Palladium‐Catalyzed Direct Arylations of 1,2,3‐Triazoles with Aryl Chlorides using Conventional Heating

Generally applicable, palladium‐catalyzed direct arylations of 1,2,3‐triazoles with aryl chlorides were accomplished through conventional heating at reaction temperatures of 105–120 °C. Thereby, intra‐ and intermolecular C H bond functionalizations were achieved with a variety of differently substituted chlorides as electrophiles, bearing numerous valuable functional groups.     

Palladium‐Catalysed Regioselective Sequential C‐5 and C‐2 Direct Arylations of 3‐Acetylpyrroles with Aryl Bromides

The PdCl(C₃H₅)(dppb)/KOAc system was found to be effective for the direct regioselective C‐5 arylation of 3‐acetylpyrroles with ortho‐substituted aryl bromides. This procedure has been found to be tolerant to a variety of functional groups at C‐2 of the aryl bromide such as methyl, formyl, nitrile, nitro, hydroxymethyl, chloro, fluoro or trifluoromethyl. The sequential direct C‐5 arylation followed by C‐2 arylation of such 3‐substituted pyrroles allows the synthesis of 2,5‐diaryl‐3‐acetylpyrroles in high yields.     

Intermolecular versus Intramolecular Palladium‐Catalyzed Direct Arylations between 1‐(2‐Bromobenzyl)imidazoles and Aryl Bromides

Herein, we report on the sequential palladium‐catalyzed intermolecular followed by intramolecular direct arylations of 1‐(2‐bromobenzyl)imidazoles. We found that, in the presence of 1 mol% palladium acetate and potassium acetate as base, the intermolecular reaction between 1‐(2‐bromobenzyl)imidazole derivatives and electron‐deficient aryl bromides proceeded faster than the intramolecular reaction, allowing us to prepare medium‐size polycyclic imidazoles after a second Pd‐catalyzed intramolecular arylation. These iterative direct arylations allowed the synthesis of fused nitrogen‐containing heterocycles with a 5‐ or 7‐membered‐ring in only two steps. Some reactions have also been performed as a one‐pot procedure using 2 mol% of palladium acetate in the presence of a larger amount of base (3 equiv.).

     

A General and Practical Palladium‐Catalyzed Direct α‐Arylation of Amides with Aryl Halides

An efficient system for the direct catalytic intermolecular α‐arylation of acetamide derivatives with aryl bromides and chlorides is presented. The palladium catalyst is supported by Kwong’s indole‐based phosphine ligand and provides monoarylated amides in up to 95% yield. Excellent chemoselectivities (>10:1) in the mono‐ and diarylation with aryl bromides were achieved by careful selection of bases, solvents, and stoichiometry. Under the coupling conditions, the weakly acidic α‐protons of amides (pK_a up to 35) were reversibly depotonated by lithium tert‐butoxide (LiO‐t‐Bu), sodium tert‐butoxide (NaO‐t‐Bu) or sodium bis(trimethylsilyl)amide [NaN(SiMe₃)₂].

     

One‐Pot Palladium‐Catalyzed Synthesis of Selectively Substituted Phenanthridines by Sequential Aryl‐Aryl and Heck Couplings,Aza‐Michael and Retro‐Mannich Reactions

A catalytic synthesis of selectively substituted phenanthridines is achieved through a reaction sequence involving palladium/norbornene‐catalyzed unsymmetrical aryl‐aryl and Heck couplings followed by aza‐Michael and retro‐Mannich reactions. In spite of the many steps involved the method is very simple and allows the formation of selectively substituted phenanthridines under mild conditions in a straightforward one‐pot reaction starting from readily available aryl iodides and bromides.     

Palladium‐Catalyzed Regioselective γ‐Mono‐ and Diarylation of Acrylamide Derivatives with Aryl Halides

Palladium‐catalyzed direct mono‐ and diarylations involving C(sp³) H cleavage at the γ‐position of acrylamides are described. The monoarylation products can be obtained with ortho‐substituted aryl halides. Single crystal X‐ray diffraction has shown that the double bond has shifted towards the introduced aryl group to afford the γ‐arylated β,γ‐unsaturated amide products. A second arylation occurs when less sterically hindered aryl halides are employed. This chemistry offers a novel disconnection for the synthesis of γ‐arylated compounds.     

