1,3-Enynes stereoselective

In general, hydroboration—protonolysis is a stereoselective noncatalytic method of cis-hydrogenation providing access to alkanes, alkenes, dienes, and enynes from olefinic and acetylenic precursors (108,212). Procedures for the protonolysis of alkenylboranes containing acid-sensitive functional groups under neutral or basic conditions have been developed (213,214). 

Cyclopenta[fc]dioxanes (44) are accessible from the reaction of the dioxenylmolybdenum carbene complex (43) with enynes <96JOC159>, whilst an intramolecular and stereoselective cyclisation of (Ti5-dienyl)tricarbonyliron(l+) cations affords chiral frans-2,3-disubstituted 1,4-dioxanes <96JOC1914>. 2,3-Dimethylidene-2,3-dihydro-1,4-benzodioxin is a precursor of the 3,8-dioxa-lff-cyclopropa[i]anthracene, which readily dimerises to dihydrotetraoxaheptacene (45) and the analogous heptaphene <96AJC533>. 

AUylzirconium complexes are conveniently obtained by the regio- and stereoselective hydrozirconation of allene [127-133] and can be, for example, used subsequently for the MAO-catalyzed allylzirconation of alkynes to prepare enyne derivatives [132]. Alternatively, the preparation of (E)-l,3-dienes from aldehydes and the appropriate allylstannane zirconocene derivative (R = SnBu,) is accomplished (Scheme 8-17) [131], Note that addition of [Cp2Zr(H)Cl[n (1) on the aUenyl reagent with the... 

A hydroboration-protonolysis procedure for the conversion of conjugated enynes to dienes is far superior to partial hydrogenation over Lindlar s catalyst, in terms of stereoselectivity and yields280. Ratovelomanana and Linstrumelle reported the synthesis of methyl a-eleostearate (equation 163) and methyl punicate by employing this strategy280. 

A characteristic feature of contemporary investigations in the held under consideration, is the interest in cycloaddition reactions of nitrile oxides with acetylenes in which properties of the C=C bond are modified by complex formation or by an adjacent metal or metalloid atom. The use of such compounds offers promising synthetic results. In particular, unlike the frequently unselec-tive reactions of 1,3-enynes with 1,3-dipoles, nitrile oxides add chemo-, regio-and stereoselectively to the free double bond of (l,3-enyne)Co2(CO)6 complexes to provide 5-alkynyl-2-oxazoline derivatives in moderate to excellent yield. For example, enyne 215 reacts with in situ generated PhCNO to give 80% yield of isoxazoline 216 (372). 

When the TMS group is absent and if the reaction is carried out in methanol, a platinum(ll)-catalyzed alkoxycy-clization takes place (Scheme 87).308 This cyclization catalyzed by Pt(ll) was found to be mechanistically similar to the carbohydroxypalladation reported by Genet.309 310 This process has intrinsic importance in organic synthesis since it allows the simultaneous and generally stereoselective formation of a C-O and a C-C bond to occur from an enyne system. This reaction has been applied for the synthesis of a key intermediate of podophyllotoxin.311... 

The intermolecular ruthenium enyne Alder-ene reaction has been extended to the stereoselective preparation of enamines (Equation (26)).39 The yields obtained for this reaction were high with allylacetamides, -benzamides,... 

Kibayashi and co-workers103 implemented the palladium-catalyzed cycloisomerization reaction in a stereoselective total synthesis of enantiomerically pure (+)-streptazolin. The cycloisomerization of enyne 172 to provide diene 173 was remarkably selective when performed in the presence of A,Ar -bis(benzylidene)ethylenediamine (BBEDA) as a ligand and water as a proton source (Scheme 44). 

Undheim [24] described the stereoselective synthesis of cyclic 1-amino-l-carboxylic acid using ruthenium-catalyzed enyne metathesis. His plan is shown... 

Introduction of a double bond between the triple bond and the leaving group leads to enyne electrophiles 45, which would give access to vinylallenes 46 if the attack of the nucleophile takes place at the triple bond in an SN2" (1,5) substitution reaction (Scheme 2.16). In addition to the regioselectivity, two types of stereoselectivity also have to be considered in this transformation, i.e. the configuration of the olefinic double bond of the vinylallene and the (relative or absolute) configuration of the allenic chirality axis. 

