Amines, metal catalyzed arylation

For recent reviews on transition metal-catalyzed aryl amine formation, see ... 

Thus, the transition metal catalyzed arylation reactions of amines and alcohols would constitute powerful tools for synthetic chemists. We have been developing practical procedures for the palladium-catalyzed arylation of amines and alcohols with aryl halides or sulfonates. During the course of our investigations [9] as well as those of John Hartwig and co-workers [10] the substrate scope of these transformations has been incrementally expanded. With each cycle of this catalyst improvement process, advances in mechanistic understanding and ligand design have also been made. 

The arylation of aliphatic amines has been difficult under metal-free conditions, but intramolecular arylations using aminoalkyl-substituted iodonium salts to yield indolines were viable (Scheme 5b) [94]. The groups of Olofsson and Adolfsson recently accomplished a metal-free arylation of secondary amides at room temperature (Scheme 5c) [95], A chemoselectivity study revealed a substantial orthoeffect, allowing selective transfer of a TRIP moiety and providing access to sterically hindered tertiary amides that are inaccessible by metal-catalyzed arylations. 

Kang and coworkers developed a number of metal-catalyzed arylations with diaryliodonium salts under mUd reaction conditions at the turn of the century, including the Pd-catalyzed arylation of secondary amines at room temperature and the Cu-catalyzed arylation of amines, anilines, amides, imidazoles, and triazoles at room temperature to 50 °C [98, 99]. The copper-catalyzed N-arylation of indoles, on the other hand, required heating to 150 °C in DMF [100], and makes an interesting comparison with the recently developed C-arylation of the same substrates (see Sect. 4.2.2). 

Transition metal-catalyzed synthesis of hetarylamines and hetaryl ethers from triflates and aryl/hetaryl halides or heterocyclic amines 98AG(E)2046. 

The Suzuki reaction has been successfully used to introduce new C - C bonds into 2-pyridones [75,83,84]. The use of microwave irradiation in transition-metal-catalyzed transformations is reported to decrease reaction times [52]. Still, there is, to our knowledge, only one example where a microwave-assisted Suzuki reaction has been performed on a quinolin-2(lH)-one or any other 2-pyridone containing heterocycle. Glasnov et al. described a Suzuki reaction of 4-chloro-quinolin-2(lff)-one with phenylboronic acid in presence of a palladium-catalyst under microwave irradiation (Scheme 13) [53]. After screening different conditions to improve the conversion and isolated yield of the desired aryl substituted quinolin-2( lff)-one 47, they found that a combination of palladium acetate and triphenylphosphine as catalyst (0.5 mol %), a 3 1 mixture of 1,2-dimethoxyethane (DME) and water as solvent, triethyl-amine as base, and irradiation for 30 min at 150 °C gave the best result. Crucial for the reaction was the temperature and the amount of water in the... 

Some other examples of metal-catalyzed substitutions are given in Scheme 11.10. Entries 1 to 3 are copper-catalyzed reactions. Entry 1 is an example of arylation of imidazole. Both dibenzylideneacetone and 1,10-phenanthroline were included as ligands and Cs2C03 was used as the base. Entry 2 is an example of amination by a primary amine. The ligand used in this case was (V,(V-diethyl sal icyl amide. These conditions proved effective for a variety of primary amines and aryl bromides with both ERG and EWG substituents. Entry 3 is an example of more classical conditions. The target structure is a phosphodiesterase inhibitor of a type used in treatment of asthma. Copper powder was used as the catalyst. 

Aryl- and heteroaryl halides can undergo thermal or transition metal catalyzed substitution reactions with amines. These reactions proceed on insoluble supports under conditions similar to those used in solution. Not only halides, but also thiolates [76], nitro groups [76], sulfinates [77,78], and alcoholates [79] can serve as leaving groups for aromatic nucleophilic substitution. 

