Allyl bromides Allylic acetates

The most prominent use of ketenes is for [2 + 2] cycloaddition with imine for the construction of /3-lactam skeleton. When the Y group in Scheme 1 is vinyl or aryl group, the deprotonation of the activated a-proton is highly facilitated. In this context, the carbonylation of some allylic derivatives, for example, allyl bromide, allyl acetate, allyl phenyl ether, allyl methyl carbonate, allyl phenyl sulfone, and allyl phosphate, documented to form TT-allylpalladium intermediates is examined. It is interesting to note that only phosphate undergoes the cycloaddition to produce /3-lactam. The characteristic dependency of the stereochemistry on the reaction conditions, being contrary to the results in the usual base-induced cycloaddition is also intriguing. Scheme 2 presents the... 

Numerous applications have been reported. A derivative of the (alkyn-1-yl)nucleosides 295. which have anticancer and antiviral activities, has been synthesized by this reaction. They are also used as chain-terminating nucleosides for DN.A. sequencing[l98,199]. In this reaction, use of DMF as the solvent is most important for successful operation[200]. Only the alkenyl bromide moiety in 2-bromo-3-aceto.xycycloheptene (296) reacts with alkynes without attacking the allylic acetate moiety[201]. 

It is known that tr-allylpalladium acetate is converted into allyl acetate by reductive elimination when it is treated with CO[242,243]. For this reason, the carbonylation of allylic acetates themselves is difficult. The allylic acetate 386 is carbonylated in the presence of NaBr (20-50 mol%) under severe conditions, probably via allylic bromides[244]. However, the carbonylation of 5-phenyl-2,4-pentadienyl acetate (387) was carried out in the presence of EtiN without using NaBr at 100 °C to yield methyl 6-phenyl-3,5-hexadienoate (388)[245J. The dicarbonylation of l,4-diacetoxy-2-butene to form the 3-hexenedioate also proceeds by using tetrabutylphosphonium chloride as a ligand in 49% yield[246]. 

Organoboranes are reactive compounds for cross-coupling[277]. The synthesis of humulene (83) by the intramolecular cross-coupling of allylic bromide with alkenylborane is an example[278]. The reaction of vinyiborane with vinyl-oxirane (425) affords the homoallylic alcohol 426 by 1,2-addition as main products and the allylic alcohol 427 by 1,4-addition as a minor product[279]. Two phenyl groups in sodium tetraphenylborate (428) are used for the coupling with allylic acetate[280] or allyl chloride[33,28l]. 

The allylstannane 474 is prepared by the reaction of allylic acetates or phosphates with tributyltin chloride and Sml2[286,308] or electroreduction[309]. Bu-iSnAlEt2 prepared in situ is used for the preparation of the allylstannane 475. These reactions correspond to inversion of an allyl cation to an allyl anion[3l0. 311], The reaction has been applied to the reductive cyclization of the alkenyl bromide in 476 with the allylic acetate to yield 477[312]. Intramolecular coupling of the allylic acetate in 478 with aryl bromide proceeds using BuiSnAlEti (479) by in situ formation of the allylstannane 480 and its reaction with the aryl bromide via transmetallation. (Another mechanistic possibility is the formation of an arylstannane and its coupling with allylic... 

The structural homology between intermediate 4 and isostrych-nine I (3) is obvious intermediates 3 and 4 are simply allylic isomers and the synthetic problem is now reduced to isomerizing the latter substance into the former. Treatment of 4 with hydrogen bromide in acetic acid at 120°C results in the formation of a mixture of isomeric allylic bromides which is subsequently transformed into isostrychnine I (3) with boiling aqueous sulfuric acid. Following precedent established in 194810 and through the processes outlined in Scheme 8a, isostrychnine I (3) is converted smoothly to strychnine (1) upon treatment with potassium hydroxide in ethanol. Woodward s landmark total synthesis of strychnine (1) is now complete. 

Allyl tosylate is also an excellent reactant (entry 2, Table 5.8), while allyl acetate is not under Cu(I)-catalyzed conditions. Not only saturated acylzirconocene chlorides, but also a,(3-unsaturated acylzirconocene chlorides give coupling products in good yields (entry 8, Table 5.8). Prenyl bromide also reacts with acylzirconocene chlorides under identical conditions to give a mixture of regioisomers (Scheme 5.30). However, a longer reaction time (10 h) is required for the completion of the reaction as compared to the reaction of allyl bromide (1 h). 

