Palladium-trimethylenemethane cycloadditions

Catalytic asymmetric Diels-Alder reactions are presented by Hayashi, who takes as the starting point the synthetically useful breakthrough in 1979 by Koga et al. The various chiral Lewis acids which can catalyze the reaction of different dieno-philes are presented. Closely related to the Diels-Alder reaction is the [3-1-2] carbo-cyclic cycloaddition of palladium trimethylenemethane with alkenes, discovered by Trost and Chan. In the second chapter Chan provides some brief background information about this class of cycloaddition reaction, but concentrates primarily on recent advances. The part of the book dealing with carbo-cycloaddition reactions is... 

Recent Advances in Palladium-catalyzed Cycloadditions involving Trimethylenemethane and its Analogs... 

The discovery of palladium trimethylenemethane (TMM) cycloadditions by Trost and Chan over two decades ago constitutes one of the significant advancements in ring-construction methodology [1]. In their seminal work it was shown that in the presence of a palladium(O) catalyst, 2-[(trimethylsilyl)methyl]-2-propen-l-yl acetate (1) generates a TMM-Pd intermediate (2) that serves as the all-carbon 1,3-di-pole. It was further demonstrated that (2) could be efficiently trapped by an electron-deficient olefin to give a methylenecyclopentane via a [3-1-2] cycloaddition (Eq. 1). 

In a variation on the two-component cycloaddition reaction, a [3+3] strategy was reported whereby reaction of enantiomerically pure aziridines, generated from amino acids, with palladium trimethylenemethane complexes leads to a piperidine (Scheme 114). Yields ranged from 63% to 82% and the efficiency of the methodology was demonstrated by the four-step synthesis of (—)-pseudoconhydrin <2001SL1596>. 

As an approach to the synthesis of piperidines with stereocontrol, multiple functionality, and flexibility, the authors employed a [3+3] cycloaddition reaction of a silylpropenyl acetate with aziridines in the presence of a palladium catalyst. The key intermediate is a palladium-trimethylenemethane (Pd-TMM) complex <03JOC4286>. Optically active aziridines gave enantiomerically pure piperidines. 

The success of this carboxylative trimethylenemethane cycloaddition extends to the addition to cyclohexenone. In contrast to the poorly yielding process involving the unsubstituted TMM -Pd complex, a respectable yield of 49 % is obtained here. This is explained by the reduced basicity of the silylated complex, thus leading to fewer side reactions. The reaction is also considered to have a greater degree of concertedness and this becomes apparent in the discussion of chiral Z- and f-olefins in Section 1.6.1.2.3.2. The failure of in situ derived palladium complexes to yield the desired product is attributed to the basic conditions employed which result in double-bond migrations to the endocyclic, conjugated system. 

Palladium-catalyzed cycloaddition is one of the most popular and useful reactions for the construction of a variety of cyclic compounds. The first one was the [3 + 2] cycloaddition of 2-[(trimethylsilyl)methyl]aUyl ester with olefins bearing electron-withdrawing groups reported in 1979 (Scheme and later a large number of cycloaddition reactions were studied, where [3 + 2], [3 + 4], [3 + 6], and [1 + 2] cycloaddition reactions were developed (Scheme 2) and applied to natural product synthesis. Most of these catalytic cycloadditions proceed via a trimethylenemethane palladium (TMM-Pd) intermediate or its analogs, oxatrimethylenemethane palladium (OTMM-Pd) and azatrimethylenemelhane palladium (ATMM-Pd) (Scheme 3). 

Introduction. The development by Trost and co-workers of palladium-trimethylenemethane (TMM) cycloadditions en5)loy-ing the title reagent (1) and related reagents was a seminal advance in ring-construction methodology. The generality and versatility of these reactions is illustrated below by their use in [3 + 2] cycloadditions to form both cyclopentanes and heterocycles, [3 +4] and [3 + 6] cycloadditions, and applications in total synthesis. 

The reactivity of trimethylenemethane complexes has not been studied extensively. There are, however, a number of catalytic reactions, for which the intermediacy of trimethylenemethane complexes is plausible albeit not proved in all cases, stepwise processes might also be considered [33]. The most prominent examples in this context are palladium-catalyzed trimethylenemethane cycloadditions [34,35] in the presence of a phosphane or phosphite, starting from 2-acetoxymethyl-3-allyltrimethsilane (33), which have been explored in great depth by Trost et al. [36, 37]. 33 undergoes [3-1-2]- as well as [3-H4]cyclizations with electron-poor alkenes or dienes such as 34, respectively, leading to 35 and 36 (Scheme 10.13). 

