Intermolecular reactions alkynes

Intermolecular Reactions Dimethyl acetylenedicarboxylate (DMAD) is frequently used as an alkyne dipolarophile (23, 24, 126b, 152, 241, 333). 

Recently, addition of organorhodium species to nitriles has been reported.420 4203 4201 Intermolecular reaction of benzonitrile with phenylborate (accompanied with r//w-aryiation) (Equation (65)), arylative cyclization of acetylenic nitriles (Equation (66)), and cyclization of 2-cyanophenylboronic acid with alkynes or strained alkenes (Equation (67)) are proposed to proceed via this process. 

Intermolecular enyne metathesis has recently been developed using ethylene gas as the alkene [20]. The plan is shown in Scheme 10. In this reaction,benzyli-dene carbene complex 52b, which is commercially available [16b], reacts with ethylene to give ruthenacyclobutane 73. This then converts into methylene ruthenium complex 57, which is the real catalyst in this reaction. It reacts with the alkyne intermolecularly to produce ruthenacyclobutene 74, which is converted into vinyl ruthenium carbene complex 75. It must react with ethylene, not with the alkyne, to produce ruthenacyclobutane 76 via [2+2] cycloaddition. Then it gives diene 72, and methylene ruthenium complex 57 would be regenerated. If the methylene ruthenium complex 57 reacts with ethylene, ruthenacyclobutane 77 would be formed. However, this process is a so-called non-productive process, and it returns to ethylene and 57. The reaction was carried out in CH2Cl2 un-... 

Dailey and colleagues109 employed a domino Diels-Alder reaction to synthesize the complex hexacycle 146. The intermolecular reaction of tetracycle 143 with maleic anhydride 144 afforded a single adduct (145) which immediately underwent an intramolecular Diels-Alder reaction to give 146 (equation 42). This reaction is similar to a reaction performed previously by Prinzbach and colleagues110. Prinzbach observed that when alkynes were used as dienophiles, either domino or pincer Diels-Alder reactions occurred. In the latter type, the triple bond reacts with both diene units. 

A development of the last two decades is the use of Wacker activation for intramolecular attack of nucleophiles to alkenes in the synthesis of organic molecules [9], In most examples, the nucleophilic attack is intramolecular, as the rates of intermolecular reactions are very low. The reaction has been applied in a large variety of organic syntheses and is usually referred to as Wacker (type) activation of alkene (or alkynes). If oxygen is the nucleophile, it is called oxypalladation [10], Figure 15.4 shows an example. During these reactions the palladium catalyst is often also a good isomerisation catalyst, which leads to the formation of several isomers. 

The intermolecular reaction of alkynes with acylcarbene complexes normally yields cyclopropenes [587,1022,1060-1062]. Because of the high reactivity of cyclopropenes, however, in some of these reactions unexpected products can result. In particular intramolecular cyclopropanations of alkynes, which would lead to highly strained bicyclic cyclopropenes, often yield rearrangement products of the latter. In many instances these products result from a transient vinylcarbene complex, which can be formed by two different mechanisms (Figure 4.3). 

Two precedent examples had been reported of the enantioselective [2+2+2] cycloaddition of alkynes. In one case, an enantioposition-selective intermolecular reaction of a triyne with acetylene generated an asymmetric carbon at the benzylic position of a formed benzene ring [19]. In the other case, an intramolecular reaction of a triyne induced helical chirality [20]. Both reactions were developed by chiral Ni catalysts. 

As an extension of intermolecular reactions described earlier, some intramolecular lEDDA reactions of electron-deficient pyridazines with alkyne dienophiles have been presented <1998MOL10, 2001TL7929>. 

The most widely used, and often most convenient reagents for such one-pot reactions are sodium hypochlorite (45) or hypobromite (16). These reactions are performed in the presence of an organic base (generally triethylamine) that normally enhances the yield of cycloaddition products (45). This method was employed for many intermolecular reactions (71) and also seems especially suited for intramolecular ones (72-77) as well as for the solid-phase synthesis (78) of 2-isoxazolines. Hypohalite can also be replaced by sodium broruite in combination with a catalytic amount of tri-u-butyltin chloride (79). In a related method, O-tributylstannyl oximes were treated with tert-butyl hypochlorite to produce nitrile oxides that were trapped with aUcenes or alkynes to afford the corresponding isoxazolines or isoxazoles in moderate to good yield (80). 

The yield was based on the used alkynes during the intermolecular reaction. 

Later, Wender and co-workers showed that an intermolecular reaction with disubstituted alkynes and 2,3-dimethylbutadiene provided PKR products in high yields under similar conditions/... 

At the beginning of the new millennium, Hashmi et al. presented a broad research study on both intramolecular and intermolecular nucleophilic addition to alkynes and olefins [18]. One of the areas covered by these authors was the isomerization of co-alkynylfuran to phenols [19]. After that, Echavarren and coworkers identified the involvement of gold-carbene species in this type of process, thus opening a new branch in gold chemistry [20]. And subsequently, Yang and He demonstrated the initial activation of aryl —H bonds in the intermolecular reaction of electron-rich arenes with O-nucleophiles [21, 22]. 

