Cross-coupling reactions protocol

AT-acetyltryptamines could be obtained via microwave-assisted transition-metal-catalyzed reactions on resin bound 3-[2-(acetylamino)ethyl]-2-iodo-lH-indole-5-carboxamide. While acceptable reaction conditions for the application of microwave irradiation have been identified for Stille heteroaryla-tion reactions, the related Suzuki protocol on the same substrate gave poor results, since at a constant power of 60 W, no full conversion (50-60%) of resin-bound 3-[2-(acetylamino)ethyl]-2-iodo-lH-indole-5-carboxamide could be obtained even when two consecutive cross-coupling reaction cycles (involving complete removal of reagents and by-products by washing off the resin) were used (Scheme 36). Also under conventional heating at 110 °C, and otherwise identical conditions, the Suzuki reactions proved to be difficult since two cross-coupling reaction cycles of 24 h had to be used to achieve full conversion. 

In the context of NHC/metal catalysed cross-coupling reactions, the only example of a Hiyama reaction was reported by Nolan using an in situ protocol by mixing Pd(OAc)j and IPr HCl for the formation of the catalyst. Activated aryl bromides and chlorides, such as 2-chloropyridine, were coupled with phenyl and vinyl-trimethoxysilane in good yields [123] (Scheme 6.39). 

Anionic complexes of boron (boronates, borinates, etc.) have been introduced as convenient reagents in cross-coupling reactions of broad scope, particularly interesting for the transfer of alkynyl and primary alkyl residues, which cannot be accomplished using the standard protocols of the Suzuki-Miyaura reaction. Readily available Ph4BNa can be used as a convenient reagent for phenylation in place of the much more expensive PhB(OH)2, and all four phenyl groups can be utilized when the reaction is carried out with a phosphine-free catalyst in aqueous solutions.244... 

The use of enol- and phenol-esters in cross-coupling reactions is a valuable protocol, as it gives an indirect way to involve readily available phenols and carbonyl compounds as the electrophilic components of cross-couplings (Equation (22)) ... 

Commercially available Pd(PtBu3)2 is a unique, air-stable 14e Pd° complex, an excellent catalyst for cross-coupling reactions of aryl chlorides. The ability of P Bu3 to stabilize such a coordin-atively unsaturated, extremely reactive, and yet easily manageable form of Pd° is one of the most amazing and fruitful recent findings in Pd-based catalysis. The cross-coupling of arylzinc reagents with aryl or vinyl chlorides can be readily accomplished with as little as 0.03% of this catalyst. Both electron-rich and sterically hindered substrates are welcome in this protocol.404... 

Generalized protocol for the cross- coupling reactions of Ar3Bi with aryl halides ... 

Transition metal-catalyzed cross-coupling reactions between vinyl organometallic compounds and unactivated alkyl halides that can be usually performed with palladium, nickel and cobalt are of particular synthetic interest [37-39]. Recently, the groups of Cahiez [48] and Cossy [49] concurrently reported the first iron-catalyzed reaction of alkenyl Grignard compounds with primary and secondary alkyl halides (X=Br, I) (Scheme 5.15). The two protocols basically differ in the iron source... 

Scheme 10.2 shows a protocol for synthesizing 1 and its further transformation into 4 [13a,d], Monolithiation of the diiodide 9 followed by treatment with S8 and AcCI generated 1. Next, a Sonogashira cross-coupling reaction with trimethylsilyl-acetylene afforded 10 in high yield. Desilylation was obtained upon treatment with n-Bu4NF, which provided the terminal alkyne 4. 

Most recently, Monteiro et al. have reported that cyclopalladated compounds derived from the ortho-metalation of benzylic tert-butyl thioethers are excellent catalyst precursors for the Suzuki cross-coupling reaction of aryl bromides and chlorides with phenylboronic acid under mild reaction conditions. A broad range of substrates and functional groups are tolerated in this protocol, and high catalytic activity is attained (Eq. (58)) [93]. 

Lithiation of compound 560 with s-BuLi-TMEDA in THF at —78 °C following an inverse addition protocol provided the anion 561. It reacts with primary alkyl iodides and triflates, silyl chlorides, diphenyl disulfide, epoxides, aldehydes, ketones, imines, acyl chlorides, isocyanates and sulfonyl fluorides to yield the expected compounds 562 (Scheme 152). The transmetallation of compound 561 with ZnBr2 allowed the palladium-catalyzed cross-coupling reaction with aryl and vinyl bromides837. When the reaction was quenched with 1,2-dibromotetrafluoroethane, the corresponding bromide 562 (X = Br) is obtained838. 

The log, lath-like molecular structure of most liquid crystalline compounds makes the cross-coupling protocol very important in syntheses [178,179]. The method based on arylboronic acids simplifies the procedure for liquid crystal materials of more complex substitution patterns [64,180,181] (Scheme 32). The synthesis of arylboronic acids via ortho-metalation of fiuoroarenes and the successive cross-coupling reaction readily extended the aryl units. The Pd/C-cat-alyzed reaction was also reported as an economical alternative [64]. Several liquid crystals having a biaryl unit are now an industrial process of Merck in Germany (ca. 3 tons/year) [182]. 

For the ketone synthesis via the present protocol, acid chlorides are useful precursors, in deed. Nevertheless, carbonylative cross coupling with organic halides is strategically the most simple and direct way to this purpose. The palladium-catalyzed carbonylative cross-coupling reaction with various organic halides has been extensively investigated, because of its merits from synthetic as well as phenomenal point of view. Acid chlorides are not always readily available, and their preparation is not always compatible with many sensitive functionalities. Therefore the development of this type of reaction widens the scope of the ketone synthesis in the present protocol because of the ready availability and storability of organic halides and pseudohalides. 

While organic chlorides, bromides, and iodides are still the most common substrates, recently the scope has been expanded to include organic fluorides, nitriles, ethers, triflates, phosphates, iodonium salts, and substrates with various chalconide-leaving groups. Of the different cross-coupling reactions covered in this article, the Kumada Corriu protocol has been the least reviewed. However, the topic has been covered in recent historical treatments. ... 

Unlike other cross-coupling reactions, for which the scope has rapidly expanded in recent years, the range of electrophilic substrates that can be used successfully in the Sonogashira protocol is still rather limited. Vinylic substrates (iodides, bromides, chlorides, triflates, and more recently tosylates) typically yield the best results. For aromatic substrates, iodides and triflates are preferred over bromides, which in turn give far better yields than aryl chlorides. This latter aspect of the reaction is particularly frustrating when one considers the recent advances in the activation of aryl chloride substrates for reactivity in other cross-coupling protocols. ... 

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