Although the resulting vinylallenes 48 were usually obtained as mixtures of the E and Z isomers, complete stereoselection with regard to the vinylic double bond was achieved in some cases. In addition to enyne acetates, the corresponding oxiranes (e.g. 49) also participate in the 1,5-substitution (Scheme 2.18) and are transformed into synthetically interesting hydroxy-substituted vinylallenes (e.g. 50) [42], Moreover, these transformations can also be conducted under copper catalysis by simultaneous addition of the organolithium compound and the substrate to catalytic amounts of the cuprate (see Section 3.2.3). 

Initial attempts to perform the 1,5-substitution enantioselectively with chiral enyne acetates proceeded disappointingly. For example, treatment of the enantio-merically pure substrate 51 with the cyano-Gilman cuprate tBu2CuLi LiCN at -90 °C provided vinylallene 52 as a 1 3 mixture of E and Z isomers with 20 and 74% ee, respectively (Scheme 2.19) [28], As previously described for the corresponding Sn2 substitution of propargylic electrophiles, this unsatisfactory stereoselection may be attributed to a racemization of the allene by the cuprate or other organome-... 

The transition metal cross-couplings of allenes described here offer practical solutions for the modification of 1,2-dienes and access to the preparation of highly functionalized 1,3-dienes, alkynes and alkenes, which are often not easily accessible in a regio- and stereoselective manner by classical methods. Some of the prepared alkynes or functionalized allenes serve as important intermediates in syntheses of natural products, biologically active compounds, e.g. enynes and enyne-allenes, and new materials. It can be predicted that further synthetic efforts will surely be focused on new applications of allenes in transition metal-catalyzed cross-coupling reactions. 

Panacene (61) is a metabolite of the sea hare Aplysia brasiliana and acts as a fish antifeedent [61]. The synthesis of the racemic natural product, published by Feldman et al. [77] in 1982, takes advantage of the anti-selective SN2 -substitution of the propargylic mesylate 67 with LiCuBr2 (Scheme 18.21). In contrast, the later attempted biomimetic synthesis by treatment of the enyne 68 with NBS or 2,4,4,6-tetrabromocyclohexadienone did not proceed stereoselectively and led to a 1 1 mixture of the target molecule 61 together with its allenic epimer [78]. 

As in the case of addition reactions of carbon nucleophiles to activated dienes (Section HA), organocopper compounds are the reagents of choice for regio- and stereoselective Michael additions to acceptor-substituted enynes. Substrates bearing an acceptor-substituted triple bond besides one or more conjugated double bonds react with organocuprates under 1,4-addition exclusively (equation 51)138-140 1,6-addition reactions which would provide allenes after electrophilic capture were not observed (cf. Section IV). 

The regio- and stereoselective dimerization of terminal alkynes into disubstituted enynes is efficiently catalyzed by rare-earth metal alkyl and hydride complexes, as reported independently by Bercaw et al. and Teuben et al. in 1987 [211,212]. Takaki and coworkers have shown that complexes Ln[N(SiMe3)2]3 when combined with an amine additive (typically, ArNH2 compounds) afford an active species for the... 

Initial attempts at carbocydization of the enyne 82 with Wilkinson s catalyst under an atmosphere of 1,3-butadiene in refluxing toluene furnished only trace amounts of product, which was attributed to the preference for the enyne to undergo homodimerization in a highly stereoselective manner (Tab. 12.8, entry 1 ds 19 1) [38]. Nonetheless, the coordinatively unsaturated (AgOTf-modified) catalyst furnished the [4-i-2-1-2] product in excellent yield (entry 2). The ability to alter the product distribution in this manner prompted further examination of various other silver salts. 

Evans and co-workers were also successful in extending this methodology to the diastereoselective rhodium-catalyzed [4-1-2-i-2] reaction, which probed the influence of a C2-substituted tethered enyne (Eq. 15). Treatment of the substituted enyne 90, under optimized conditions, furnished the 5,8-bicycHc product 91 in a highly efficient and diastereoselective manner. The observed stereoselectivity is in strong agreement with the selective formation of a single metallacycle intermediate as originally outlined. 

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