The reaction worked with both internal and terminal alkynes (except silylated alkynes) and in many solvents, even in the neat alcohol added [105]. The mechanism proposed involved two catalytic cycles first, gold catalysis would lead to dihydro-furan by a fast intramolecular reaction then, the subsequent slower intermolecular reaction would be produced by the addition of alcohol to the enol ether to deliver a ketal (Scheme 8.18). 

Solvent-free conditions were used by Tanaka et al. in their assays to obtain intermolecular reactions from alkynes and anilines. The chosen catalyst was [AuMe(PPh3)] with an acidic promoter [92]. Reaction, whose effectiveness was greater in the case of aromatic amines, proceeded via Markovnikov by amine electrophilic attack of the alkyne in a similar way to the methanol addition proposed by Teles (see Section 2.1.3.2) and provided high yields and TONs. 

Oxidative cyclization is another type of oxidative addition without bond cleavage. Two molecules of ethylene undergo transition metal-catalysed addition. The intermolecular reaction is initiated by 7i-complexation of the two double bonds, followed by cyclization to form the metallacyclopentane 12. This is called oxidative cyclization. The oxidative cyclization of the a,co-diene 13 affords the metallacyclopentane 14, which undergoes further transformations. Similarly, the oxidative cyclization of the a,co-enyne 15 affords the metallacyclopentene 16. Formation of the five-membered ring 18 occurs stepwise (12, 14 and 16 likewise) and can be understood by the formation of the metallacyclopropene or metallacyclopropane 17. Then the insertion of alkyne or alkene to the three-membered ring 17 produces the metallacyclopentadiene or metallacyclopentane 18. 

Alkynes continue to be used as a reactive functionality in quinoline synthesis. The readily available thiocarba-mates, thioamides, and thioureas allow intramolecular cyclization of pendant alkynes to give modest to good yields of the quinolines (Equation 118) <20030L1765>. An intermolecular reaction involving a zinc-mediated alkynylation-cyclization provides an efficient route to 4-trifluoromethyl-substituted quinolines (Equation 119) <2002JOC9449>. 

In intermolecular reactions, neutral aminyl radicals, R2N", react with n systems preferably by HAT. N-protonation increases the electrophUicity of the radical center, and successful addition of aminium radicals, R2NH, to 7t systems, usually alkenes, has been reported in the hterature." Compared to aminium radicals, amidyl and imidyl radicals, for example, RN C(0)R and [RC(0)]2N , are less electrophilic. Although they are delocahzed 7t-allyl radicals, they react exclusively at nitrogen." Only very few examples for radical cascades that are initiated by addition of A-centered radicals to alkynes have been reported. 

Formation of polycyclic ring systems via intermolecular reactions of Fischer carbenes with alkynes can be achieved. In a metathesis-type reaction, reactions of 1,6-enynes afford... 

A less efficient mode of the two-alkyne annulation is the intra-intermolecular reaction of an alkyne-containing carbene complex of the type (312) with a second alkyne. Under optimal conditions, these reactions will lead to moderate yields of bicyclic phenols of the type (313), which result from the assembly of pieces indicated by (315). The precursor dienones (314) can be isolated as minor products from these reactions.Applications of the two-alkyne annulations in organic synthesis have not yet been reported. 

An intramolecular version of this process has been described, leading to bicyclic 2-pyrones. Diynes in which both alkyne functions are internal and are linked by three-, four- or five-atom chains cycloadd to carbon dioxide in the presence of catalytic Ni° and various trialkylphosphines (equation 51). Terminal diynes require stoichiometric metal and give lower yields, however. Extensive studies of ligand effects on yield and chemoselectivity have established a broad scope for the process and pointed out important practical differences between it and the intermolecular reactions described above. ... 

The Pauson-Khand reaction is especially useful for the intramolecular cycliza-tion of 1,6-enynes to give bicyclo[3.3.0]octenones. The intermolecular reaction has problems of regioselectivity when unsymmetrical alkynes or alkenes are used, although some substrates give especially good selectivity for various reasons. 

Intermolecular reactions of tungsten carbene complexes have also been studied . Upon stirring a solution of the complex in dichloromethane or hexane at 10°C or room temperature with two equivalents of an alkyne, bicyclo[4.1.0]heptan-3-ones were obtained directly after chromatographic workup. ... 

In addition, the application of Jeffery s conditions by Sinou and co-workers, with extra triphenylphosphine and tetrabutylammonium hydrogensulfate, confirmed that Cul is not essential to success in alkyne coupling reactions [24], Moreover, they reported the most efficient coupling of bromoanisole with propargyl alcohol in 81% yield. These results prompted the authors to apply these conditions in a cascade reaction, consisting of an intermolecular Heck reaction followed by cyclization of the intermediate cr-complex (Eq. 9). The product, which is a mixture of (E) and (Z) stereomers (approximately 1 1), was sometimes contaminated with a by-product resulting from aromatization, especially for longer reaction times. 

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