Copper-mediated reactions amidation

Nucleophilic Reactions. Useful nucleophilic substitutions of halothiophenes are readily achieved in copper-mediated reactions. Of particular note is the ready conversion of 3-bromoderivatives to the corresponding 3-chloroderivatives with copper(I)chloride in hot N,N-dimethylform amide (26). High yields of alkoxythiophenes are obtained from bromo- and iodothiophenes on reaction with sodium alkoxide in the appropriate alcohol, and catalyzed by copper(II) oxide, a trace of potassium iodide, and in more recent years a phase-transfer catalyst (27). 

A few reports involving copper-mediated substitution of selenophenes with heteroatoms (N, S) have appeared. The preparation of 2-amidoselenophenes (e.g., 48) was accomplished by treating 45 with amides in the presence of copper(l) iodide and ethylenediamine <2006JOC1552>. A similar copper-mediated reaction involving thiols was utilized to prepare sulfur-substituted selenophenes (e.g., 49) <2005TL2647>. 

A. Ullmann and Goldberg Reactions Copper-mediated Amination and Amidation of Aryl Halides... 

Coordination of nitrile to metal directly through the nitrogen or through some other proximal atom activates the carbon toward nucleophilic attack by water and other nucleophiles. The products are commonly amides. The metal-mediated reactions of dicyanodiamide (19) have been further investigated in the presence of nickel or copper salts (19) reacts with alcohols to yield (20). 

Reports by the groups of Chan, Evans, and Lam in 1998 revealed an alternative method to conduct copper-mediated couplings that form C(aryl)-0 and C(aryl)-N bonds. In this process, arylboronic acids react with compounds containing N-H or 0-H bonds in the presence of a Cu(II) reagent or catalyst. TTiese reactions were initially conducted with stoichiometric amounts of copper reagents. " Amines, anilines, amides, ureas, carbamates, and sulfonamides underwent N-arylation in moderate to excellent yields by this process (Equation 19.124). The commercial availability of boronic acids and the ability to conduct these arylations in air under mild conditions has caused this method to be adopted quickly for synthetic applications on a small scale. 

Rhodium(lll)-catalyzed redox—neutral coupling of N-phenoxyacet-amides and alkynes led to benzo[l)]furan derivatives (13AGE6033). Furo[2,3-l)]pyran-6-one derivatives were prepared via rhodium(II)-catalyzed reactions of diazo compounds and ethynyl compounds (13T9294). Copper-mediated oxidative annulation of phenols and unactivated internal alkynes afforded benzo[l ]furan derivatives (13CS3706). E t-kaurane maoecrystalV was produced via C-H functionalization (13JA14552). Rhodium-catalyzed intramolecular C-H... 

In Xia s light-mediated coupling of silyl enol ethers to 1 (Scheme 11.28), the absenee of the nucleophile led to the formation of the metho - (27a) and hydrojgr-substituted intermediates (27b) in yields of 43% and 57% respectively in a similar fashion to that proposed by Klussmann for the copper-mediated CDC reaction, i.e., off-cycle equilibria that trap the reactive intermediate. The use of wet methanol gave complete conversion to the hemiaminal. The authors proposed that formation of these products prevented further irreversible oxidation to the corresponding amide 84. Instead, 27a and 27b are in equilibrium with the iminium ion and this competes with the irreversible carbon-carbon bond-forming reaction to give 27e upon addition of the nucleophile. 

Abstract This review covers the recent recyclable protocols for the C-N bond forming reactions between aromatic, heterocyclic and aliphatic amines such as imidazoles, benzimidazoles, benzylamines, piperidine, pyrrole, imides, anilines, hexyl, cyclohexyl amines, and amides as coupling partners with aryl iodides, bromides, chlorides, and arylboronic acids employing copper-mediated systems. The physical properties and characterization of the catalysts and their use in organic synthesis will be outlined. Most importantly, these recyclable versions developed by many groups in the recent years are potential candidates for commercial exploitation. The effect of additives, solvents, temperature, base, the nature of aryl halides on reactivity, and recycle studies of the heterogeneous catalysts are included in this... 

