Allenes intermolecular

The synthesis of unsaturated compounds by C-C bond formation can also be carried out by coupling of alkenes with allenes, intermolecularly or intra-molecularly. Thus, 1,3-dienes were selectively obtained by coupling of allenes and vinyl ketones [28-30]. The reaction was catalyzed by the complex CpRuCl(COD) and with CeCl3 as a cocatalyst (Eq. 19). This cocatalyst is expected to decrease the chloride ion concentration to keep the active cationic ruthenium complex coordinatively unsaturated. 

Intermolecular hydroalkoxylation of 1,1- and 1,3-di-substituted, tri-substituted and tetra-substituted allenes with a range of primary and secondary alcohols, methanol, phenol and propionic acid was catalysed by the system [AuCl(IPr)]/ AgOTf (1 1, 5 mol% each component) at room temperature in toluene, giving excellent conversions to the allylic ethers. Hydroalkoxylation of monosubstituted or trisubstituted allenes led to the selective addition of the alcohol to the less hindered allene terminus and the formation of allylic ethers. A plausible mechanism involves the reaction of the in situ formed cationic (IPr)Au" with the substituted allene to form the tt-allenyl complex 105, which after nucleophilic attack of the alcohol gives the o-alkenyl complex 106, which, in turn, is converted to the product by protonolysis and concomitant regeneration of the cationic active species (IPr)-Au" (Scheme 2.18) [86]. 

The intermolecular hydration of allenes catalysed by [AuCl(lPr)]/AgOTf (1 1,5 mol%) in dioxane/waler at room temperature, has also been studied. In most cases, low to modest yields (25-65%) of fi-aUylic alcohols were obtained by selective addition of the water to the terminal C atom of the aUene group [89]. 

As shown in the preceding examples, although intramolecular Pd-catalyzed poly-cyclization is a well-established procedure, some few examples exist of polycycliza-tions where the first step is an intermolecular process. In this respect, the Pd°-cata-lyzed domino reaction of allenes in the presences of iodobenzene reported by Tanaka and coworkers [40] is an intriguing transformation. As an example the Pd-catalyzed reaction of 6/1-60 in the presence of iodobenzene led to 6/1-61 in 49% yield, allowing the formation of three rings in one sequence (Scheme 6/1.14). 

Organometallic complexes of the /-elements have been reported that will perform both intra-and intermolecular hydroamination reactions of alkenes and alkynes, although these lie outside of the scope of this review.149-155 Early transition metal catalysts are not very common, although a number of organometallic systems exist.156-158 In these and other cases, the intermediacy of a metal imido complex LnM=NR was proposed.159,160 Such a species has recently been isolated (53) and used as a direct catalyst precursor for N-H addition to alkynes and allenes (Scheme 35).161,162... 

Attempts to employ allenes in palladium-catalyzed oxidations have so far given dimeric products via jr al lyI complexes of type 7i62.63. The fact that only very little 1,2-addition product is formed via nucleophilic attack on jral ly I complex 69 indicates that the kinetic chloropalladation intermediate is 70. Although formation of 70 is reversible, it is trapped by the excess of allene present in the catalytic reaction to give dimeric products. The only reported example of a selective intermolecular 1,2-addition to allenes is the carbonylation given in equation 31, which is a stoichiometric oxidation64. 

The intramolecular and intermolecular deuterium isotope effects in the cycloaddition of acrylonitrile to allene (equation 98) have been studied by Dolbier and Dai231,232. The intramolecular KIEs in the allene-acrylonitrile system were found to be 1.21 0.02 at 206°C and 1.14 0.02 at 225°C. A negligible intermolecular SKIE was found in the reaction of the mixture of tetradeuteriated and undeuteriated allene using a limited amount of acrylonitrile (ku/ku) = 1.04 0.05 at 190-210 °C for D0/D4 allene. An equilibrium deuterium IE of 0.92 0.01 was found at 280-287 5°C (15-45 h reaction time). 

Arylative or silylative cyclizations of allenyl aldehydes or ketones have been reported (Equations (101) and (102)).459,459a The intermolecular process, that is, three-component coupling reaction of aldehydes, allenes, and arylboronic acids, is catalyzed by palladium as well (Equation (103)).46O 46Oa These reactions are proposed to proceed through nucleophilic attack of the allylpalladium intermediates to the carbonyl groups. 

Trost et alJ2 also explored the compatibility of di-, tri-, and tetrasubstituted allenes with their intermolecular Alder-ene protocol. Multiple substituents present the opportunity for a mixture of products to arise from differing regio- and chemoselectivity. 1,1-Disubstituted allenes were coupled to methyl vinyl ketone with excellent chemo-selectivity only when one set of /3-hydrogens was activated by an cy-ester or amide (Equation (69)). If the /3-hydrogens were of similar acidity, a mixture of products was obtained, as in the coupling of allenol 103 with methyl vinyl ketone dienes 104 and 105 are produced in a 1.3 1 mixture (Equation (70)). 

In contrast to the intramolecular process, simple allenes do not participate in the intermolecular [5 + 2]-reaction with VCP 18. However, when a second functionality is incorporated into the allene, an efficient and facile cycloaddition occurs, presumably assisted by a directing effect of the secondary functional group. The [5 + 2]-reaction also works with styrenyl- and cyano-substituted allenes as directing groups (Scheme 12). As would be expected from... 