One may also resort here to organotransition metal complexes. For example, benzene rings can be selectively activated to nucleophilic attack by complexation to chromium tricarbonyl (Scheme 12.8) [21]. Similarly, an allylic acetate can also be selectively activated in the presence of a bromide (29 versus 3Q) by addition of a palladium(O) catalyst in THF, which coordinates with the double bond [22] (Scheme 12.9). 

The effect of the leaving group was briefly examined, but cinnamyl bromide gave a substantially lower ee (38%). Cinnamyl dimethyl phosphonate, or acetate, gave very poor results. The cyclohexyl-substituted allylic acetate 21, on the other hand, afforded a completely y-selective reaction, but the product turned out to be racemic. Changing the Grignard reagent halide from bromide to either chloride or iodide resulted in very low ees. 

Electroreduction of the cobalt(II) salt in a mixture of either dimethylform-amide-pyridine or acetonitrile-pyridine as solvent, often in the presence of bipyridine, produces a catalytically active cobalt(I) complex which is believed to be cobalt(I) bromide with attached bipyridine ligands (or pyridine moieties in the absence of bipyridine). As quickly as it is electrogenerated, the active catalyst reduces an aryl halide, after which the resulting aryl radical can undergo coupling with an acrylate ester [141], a different aryl halide (to form a biaryl compound) [142], an activated olefin [143], an allylic carbonate [144], an allylic acetate [144, 145], or a... 

The electrochemical allylation of carbonyl compounds by electroreductivc regeneration of a diallyltin reagent from allyl bromide and a Sn species leads to formation of homoallylic alcohols in yields of 70-90 % even in methanol or methanol/water (Table 7, No. 12) Bisaryl formation is possible also from aryl iodides or bromides in the presence of electro-generated Pd phosphane complexes (Table 7, No. 13) In the presence of styrenes, 1,3-butadienes, or phenyl acetylene the products of ArH addition are formed in this way (Table 7, No. 14) . The electroreductivc cleavage of allylic acetates is also possible by catalysis of an Pd°-complex (Table K No. 15)... 

Addition to 1-atkenes (8, 25). The critical steps in a recent synthesis of aldosterone (4) involve anli-Markovnikov addition of C6H5SeBr to I, oxidation to the allylic bromide, and acetate displacement to give 2. The corresponding 21-monoacctate was converted to the triol 3 (0s04, N-mcthylmorpholine N-oxide). The final steps to 4 involved periodate cleavage and saponification.2... 

The concept (see Scheme 15) was introduced by Shue et al.,144-85-861 who used a zinc-induced reductive isomerization of diasteromeric allylic bromides which already contained the R2 side chain. Because of the lack of stereocontrol at the a-carbon, and of difficulties in obtaining the allylic bromide, this method has not been further developed instead, homochiral allylic acetates or mesylates have been used. 

In the presence of bromide, the oxidation of alkenes by Mn(OAc)3 in acetic acid readily occurs it 70-80 °C and produces allylic acetates in good yields. Thus cyclohexene is oxidized to cyclo-lexenyl acetate in 83% yield,508 and a-methylstyrene to j3-phenylallyl acetate in 70% yield,509 vith a mechanism involving allylic hydrogen abstraction by bromine atoms coming from the ixidation of bromide by MniU (equation 206). 

The Tsuji-Trost Reaction (or Trost Allylation) is the palladium-catalyzed allylation of nucleophiles such as active methylenes, enolates, amines and phenols with allylic compounds such as allyl acetates and allyl bromides. 

Carbonylation of allylic acetates. This reaction is effected by catalysis with this and a few other Pd(0) complexes, but requires bromide ion as a cocatalyst. It provides a route to (E)-p,y-unsaturated esters in generally high yield from primary allylic acetates. 

Similar to the conjugate addition, the focus of the last decade has been put on the development of chiral copper catalysts for enantioselective S -substitutions of prochiral substrates.197,197a,197b 271,285 These represent a useful alternative for the preparation of those substitution products which cannot be obtained by anti-stereoselective copper-promoted or -catalyzed SN2 -substitution of chiral substrates (see Section 9.12.2.1.2). The first reported example for such a transformation is the reaction of the allyl acetate 333 with //-butylmagnesium bromide in the presence of 15 mol.% of the copper arenethiolate 334 which gave the substitution product 335 with exclusive y-selectivity and 50% ee (Equation (18)),286 286a... 

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