1.3- Dienes heteroatom nucleophilic addition

The same transition metal systems which activate alkenes, alkadienes and alkynes to undergo nucleophilic attack by heteroatom nucleophiles also promote the reaction of carbon nucleophiles with these unsaturated compounds, and most of the chemistry in Scheme 1 in Section 3.1.2 of this volume is also applicable in these systems. However two additional problems which seriously limit the synthetic utility of these reactions are encountered with carbon nucleophiles. Most carbanions arc strong reducing agents, while many electrophilic metals such as palladium(II) are readily reduced. Thus, oxidative coupling of the carbanion, with concomitant reduction of the metal, is often encountered when carbon nucleophiles arc studied. In addition, catalytic cycles invariably require reoxidation of the metal used to activate the alkene [usually palladium(II)]. Since carbanions are more readily oxidized than are the metals used, catalysis of alkene, diene and alkyne alkylation has rarely been achieved. Thus, virtually all of the reactions discussed below require stoichiometric quantities of the transition metal, and are practical only when the ease of the transformation or the value of the product overcomes the inherent cost of using large amounts of often expensive transition metals. 

Telomerization is defined as an oligomerization of dienes accompanied by addition of a heteroatom or carbon nucleophilic reagent10. It is catalyzed by various organometallic compounds of transition metals, especially palladium compounds. The nucleophiles, such as water, alcohols, amines or carboxylic acids, as well as enamines, nitroalkanes and stabilized carban-ions, are mainly introduced in the terminal position of the dimeric molecule in excellent yield10. It is also possible to direct the reaction towards an internal product functionalization. Telo-merizations with heteronucleophiles are regarded as heterocarborative addition reactions and are described in Section 1.5.8.4. 

A number of intramolecular Pd-catalyzed 1,4-oxidations of conjugated dienes were developed.f In these reactions, two nucleophiles are added across the diene, one of which adds intramolecularly. So far, only heteroatom nucleophiles have been employed. In order to extend these intramolecular 1,4-oxidations to carbon nucleophiles, it was found that a vinylpalladium species can be obtained in situ from an alkyne via a chloropalladation. The approach is particularly attractive since it involves a Pd(II) chloride salt and could be compatible with the rest of the catalytic cycle. Reaction of dienyne with LiCl, and benzoquinone in the presence of palladium acetate as the catalyst, afforded the carbocyclization products. The reaction resulted in an overall stereoselective fltiri-addition of carbon and chlorine across the diene t B (Scheme 23). 

The addition of various carbon and heteroatom nucleophiles to (bicyclo[5.1.0]-octadienyl)iron cations has been reported. Mostly, the nucleophile attacks at the terminus of the dienyl system to form substituted (bicyclo[5.1.0]octa-2,4-diene)iron complexes. The nucleophile stereoselectively attacks from the rear side of the dienyl system, opposite to the iron atom. The method can be used for the synthesis of cis-2-(2 -carboxycyclopropyl)glycine (CCG-III) (Scheme 4-180). ... 

Five-membered ring systems can be obtained from hetero-l,3-dienes on reaction with oxiranes and thiiranes. To avoid competition from a possible 1,4-addition, the nucleophilic attack of the terminal heteroatom of the diene has to be sterically or electronically hindered by incorporation of the heteroatom into... 

Formation of five-membered ring systems (1,2-addition) can compete with formation of the seven-membered heterocycles (1,4-addition). If the first step of the reaction sequence, namely the nucleophilic attack of the terminal heteroatom of the diene, is hindered by steric or electronic effects, the five-membered ring product is formed exclusively. 

The vast majority of work on asymmetric Diels-Alder reactions deals with additions of 1,3-dienes to a, -alkenic carbonyl derivatives XXI) where the chirophore R is attached to the carbonyl group eiAer directly or via a heteroatom X, permitting subsequent removal of the auxiliary (e.g. by attack of a nucleophile Nu Scheme 75). 

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