Terminal alkynes, cycloaddition

Terminal alkynes with no electron-withdrawing group next to the acetylenic linkage when treated with enamines merely add across the double bonds of the enamines (9i). But electrophilic alkynes (those with an electron-withdrawing group next to the acetylenic linkage) undergo cycloaddition reactions with enamines. 

Normally, copper-catalysed Huisgen cycloadditions work with terminal alkynes only. The formation of a Cu-acetylide complex is considered to be the starting point of the catalyst cycle. However, the NHC-Cu complex 18 was able to catalyse the [3-1-2] cycloaddition of azides 17 and 3-hexyne 23 (Scheme 5.6). 

The benzoquinone 66 is similarly prepared by the regioselective cycloaddition of 64, derived from 63. The cyclization reaction is based on the electronic effect of the substituent of 65 [34]. The maleoylcobalt complex 67, substituted by PPh3, is unreactive towards terminal alkynes. The reaction course is altered... 

V. V. Rostovtsev, L. G. Green, V. V. Fokin, and K. B. Sharpless, A stepwise Huisgen cycloaddition process Copper(I)-catalysed regioselective ligation of azides and terminal alkynes, Angew. Chem. Int. Ed., 41 (2002) 2596-2599. 

Figure 17.3 Maleimide-modified glass slides (1) can be derivatized using two chemoselective ligation reactions to create biotin modifications. In the first step, alkyne-PEG4-cyclopentadiene linkers (2) are added to the maleimide groups using a Diels-Alder reaction. In the second reaction, an azido-PEG4-biotin compound (3) is reacted with the terminal alkyne on the slide using click chemistry to result in another cycloaddition product, a triazole ring.

Torn0e, C.W., Christensen, C., and Meldal, M. (2002) Peptidotriazoles on solid phase [l,2,3]-triazoles by regiospecific copper) I)-catalyzed 1,3-dipolar cycloadditions of terminal alkynes to azides. J. Org. Chem. 67, 3057-3064. 

Disubstituted 1,2,3-triazoles are exclusive products of copper catalyzed 1,3-dipolar cycloadditions of terminal alkynes to azides. A variety of substituents can be introduced in this way. Many examples of such reactions are discussed in Section 5.01.9. 

The cycloaddition-isomerization procedure can be accomplished in the presence of a catalytic amount of a transition metal salt. The reactions proceed at room temperature, neither air nor water needed to be excluded. The presence of an electron-withdrawing group is not necessary to activate the dienophile as the example below shows that gold coordination increases the electrophilicity of the triple bond. The presence of a terminal alkyne should also be important. In the case of a disubstituted alkyne no reaction can be observed <00JA11553>. 

Although disubstituted alkynes are used successfully as two-carbon components in chromium-mediated and -catalyzed [6 + 2]-reactions, the use of terminal alkynes produces a [6 + 2 + 2]-reaction (Section 10.13.3.7). Buono and co-workers have discovered that when a cobalt catalyst is employed, several monosubstituted alkynes can be used in [6 + 2]-cycloadditions with cycloheptatriene (Scheme 35). The use of a chiral BINOL-phosphoramidite cobalt complex affords an enantioselective [6 + 2]-cycloaddition reaction (Equation (18)).121... 

During the course of their studies on the chromium-mediated [6 + 2]- and [6 + 2 + 2]-reactions, the Rigby group uncovered a new four-component [6 + 2 + 2 + 2]-cycloaddition.167 When the two terminal alkynes are connected by three methylene units, an anticipated [6 + 2 + 2]-cycloaddition occurs in a moderate yield. Surprisingly, when the alkynes are tethered by four or five methylenes, a third alkyne is incorporated in an overall [6 + 2 + 2 + 2]-process (Scheme 71). The authors propose that the [6 + 2 + 2 + 2]-cycloaddition products arise from a [3 + 2] reaction of an alkyne with the initially formed [6 + 2 + 2]-reaction products (Scheme 72). These reactions greatly increase structural complexity by stereoselec-tively converting four achiral components to a pentacyclic product with six contiguous stereocenters. 

Scheme 16.81 Rh-catalyzed [4 + 2]-cycloaddition of a vinyl allene and a terminal alkyne.

CuO Nanostructures of Variable Shapes as an Efficient Catalyst for [3+2] Cycloaddition of Azides with Terminal Alkyne... 

Terminal alkynes readily react with coordinatively unsaturated transition metal complexes to yield vinylidene complexes. If the vinylidene complex is sufficiently electrophilic, nucleophiles such as amides, alcohols or water can add to the a-carbon atom to yield heteroatom-substituted carbene complexes (Figure 2.10) [129 -135]. If the nucleophile is bound to the alkyne, intramolecular addition to the intermediate vinylidene will lead to the formation of heterocyclic carbene complexes [136-141]. Vinylidene complexes can further undergo [2 -i- 2] cycloadditions with imines, forming azetidin-2-ylidene complexes [142,143]. Cycloaddition to azines leads to the formation of pyrazolidin-3-ylidene complexes [143] (Table 2.7). 

A cycloaddition process between the Rh=C bond of the allenylidene derivative 38 and the C=C bond of the terminal alkyne has been evoked in the formation of the zwitterionic 71-aUyl-allenyl complexes 81 (Scheme 28), the initially formed metaUacyclobutenes 80 evolving into 81 by formation of carbene intermediate [RhCl(P/-Pr3)2(=CHCR=C=C=CPh2)] (R = Ph, p-MeC6H4, SiMe3) and subsequent migration of one of the phosphine ligands from the metal to the carbene carbon atom [205]. 

Aryl acetylenes undergo dimerization to give 1-aryl naphthalenes at 180 °C in the presence of ruthenium and rhodium porphyrin complexes. The reaction proceeds via a metal vinylidene intermediate, which undergoes [4 + 2]-cycloaddition vdth the same terminal alkyne or another internal alkyne, and then H migration and aromatization furnish naphthalene products [28] (Scheme 6.29). 

In an analogous late-stage arylation approach, terminal alkyne 31 was envisioned as a versatile intermediate. Slow addition of 4-pentynoyl chloride to imine 3 and (n-Bu)3N at reflux (efficient condenser, 100°C, 12 h, 1 1 toluene heptane) afforded only trace amounts of 31. Reaction of 4-pentynoyl chloride with triethylamine in methylene chloride under preformed ketene conditions ( 78°C, 1 h), followed by addition of 3 and warming to — 10°C over 4 h, afforded a complex mixture of products. Since high-yield preparation of 31 remained elusive, access to internal alkynyl analogs (type 33) was accomplished by preassembly of the appropriate arylalkynyl acid substrate for the ketene-imine cycloaddition reaction (Scheme 13.9). 

The [3+2] cycloaddition of terminal alkynes has been investigated with several dipoles. These dipolarophiles are competent in the cycloaddition, however, the corresponding isoxazolines cannot be isolated. Instead, the cycloadduct undergoes spontaneous rearrangement to provide acylaziridine products (Table 2.52) (229). Disubstituted alkynes also undergo this process, however, in lower yield. This rearrangement occurs with all nitronates studied (Chart 2.3) (66,230,231). 

TABLE 10.2. 1,3-DIPOLAR CYCLOADDITION REACTIONS OF IN SITU GENERATED MUNCHNONES AND TERMINAL ALKYNES" ... 

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