In Section 9.2, intermolecular reactions of titanium—acetylene complexes with acetylenes, allenes, alkenes, and allylic compounds were discussed. This section describes the intramolecular coupling of bis-unsaturated compounds, including dienes, enynes, and diynes, as formulated in Eq. 9.49. As the titanium alkoxide is very inexpensive, the reactions in Eq. 9.49 represent one of the most economical methods for accomplishing the formation of metallacycles of this type [1,2]. Moreover, the titanium alkoxide based method enables several new synthetic transformations that are not viable by conventional metallocene-mediated methods. 

Various intermolecular coupling reactions involving acetylene hydrocarbons have been reported to lead to vinylallenes. For example, 1-phenylpropyne (93), after activation with Hg(II) chloride, is first metalated by butyllithium treatment, then trans-metalated with zinc bromide and finally coupled with 1-iodo-l-phenylethene (94) in the presence of tetrakis(triphenylphosphine)palladium to provide the diphenylvinyl-allene 95 in moderate yield (Scheme 5.12) [31]. 

For the performance of intermolecular reactions of 5, its generation from the sodium salt of tropone tosylhydrazone (517) and from halo-1,3,5-cydoheptatrienes (518) are most suitable, but other precursors can also be employed, as illustrated in Scheme 6.105. In view of the product structures, some reactions of 5 give results that deviate from those of typical allene processes, and this is even valid for the dimerization (Scheme 6.105). 

In this chapter, both intermolecular and intramolecular electrophilic [1] and nucleophilic additions [2, 3] to allenes will be discussed. For electrophilic addition, the regio- and stereoselectivity depend on the steric and electronic effects of the substituents on the allenes and the nature of the electrophiles. However, nucleophilic addition usually occurs at the central carbon atom with very limited exceptions. 

Intermolecular carbon radical additions to allenes proceed regioselectively. The a-addition is favored for propadiene (la), whereas /3-selective additions dominate for... 

Radical cydizations onto allenes are feasible via the dig (addition to C ) or the exotrig mode of ring dosure (addition to QJ. The significance of the a-addition is more pronounced in the case of the intramolecular pathway than in its intermolecular counterpart owing to (i) the chain length between the reacting entities and (ii) the stereoelectronic prerequisites for a radical attack on a Jt-bond [4],... 

The intermolecular PKR of an allenic compound with an alkyne Co2(CO)6 complex takes place under very mild conditions when N-methylmorpholine oxide (NMO) is used as a promoter, giving rise to ( )-4-heptylidene-2,3-dipropyl-2-cyclo-pentenone in 69% yield (Scheme 16.48) [50-53],... 

The key reaction in Jung et al. s proposed assembly of Plaunol B (81a) and C (81b) was an intermolecular Diels-Alder reaction between a diene and an allenic lactone that should give the exo-methylene group in the natural product (Scheme 19.16) [20], The phenyl-substituted lactone 83 was prepared as a model for the eventual furan lactone of the plaunols. Cydoaddition of 82 possessing a TBS enol ether and... 

The Diels-Alder reaction outlined above is a typical example of the way in which axially chiral allenes, accessible through 1,6-addition, can be utilized to generate new stereogenic centers in a selective fashion. This transfer of chirality is also possible by means of intermolecular Diels-Alder reactions of vinylallenes [30], aldol reactions of allenyl enolates [31], and Ireland-Claisen rearrangements of silyl allenylketene acetals [32]. 

Substrates possessing an allene that participate in the Alder-ene reaction are less common, but a few examples are known. Malacria [11] and Livinghouse [12] have independently used cobalt to effect intramolecular allenic Alder-ene reactions but the scope of these reactions was not investigated. Sato has performed an allenic Alder-ene reaction to form five-membered rings, using stoichiometric amounts of titanium [13], and Trost has shown that 1,3-dienes can be prepared via an intermolecular Alder-ene reaction between allenes and enones using a ruthenium(II) catalyst [14]. 

Rhodium catalysis has played a critical role in the development of this type of reaction. The rhodium-mediated [4 + 2] carbocyclization between dienes and unactivated olefins or alkynes is a notable early example of this concept [2]. Further investigations demonstrated the extension of this methodology to the reaction between a diene and an allene [3]. Expansion of the scope of this strategy, to both the intra- and intermolecular [5-1-2] homologs of the Diels-Alder reaction, was accomplished with a vinylcyclopropane and either an alkyne or an olefin to afford the carbocyclization adducts (Scheme 11.1) [4, 5]. 

Recent advances in the rhodium-catalyzed [4-1-2] reactions have led to the development of the first highly regioselective intermolecular cyclization, providing access to new classes of carbocycles with both activated and unactivated substrates. The chemo- and stereoselective carbocyclizations of tethered diene-allene derivatives afford new classes of 5,6- and 6,6-bicyclic systems. Additionally, examination of a wide range of factors that influence both diastereo- and enantioselectivity has provided a significant advance in the understanding of catalyst requirements across these systems. 

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