Allenes exocyclic

Conjugated terminal fluoroenynes add water to the double bond at -5 C to form a-fluoro allemc acid fluondes. At 20 C, the allenic acid fluorides and concentrated sulfunc acid give y- and 8-laaones (equation 1) In the presence of concentrated sulfuric acid, conjugated nontermmal fluoroenynes add water to the triple bond and then to the double bond to form a-fl uoro-P-diketones and exocyclic a-fluoroenones [/] (equation 2). 

This method provides a convenient synthesis of alkenes with the double bond in a relatively unstable position. Thus reduction of the p-toluenesulfonylhydrazones of a,(3-unsaturated aryl ketones and conjugated dienones gives rise to nonconjugated olefins. Unsaturated ketones with endocyclic double bonds produce olefins with double bonds in the exocyclic position. The reduction of p-toluenesulfonylhydrazones of conjugated alkynones furnishes a simple synthesis of 1,3-disubstituted allenes. ... 

Vinylphosphonium salts are reactive as dienophiles as a result of the EWG character of the phosphonium substituent. The D-A adducts can be deprotonated to give ylides that undergo the Wittig reaction to introduce an exocyclic double bond. This sequence of reactions corresponds to a D-A reaction employing allene as the dienophile.71... 

Since cumulenes and alkynes are often easily interconvertible, many syntheses discussed above have allenic counterparts, especially base-catalyzed cyclizations of allenic alcohols.77 And, of course, several of the alkyne-based syntheses may well have allenic intermediates. There are, however, a few syntheses based specifically upon allene chemistry. In an important one, due to Stirling and his collaborators,78 an allenic sulfonium salt reacts with an enolate anion. Scheme 12 sketches the main features yields as high as 86% are recorded. Methoxyallene is easily metallated by butyllithium and so converted into an allenic epoxide that can be isomerized by fe/T-butoxide into a furan (Scheme 13) or an exocyclic equivalent similar to 15 clearly this method is particularly suited to the preparation of 3-methoxyfuran... 

If the alkenes and acetylenes that are subjected to the reaction mediated by 1 have a leaving group at an appropriate position, as already described in Eq. 9.16, the resulting titanacycles undergo an elimination (path A) as shown in Eq. 9.58 [36], As the resulting vinyltitaniums can be trapped by electrophiles such as aldehydes, this reaction can be viewed as an alternative to stoichiometric metallo-ene reactions via allylic lithium, magnesium, or zinc complexes (path B). Preparations of optically active N-heterocycles [103], which enabled the synthesis of (—)-a-kainic acid (Eq. 9.59) [104,105], of cross-conjugated trienes useful for the diene-transmissive Diels—Alder reaction [106], and of exocyclic bis(allene)s and cyclobutene derivatives [107] have all been reported based on this method. 

Scheme 2.3S Formation of exocyclic allenes 103 by intra-molecular SN2 substitution of organolithium compounds.

Dipolar cycloadditions to electron-deficient allenes are not regioselective, taking place at the electron-poor C=C bond, in all cases. For example, the reaction of 372 with nitrile oxide 378 furnishes a mixture of products 379-383 [356], Obviously, 379, 380 and 381 result from different [2 + 3]-cycloadditions followed by tautomer-ism, whereas 382 and 383 are formed from the primary products of the 1,3-dipolar cydoaddition via addition of a second equivalent of 378 to the remaining exocyclic C—C bond. 

The addition of allenyl ether-derived anions to Weinreb [4] or to morpholino amides [5] follows a slightly different pathway (Eq. 13.2). For example, the addition of lithioallene 6 to Weinreb amide 7 at -78 °C, followed by quenching the reaction with aqueous NaH2P04 and allowing the mixture to warm to room temperature leads to cyclopentenone 9 in 80% yield [6]. The presumed intermediate of this reaction, allenyl vinyl ketone 8, was not isolated, as it underwent cyclization to 9 spontaneously [7]. These are exceptionally mild conditions for a Nazarov reaction and are probably a reflection of the strain that is present in the allene function, and also the low barrier for approach of the sp and sp2 carbon atoms. What is also noteworthy is the marked kinetic preference for the formation of the Z-isomer of the exocyclic double bond in 9. Had the Nazarov cyclization of 8 been conducted with catalysis by strong acid, it is unlikely that the kinetic product would have been observed. 

The oxidative cyclization of vinylallenes need not be directed by a pendant hydroxyl group in order to succeed. The higher reactivity of the allene compared with the exocyclic methylene group in 73 (Eq. 13.23) with monoperphthalic acid leads primarily to the allene oxide which rearranges to cydopentenone 74 [27]. Inevitably some epoxidation of the alkene also takes place during the reaction. When m-CPBA is used as the oxidant, another side reaction is associated with m-chlorobenzoic add-mediated decomposition of the intermediate epoxide. It is possible to overcome this problem by performing the epoxidation in dichloromethane in a two-phase system with aqueous bicarbonate so as to buffer the add [28]. 

Activation of one the double bonds of the allene by coordination to an electrophilic metal center such as Hg(II), Ag(I), Pd(II), Rh(I), Cu(I) or Au(III). Then an intramolecular nucleophile can attack and the product is formed by protodemetallation of the intermediate (Scheme 15.1). Depending on electronic and steric factors, either the proximal or the distal Jt-bond of the allene 1 is activated in that way (2 and/or 3). For each of these two possibilities now an exo or endo attack of the nucleophile is conceivable, leading to intermediates 4—7. An equilibrium between both 5 and 6 and 9 is possible. Finally, from 4 the vinyl-substituted 8 is formed. From 5, 6 or 9 the exocyclic alkene 10 and/or the endocyclic alkene 11 can be observed. Compound 7 would deliver the endocyclic alkene 12. 