The palladium-catalyzed hetero-[4 + 3]-cycloadditions reported by Trost and Marrs utilize a metal-complexed trimethylenemethane as the three-carbon component. These complexes react with a,/3-unsaturated imines to produce seven-membered heterocycles in moderate to good yields.84 Two examples of this reaction were reported and are shown in Equations (13) and (14). Only the [4 + 3]-reaction was observed with a,/3-unsaturated imine 76 however, both the [4 + 3]- and the [3 + 2]-modes of reactivity are observed with a,/3-unsaturated imine 79. 

The palladium-catalyzed trimethylenemethane reaction with tropanones was reported in 1987 by Trost and Seoane and is the first example of a [6 + 3]-cycloaddition.130 Chromium-mediated [6 + 3]-cycloadditions of two types have been described-one in which the chromium complex activates the six-carbon component and one in which the chromium complex activates the three-atom component. An example of the first type involves the reaction of a cycloheptatriene-Cr(CO)3 complex with azirines to give cyclic imines in moderate yields (Scheme 40).131... 

The [3+2] cycloaddition of trimethylenemethane (TMM) on the unsaturated lactam 288 worked efficiently with the use ofPd[P(0 Pr)3]4 (generated in situ from palladium(n) acetate (20mol%) and triisopropyl phosphite (160mol%)). The reaction proceeded cleanly in refluxing toluene to afford exclusively the desired cycloadduct 290 in 80% isolated yield (Equation 48) <2003TL5033>. 

The addition of the trimethylenemethane-palladium complex to alkenes may proceed by a concerted process or via a stepwise mechanism in which the anion of the 1,3-dipole attacks Michael-fashion to generate an intermediate anion which collapses to form a five-membered ring by attack on the allylpalla-dium complex. This [3 + 2] cycloaddition reaction has been reviewed.128 A number of additional reports of its use have appeared recently.129-134... 

The reaction of methylenecyclopropanes with transition metal complexes is well known to promote a catalytic a-ir cycloaddition reaction with unsaturated compounds, in which a trimethylenemethane complex might exist71-76. Recently, much interest has been focused on the interaction of strained silicon-carbon bonds with transition metal complexes. In particular, the reaction of siliranes with acetylene in the presence of transition metal catalysts was extensively investigated by Seyferth s and Ishikawa s groups77-79. In the course of our studies on alkylidenesilirane, we found that palladium catalyzed reaction of Z-79 and E-79 with unsaturated compounds displayed ring expansion reaction modes that depend on the (Z) and (E) regiochemistry of 79 as well as the... 

The palladium [Pd(Ph3)4]-catalysed 3 + 3-cycloaddition of trimethylenemethane with azomethineimines produced hexahydropyridazine derivatives under mild conditions (40 °C).171 The Lewis acid-catalysed formal oxa-[3 + 3]-cycloaddition of a,f+ unsaturated aldehydes with 6-methyl-4-hydroxy-2-pyrone, 1,3-diketones, and viny-logous silyl esters yielded a variety of pyrones at room temperature.172 Croton-aldehyde has been converted to 6-hydroxy-4-methylcyclohex-l-enecarboxaldehyde by an enantioselective 3 + 3-cycloaddition catalysed by proline. This methodology was used in the synthesis of (—)-isopulegol hydrate, (—)-cubebaol, and (—)-6-hydroxy-4-methylcyclohex-l-ene-1-methanol acetate, an intermediate in the total synthesis of the alkaloid magellanine.173... 

The presence of five-membered rings such as cyclopentanes, cyclopentenes, and dihydrofurans in a wide range of target molecules has led to a variety of methods for their preparation. One of the most successful of these is the use of trimethylenemethane [3 + 2] cycloaddition, catalysed by pal-ladium(O) complexes. The trimethylenemethane unit in these reactions is derived from 2-[ (trimethylsilyl)methyl]-2-propen- 1-yl acetate which is at the same time an allyl silane and an allylic acetate. This makes it a weak nucleophile and an electrophile in the presence of palladium(0). Formation of the palladium 7t-allyl complex is followed by removal of the trimethylsilyl group by nucleophilic attack of the resulting acetate ion, thus producing a zwitterionic palladium complex that can undergo cycloaddition reactions. 

The mode of COj linkage to a methylenccyclopropane involves the intermediate trimethylenemethane, which has also been Implicated in the cycloadditions of mcthylenecyclopropane to alkenes catalyzed by palladium(O). The insertion of COj into this allylic intermediate gives cyclic carboxylate species, which liberate the lactones, as shown in Scheme 11. 

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