoates (164) catalysed by phosphines has been reported. Among the catalysts, n-BmP was found to be most effective, allowing the reaction to proceed under milder conditions and in a more general manner than with other phosphines.189... 

Compound 85 was dehydrogenated at 300° over palladium black under reduced pressure to a pyridine derivative 96 which was independently synthesized by the following route. Anisaldehyde (86) was treated with iodine monochloride in acetic acid to give the 3-iodo derivative 87. The Ullmann reaction of 87 in the presence of copper bronze afforded biphenyldialdehyde (88). The Knoevenagel condensation with malonic acid yielded the unsaturated diacid 91. The methyl ester (92) was also prepared alternatively by a condensation of 3-iodoanisaldehyde with malonic acid to give the iodo-cinnamic acid (89), followed by the Ullmann reaction of its methyl ester (90). The cinnamic diester was catalytically hydrogenated and reduced with lithium aluminium hydride to the diol 94. Reaction with phosphoryl chloride afforded an amorphous dichloro derivative (95) which was condensed with 2,6-lutidine in liquid ammonia in the presence of potassium amide to yield pyridine the derivative 96 in 27% yield (53). 

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