Tandem intramolecular intermolecular

Extension of the linkage to hve atoms as in 285 provides routes to pyrazolines or pyrazoles 286, or 1,2,4-triazoles 287, fused to a seven-membered ring. The products are potentially biologically active and examples have been reported for X=N (177-181), X = 0 (181-185) and for a pyrazolo fused analogue (186) and X = S (187). In some cases, [e.g., (183)], these reactions are accompanied by tandem intramolecular-intermolecular reactions leading to the formation of macrocycles (see the section Tandem Intermolecular-Intramolecular Cycloaddition Reactions). 

In the prostaglandin synthesis shown, silyl enol ether 216, after transmetaJ-lation with Pd(II), undergoes tandem intramolecular and intermolecular alkene insertions to yield 217[205], It should be noted that a different mechanism (palladation of the alkene, rather than palladium enolate formation) has been proposed for this reaction, because the corresponding alkyl enol ethers, instead of the silyl ethers, undergo a similar cyclization[20I],... 

Alkinyloxy)diazoacetic esters 11 give rise to product mixtures that could be separated only partially. The isolated products result from a tandem intramolecular cyclopropenation/cyclopropene —> vinylcarbene isomerization (12, 14) and from a twofold intermolecular (3+2)-cycloaddition of the intact diazo compound (13). 

Chang et al. reported a mild tandem intramolecular hydroamination of yne amines to form an endo-adduct intermediate, which reacts with electron-deficient azides to produce cyclic amidines <06JA12366>. Selected examples of an interesting synthetic route to tropene derivatives 165 via a dual hydroamination strategy is shown below. This one-step reaction makes use of a palladium catalyst and takes place by sequential intermolecular hydroamination of cycloheptatriene with aryl, heteroaryl, and primary alkyl amines to generate intermediate 166, followed by transannular intramolecular hydroamination <06JA8134>. 

Z-tamoxifen 403 tandem cyclization 290, 295 tandem Heck reaction-anion capture 253-4 tandem Heck reaction-phenoxide capture 253 tandem Heck reactions 251, 252-4 tandem intramolecular Heck-intermolecular Stille cross-coupling 255 taxol 140, 143,243,245 ( )-tazettine 146,234 telomerization 352 telomerization products 343, 345 template effect 140 teraconic anhydride 468 terminal acetylenes, synthesis of 216-20 terminal alkynes 6, 213 terminal 2,2-diorgano-l-aIkcnylboronates 51 terminal diynes 207 ternary complex 444 ternary coupling 177... 

Scheme 6-28 Tandem intramolecular Heck-intermolecular Stille cross couplings.

Mechanistic investigations showed, that a sequence of tandem intramolecular Buchwald-Hartwig amination and intermolecular Suzuki-Miyaura coupHng is likely to occur as dominant process (for system 103 with simpHfied formulations for oxidative... 

SCHEME 16.76 Tandem intramolecular-[4 + 2]/intermolecular-[3 + 2] cycloadditions of allene-containing nitroalkenes. 

By definition, a diene contains two carbon-carbon double bonds each potentially can be a 2ti-component in a cycloaddition reaction. A [4 + 2] cycloaddition of a 1,3,4-oxadia-zole with a diene can proceed via one or both of two routes. In the first case, only one of the carbon-carbon double bonds from separate molecules reacts in each step, leading to a tandem, double intermolecular cycloaddition. This reaction is not much different from similar reactions with two molecules of an alkene described previously. However, in the second case, the carbon-carbon double bond remaining from the diene after the [4 + 2] cycloaddition step reacts in the [3 + 2] cycloaddition intramolecularly, which leads to a tandem, intermolecular-[4 + 2]/intramolecular-[3 + 2] cycloaddition. 

Chapter 10 considers the role of reactive intermediates—carbocations, carbenes, and radicals—in synthesis. The carbocation reactions covered include the carbonyl-ene reaction, polyolefin cyclization, and carbocation rearrangements. In the carbene section, addition (cyclopropanation) and insertion reactions are emphasized. Recent development of catalysts that provide both selectivity and enantioselectivity are discussed, and both intermolecular and intramolecular (cyclization) addition reactions of radicals are dealt with. The use of atom transfer steps and tandem sequences in synthesis is also illustrated. 

A tandem radical addition/cyclization process has been described for the formation of benzindolizidine systems from l-(2-iodoethyl)indoles and methyl acrylate <00TL10181>. In this process, sun-lamp irradiation of a solution of the l-(2-iodoethyl)ethylindoles 149 in refluxing benzene containing hexamethylditin and methyl acrylate effects intermolecular radical addition to the activated double bond leading to the stabilized radical 150. Intramolecular cyclization to the C-2 position of the indole nucleus then affords the benzindolzidine derivatives 151 after rearomatization of the tricyclic radical. 

Grubbs has reported a similar tandem olefin metathesis-carbonyl olelination process for the preparation of cyclic olefins [31]. In this case, treatment of a keto-olefin with the molybdenum alkylidene 1 at 20°C generates an intermediate alkylidene complex. Under these conditions, competing intermolecular olelination does not occur. However, intramolecular carbonyl olelination of the initially formed alkylidene complex can occur and this results in the formation of a cyclic olefin. This tandem sequence is illustrated by the transformation of keto-olefins... 

In each of the tandem iminium ion/enamine cascade processes described above, the enamine is trapped in an intramolecular fashion. The ability to perform the trapping seQuence in an intermolecular manner would allow for the one—pot introduction of three points of diversity. IVIacNlillan has realised this goal and described a series of secondary amine catalysed conjugate addition—enamine trapping sequences with oc P Unsaturated aldehydes using tryptophan derived imidazolidinone 115 to give the products in near perfect enantiomeric excess (Scheme 47) [178]. 

Silver carbonate, when used as the base in the dehydrochlorination of hydrazonyl chlorides, has a unique effect in enhancing yields and favoring particular modes of reaction, for example, in the promotion of the tandem intermolecular-intramolecular synthesis of macrocycles 302 discussed in Section 7.3.2.4 (73). Such differences have led to some investigations into the mechanism of its reaction. In this work (74), the hydrazonyl chloride 134 was reacted with 2 M equiv of silver carbonate in the presence of various allylic alcohols. 

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