A rhodium-catalyzed allenic Alder ene reaction effectively provides cross-conjugated trienes in very good yields (Scheme 16.70) [77]. The reaction most likely involves ft -hydride elimination of an intermediate rhodium metallacycle to afford an appending olefin and ensuing reductive elimination of a metallohydride species to give the exocyclic olefin. 

Among allenic natural products, bromoallenes form the most recently discovered group the first example, panacene (61), was isolated in 1977 [61] but comprise already more than 30 members [5, 14]. These are mainly C15-dioxabicyclic compounds with an exocyclic bromoallene moiety [62], which were isolated from red algae or molluscs (Scheme 18.20). 

A diastereoselective synthesis of the racemic vinylallene 96 was described by Gordon and Tabacchi [96] in 1992 (Scheme 18.31). Here, the exocyclic allene was formed via anti-SN2 -substitution of the propargylic sulfmate 98 with lithium diisopropenyl-cyanocuprate, which, however, was also found to undergo side reactions such as reduction and direct attack of the nucleophile at the sulfmate. Deprotection of the substitution product 99 (which was obtained with only 35% yield) finally provided the desired target molecule 96. 

Results of investigations on the biosynthesis of neoxanthin (30) and peridinin (6) from 3H- and I4C-labeled mevanolate by the alga Amphidinium carterae are not in accordance with the formation of the exocyclic allene from an alkyne I. E. Swift, B. V. Milborrow, Biochem.J. 1981, 299, 69-74. 

TABLE 1. H chemical shifts and coupling constants of linear and cyclic dines, exocyclic methylenes and allenes... 

Spino and colleagues134 studied the Diels-Alder reactions of vinylallenes aiming to synthesize six-membered rings with a tetrasubstituted exocyclic double bond, which were to be employed as precursors of quassinoids. Some representative results of their investigations have been summarized in Table 5 (equation 56). Due to the presence of two different substituents at the allene terminus of 200, facial differentiation occurred, which resulted in non-equivalent amounts of geometrical isomers 201 and 202. The major isomers obtained in each case were formed by endo attack of maleic anhydride 144 at the less hindered face of the diene. 

The reaction of o-halobenzenesulfonamide 256 with allene 257, in the presence of Pd(0), affords the exocyclic alkene 258 via nitrogen attack on the 7t-allyl Pd-intermediate 259 (Scheme 35) <2001EJ0707>. The related cyclopropane product 260, formed in high yields in the analogous reactions of carboxamides, is not observed for the sulfonamide substrate 256. 

Polyene cyclization in terpene and steroid synthesis is critically dependent on the terminator in order to generate useful functionalities for further modification of the products. Allyl- and propargylsilanes have proven their value in facilitation of the cyclization and generation of an exocyclic methylene and allene, respectively. Thus, a concise approach to albicanyl acetate [126] and the rapid construction of a tetracyclic precursor of steroids [127] are sufficient to demonstrate the concept. Again, a comparison of the substrates with a silyl group with those having a simple alkyl moiety is very enlightening. 

Allene ketene cycloadditions are of greater synthetic utility than cither mixed allene dimerization or mixed ketene dimerization. In this class of reaction the ketene is the more reactive species and homodimerization of ketene can be minimized by use of excess allene. Such cycloadditions always result in 2-alkylidenecyclobutanones with the sp carbons of both moieties forming the initial bond. In substituted allenes and ketenes, mixtures of stereoisomers of 2-alkylidenecyclobutanones are obtained with very little stereoselectivity, the stereoisomers arise from cisUrcins isomerism in the cyclobutane ring and EjZ isomerism of the exocyclic double bond. In unsymmetrically substituted allenes some regiochemical preference for ketene cycloaddition is observed. Examples of dimethylketene allene cycloadditions are summarized in Table 1,2... 

The addition of allene and a secondary amine to O-propargyl-2-iodophenol led to the sequential intramolecular insertion of the acetylene bond, followed by the intermolecular insertion of allene and finally the capture of the formed allylpalladium complex by the secondary amine to give benzofurane analogues bearing an exocyclic diene system (3.31.). 

Cumulated Alkenes A cumulated double-bond system, as occurs in the allenes C=C=CH2j, absorbs near 2000-1900 cm-1. The absorption results from asymmetric C=C=C stretching. The absorption may be considered an extreme case of exocyclic C=C absorption. 

Allenes react with carbenes to give cyclopropanes with exocyclic unsaturation 1028... 

The propargylsilane group can participate in intramolecular cyclization reactions to give a five-membered ring with an exocyclic allene group. An example is the cyclization of 2 to a mixture of 3 and 4 when treated with acetic acid. 1... 

In constrast with intermolecular nitrone cycloadditions to alkynes and allenes, very little work has been done on the corresponding intramolecular cycloadditions. The bicyclic isoxazolidines (65a-b) were reported as products from reaction of an alkynone with methylhydroxylamine in ethanol.26b Presumably the initial strained bridgehead C—C double bond of the AMsoxazoline added ethanol under the reaction conditions. Cyclization of an allenyl ketone with methylhydroxylamine in ethanol solution also led to isoxazolidines (65a-b) as the major products and isoxazolidine (66) as a minor product.266 Thus, preferential cyclization to the internal C—-C double bond of the allene occurred followed by addition of ethanol to the exocyclic C—C double bond of the methyleneisoxazolidine intermediate. 

The formation of fused strained tricycles 73 and 75 can be rationalized by a mechanism which includes an exocyclic diradical intermediate 78 through an initial carbon-carbon bond formation, involving the central allene carbon and the proximal alkene carbon atom (path A, Scheme 27). An alternative mechanism for the... 

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