Alkyne-gold addition

Other nucleophiles that have been used in this context are acetylides (alkynes). The addition of those to iminium cations generated in situ from aldehydes and secondary amines accomplishes a gold(III)-catalyzed three-component coupling for the synthesis of propargylamines, as can be observed in equation (124). The reactions are performed in water or in tetrahydrofuran (THF) when supported catalysts are employed.Chiral prolinol derivatives as... 

The gold(I)-catalyzed intramolecular Schmidt reaction of azido alkynes 49 provides easy entry to a series of pyrroles 54 with a variety of substitution patterns. The proposed mechanism involves gold(I)-induced activation of the alkyne toward addition by the proximal nitrogen of the azide. Subsequent loss of nitrogen leads to cationic intermediate 52, which is... 

Mechanistically, formation of products of exo-trig and endo-tng cyclization can be explained by the attack of the nucleophiles to cyclopropyl gold(l) carbene intermediates XXVI at carbons a or ft to form products 86 or 87 (Scheme 47), similarly to that found for Pt(ll) ([235], an example of gold-catalyzed methoxycy-clization of an allenene [237]). In the first step, the alkene reacts with the alkyne-gold(I) complex in an electrophilic addition process. 

A unique method to generate the pyridine ring employed a transition metal-mediated 6-endo-dig cyclization of A-propargylamine derivative 120. The reaction proceeds in 5-12 h with yields of 22-74%. Gold (HI) salts are required to catalyze the reaction, but copper salts are sufficient with reactive ketones. A proposed reaction mechanism involves activation of the alkyne by transition metal complexation. This lowers the activation energy for the enamine addition to the alkyne that generates 121. The transition metal also behaves as a Lewis acid and facilitates formation of 120 from 118 and 119. Subsequent aromatization of 121 affords pyridine 122. 

Gold(I) complexes of the type [AuCl(PPh3)ra] (n= 1, 2) or [Au(N03)(PPh3)] show an excellent performance towards oxidative addition carbonylation or aromatic amines to form corresponding carbamates, and also towards the carbonilation of aliphatic amines to produce either alkylureas or formamides.2552,2553 Cationic gold(I) compounds of the type [AuL]+ where L = phosphine, phosphite, or arsine are excellent catalysts for the addition of alcohols to alkynes.2554... 

Addition Reactions of Alkynes Catalyzed by Gold Complexes 266... 

The gold(i)-catalyzed addition of alcohols to alkynes has been investigated in the gas phase by mass spectrometry techniques. While in the condensed phase, an efficient coupling to the corresponding enol ethers has been observed, in the... 

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]. 

Until 1998, only gold(III) was believed to be effective for catalyzing these processes because, as mentioned previously, only the gold(I) compound K[Au (CN)2] was tested and it was inert to catalysis. Fortunately, Teles et al. reported very strong activity in the addition of alcohols to alkynes when they used cationic gold( I) -phosphane complexes [14]. In this study, the aforementioned authors tested for the first time the suitability of nucleophilic carbenes that displayed even greater activity than other gold complexes, but they were unable to synthesize the subsequent cationic derivatives. 

The addition of water and methanol to terminal alkynes has also been studied by Laguna et al. by pentafluorophenyl and mesityl gold derivatives. Both acidic and non-acidic conditions led to high activity, even in the presence of as little as 0.5 mol% of catalyst. The use of pentafluorophenyl compounds allowed them to obtain additional spectroscopic information in the stoichiometric reaction of the complex [Au (C6F5)2C1]2 and phenylacetylene, which showed that gold(III) was the active species in the catalytic process. The reaction followed the Markovnikov rule, as shown in the proposed mechanism (Scheme 8.13), delivering the corresponding ketones or diacetal products [96]. 

In the designed synthesis, gold first catalyzed an exo-addition of an OH group across an alkyne resulting in an enol ether. This transient enol ether could engage a ketal oxygen under protic conditions to form the bis-spiroketal [103]. 

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). 

A novel gold catalyzed example of three-component addition was recently reported by Shi et al. (Equation 8.44) [106]. Terminal aryl alkynes, alcohols and 2-(arylmethy-lene) cyclopropylcarbinols provided an intermolecular tandem hydroalkoxylation/ Prins-type reaction to form 3-oxabicyclo[3.1.0]hexanes from simple materials and under mild conditions, catalyzed by the system AuClPPh3/AgOTf. The proposed mechanism for this reaction is shown in Scheme 8.19. 

Hydroamination of Alkynes The discovery of palladium-catalyzed intramolecular addition of amines to acetylene coupled with the spectacular contribution of Hutchings opened the door for the synthesis of several nitrogen heterocycles. The first study in this field was performed by Utimoto et al., who researched gold catalyzed intramolecular 6-exo-dig hydroamination. Tautomerization of the initial enamines allowed them to obtain imines, which were thermodynamically more stable [111] (Scheme 8.20). 

A related work by Nakamura et al. was recently reported to show the gold-catalyzed process of aminosulfonylation, the formal addition of a nitrogen-sulfur bond to an alkyne moiety, and environmentally benign synthesis of a wide variety of 3- and 6-sulfonylindoles, present in many biologically active compounds [120]. 

Phosphorus—selenium bonds, alkyne additions, 10, 782 Phosphorus—sulfur bonds, alkyne additions, 10, 781 Phosphorus ylides with gold(I), 2, 275 with trinuclear Os clusters, 6, 740 Phosphoylides, actinide complexes, 4, 203 Photoacoustic calorimetry, in thermochemistry, 1, 612-613 Photoactive molecular devices, and -[RefCO) ,] fragment, 5, 886... 

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