Abstract Although requiring the use of stoichiometric amounts of metal and harsh conditions, the copper-mediated coupling reactions of aryl halides with amines and phenols (Ullmann craidensatiOTis), amides and carbamates (Ullmann-Goldberg condensations), or activated methylene compounds (Ullmann-Hurtley condensations) have been for a long time useful methods for the formation of C(aryl)-N, C(aryl)-0, and C(aryl)-C bonds. In 2001, a renaissance of the Ullmann reaction has been initiated with the discovery of versatile new copper catalytic systems for C-C, C-N, or C-O coupling under mild temperature ccmditions. 

In addition to the ruthenium SNAr chemistry discussed in Section 11.7.2, an analogous copper-assisted S Ar cyclization reaction of a boronic acid and a phenol has been reported to construct biaryl ethers 146 (Scheme 11.19). Specifically, this functionality was then incorporated into MMP inhibitors. The mild conditions were shown to tolerate amides and esters in the substrate, although the presence of an additional phenol resulted in only trace product. Some other transformations involving copper mediation are presented in Section 11.8. 

After successful application of the silver catalyst shown in olefin aziridination (Section 6.1.1), He and coworkers showed that intramolecular amidation was possible with both hydrocarbon-tethered carbamates and sulfamate esters.24 They found that only the Bu3tpy silver complex could catalyze efficient intramolecular amidation, while other pyridine ligands gave either dramatically lower yields or complicated product mixtures. In an interesting control study, both copper and gold were also tested in this reaction. Both the copper and gold Bu tpy complexes can mediate olefin aziridination, but only silver can catalyze intramolecular C-H amidation, indicating that the silver catalyst forms a more reactive metal nitrene intermediate. 

Metal nitrene complexes were used in a number of C-H amination reactions (recent reviews [358, 359]). Copper ketiminate complexes react with azides to nitrene complexes, which were isolated [360]. (p-Ketiminate)copper(I) complex 262 (2.5 mol%) serves therefore as an efficient catalyst for the intermolecular C-H amination of alkylarenes, cycloalkanes, or benzaldehydes 260 using adamantyl azide 261 as the nitrogen source ig. 68) [361]. The corresponding adamantyl amines or amides 263 were isolated in 80-93% yield. Copper complex 262 forms initially a dinuclear bridged complex with 261. From this a copper nitrene complex is generated by elimination of nitrogen, which mediates the hydrogen abstraction from 260. 

The reaction of A -[A -(benzoylimino)-A -phenylsulfonyl]amide 429 with iodosylbenzene 426 leads efficiently to nitrene intermediates that convert olefins 411 into aziridines 430 in good yields, through a copper(ll)-mediated (Cu(OTf)2) reaction. Owing to the stereogenic sulfur atom present in the molecules, the reactions proceed with some degree of diastereoselectivity (Scheme 111) <2004OL3573>. 

Other methods, among which thermolysis or photolysis of tetrazene [59], photolysis of nitrosoamines in acidic solution [60], photolysis of nitrosoamides in neutral medium [61], anodic oxidation of lithium amides [62], tributylstannane-mediated homolysis of O-benzoyl hydroxamic derivatives [63, 64], and spontaneous homolysis of a transient hydroxamic acid sulfinate ester [65] could have specific advantages. The redox reaction of hydroxylamine with titanium trichloride in aqueous acidic solution results in the formation of the simplest protonated aminyl radical [66] similarly, oxaziridines react with various metals, notably iron and copper, to generate a nitrogen-centered radical/oxygen-centered anion pair [67, 68]. The development of thiocarbazone derivatives by Zard [5, 69] has provided complementary useful method able to sustain, under favorable conditions, a chain reaction where stannyl radicals act simply as initiators and allow transfer of a sulfur-containing... 

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