The transition metal catalyzed synthesis of arylamines by the reaction of aryl halides or tri-flates with primary or secondary amines has become a valuable synthetic tool for many applications. This process forms monoalkyl or dialkyl anilines, mixed diarylamines or mixed triarylamines, as well as N-arylimines, carbamates, hydrazones, amides, and tosylamides. The mechanism of the process involves several new organometallic reactions. For example, the C-N bond is formed by reductive elimination of amine, and the metal amido complexes that undergo reductive elimination are formed in the catalytic cycle in some cases by N-H activation. Side products are formed by / -hydrogen elimination from amides, examples of which have recently been observed directly. An overview that covers the development of synthetic methods to form arylamines by this palladium-catalyzed chemistry is presented. In addition to the synthetic information, a description of the pertinent mechanistic data on the overall catalytic cycle, on each elementary reaction that comprises the catalytic cycle, and on competing side reactions is presented. The review covers manuscripts that appeared in press before June 1, 2001. This chapter is based on a review covering the literature up to September 1, 1999. However, roughly one-hundred papers on this topic have appeared since that time, requiring an updated review. 

Furthermore, Pd-catalyzed aminations can be sequentially coupled with alkene insertion and amination. Wolfe and Lira [102] have established a transformation involving two different sequential metal-catalyzed reactions that lead to AT-aryl-2-benzylindolines 125 in moderate to excellent yields upon formation of two C - N bonds and one C - C bond in a one-pot process (Scheme 45). Interestingly, the selective installation of two different aryl groups in this sequence can be accomplished by in situ modification of the Pd catalyst system Pd-126 upon addition of the chelating ligand dpephos prior to addition of the second aryl bromide (Scheme 46). The selectively substituted indoline derivatives 127 were isolated in good to excellent yields. 

There are interesting transition metal-catalyzed-reactions that lead to aryl amides. The use of POCI3 and DMF, with a palladium catalyst, converts aryl iodides to benzamides. A palladium-catalyzed reaction of aryl hahdes and for-mamide leads to benzamide derivatives. Carbonylation is another method that generates amides. When an aryl iodide was treated with a secondary amine and Mo(CO)e, in the presence of 3 equivalents of DBU, 10% Pd(OAc)2, with micro-wave irradiation at 100°C, the corresponding benzamide was obtained. 

The metal catalyzed reaction with ammonia or amines likely proceeds by the SNAr mechanism. This reaction, with phase-transfer catalysis, has been used to synthesize triarylamines. Copper ion catalysts (especially cuprous oxide or iodide) also permit the Gabriel synthesis (10-41) to be applied to aromatic substrates. Aryl bromides or iodides are refluxed with potassium phthalimide and... 

A variety of other nucleophiles have been used for the metal-catalyzed displacement of chlorine in nonactivated chloroarenes, including arylthiolate [191-193] and iodide [194, 195] anions, primary and secondary amines [196, 197], tertiary phosphines [198,199], and aminophosphines [200]. All these reactions are catalyzed by either preformed or generated in situ Ni(0) complexes. Very recently, however, Reddy and Tanaka [201] and Koie et al. [202] reported the arylation of secondary amines with chlorobenzene and other chloroarenes, catalyzed by palladium complexes containing bulky, electron-rich phosphines,... 

The transition-metal catalyzed cross-coupling reaction of (hetero)aryl hahdes and triflates with primary and secondary amines or (hetero)aryl amines is know as the Buchwald-Hartwig reaction [144]. Mechanistically, this reaction is related to the crosscoupling reactions outlined thus far (Fig. 4.6). The modification arises at the point of transmetalation. This step in the process is substituted with the coordination of the amine reactant. Deprotonation of the amine nitrogen now precedes the reductive elimination step to generate the aryl amine product. This reaction has foimd utility in the academic setting, for use in natural product total synthesis, and in industry, for the preparation of materials up to the multi-hundred kilogram scale. 

Optically active alcohols, amines, and alkanes can be prepared by the metal catalyzed asymmetric hydrosilylation of ketones, imines, and olefins [77,94,95]. Several catalytic systems have been successfully demonstrated, such as the asymmetric silylation of aryl ketones with rhodium and Pybox ligands however, there are no industrial processes that use asymmetric hydrosilylation. The asymmetric hydrosilyation of olefins to alkylsilanes (and the corresponding alcohol) can be accomplished with palladium catalysts that contain chiral monophosphines with high enantioselectivities (up to 96% ee) and reasonably good turnovers (S/C = 1000) [96]. Unfortunately, high enantioselectivities are only limited to the asymmetric hydrosilylation of styrene derivatives [97]. Hydrosilylation of simple terminal olefins with palladium catalysts that contain the monophosphine, MeO-MOP (67), can be obtained with enantioselectivities in the range of 94-97% ee and regioselectivities of the branched to normal of the products of 66/43 to 94/ 6 (Scheme 26) [98.99]. 

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