Recent Applications of Palladium‐Catalyzed Coupling Reactions in the Pharmaceutical,Agrochemical, and Fine Chemical Industries

Palladium‐catalyzed coupling reactions have become a central tool for the synthesis of biologically active compounds both in academia and industry. Most of these transformations make use of easily available substrates and allow for a shorter and more selective preparation of substituted arenes and heteroarenes compared to non‐catalytic pathways. Notably, molecular‐defined palladium catalysts offer high chemoselectivity and broad functional group tolerance. Considering these advantages, it is not surprising that several palladium‐catalyzed coupling reactions have been implemented in the last decade into the industrial manufacture of pharmaceuticals and fine chemicals. In this review different examples from 2001–2008 are highlighted, which have been performed at least on a kilogram scale in the chemical and pharmaceutical industries.     

Selective Palladium‐Catalyzed Suzuki–Miyaura Reactions of Polyhalogenated Heteroarenes

The palladium‐catalyzed Suzuki–Miyaura reaction of multiply halogenated, electron‐rich and electron‐deficient heteroarenes is one of the most reliable and environmentally friendly tools for installing a wide range of non‐functionalized and functionalized carbon substituents onto heteroaromatic systems with exquisite chemo‐ and site‐selectivity. For substrates with different halogen groups the chemoselectivity of the Suzuki–Miyaura reactions has been found to be dependent on the reactivity difference between the halogens. However, the hardest achievement of selectivity in Suzuki–Miyaura monocouplings involving polyhalogenated heteroarenes with identical halogen atoms has been shown to be dominated by steric and electronic effects and the presence of directing groups at positions neighbouring the reaction sites. Moreover, in the case of symmetrically substituted dihaloheteroarenes with identical halogen atoms, highly selective monocoupling reactions have often been achieved only after a careful optimization of reaction parameters including the catalyst precursor, base, solvent, and the molar ratio between electrophile and organoboron reagent. This critical review with 341 references covers developments on the chemo‐ and site‐selective Suzuki–Miyaura monocoupling reactions of polyhalogenated heteroarenes with different or identical halogen atoms. It also includes the synthesis of polysubstituted heteroarenes, not easily accessible by other means, via consecutive monocoupling reactions and/or a more synthetically valuable approach involving one‐pot polycoupling reactions.     

Palladium‐Catalysed Direct Arylation of Heteroaromatics Bearing Unprotected Hydroxyalkyl Functions using Aryl Bromides

Heteroaromatics bearing unprotected hydroxyalkyl functions can be arylated using aryl or heteroaryl bromides, via palladium‐catalysed carbon‐hydrogen bond activation/arylation. Good yields were generally obtained using 0.01–0.5 mol% of the air‐stable palladium acetate complex as the catalyst. The nature of the base was found to be crucial for the selectivity of this reaction. Potassium acetate led to the direct arylation products whereas caesium carbonate led to the formation of the ether. This procedure is certainly more atom‐economic than other methods for the preparation of such compounds, as no protection/deprotection sequence of the hydroxyalkyl function and no preparation of an organometallic derivative is required.     

Iron‐Catalyzed Nitrogen‐Directed Coupling of Arene and Aryl Bromides Mediated by Metallic Magnesium

2‐Arylpyridines, 2‐alkenylpyridine, and aromatic imines can be coupled with aryl bromides in the presence of an iron catalyst, metallic magnesium, a diamine ligand and an organic dihalide oxidant at 0 °C. The use of a 1:1 mixture of tetrahydrofuran and 1,4‐dioxane is essential for this C H bond activation reaction. The reaction has wider scope of the substrate compared with the reaction using a separately prepared Grignard reagent, and proceeds with lower catalyst loading (2.5 mol%).     

Iridium‐Catalyzed Selective Synthesis of 4‐Substituted Benzofurans and Indoles via Directed Cyclodehydration

A directed cyclization‐dehydration cascade of α‐aryloxy ketones and α‐arylamino ketones was efficiently catalyzed by a cationic iridium‐BINAP complex, which afforded various types of 4‐substituted benzofurans and indoles in high yields with complete regioselectivity. The newly developed protocol also enabled the enantioselective preparation of chiral 4‐acetyloxindole using a chiral iridium catalyst.     

Palladium‐Catalyzed Aryl Amination Reactions of 6‐Bromo‐ and 6‐Chloropurine Nucleosides

Palladium‐catalyzed C N bond forming reactions of 6‐bromo‐ as well as 6‐chloropurine ribonucleosides and the 2′‐deoxy analogues with arylamines are described. Efficient conversions were observed with palladium(II) acetate/Xantphos/cesium carbonate, in toluene at 100 °C. Reactions of the bromonucleoside derivatives could be conducted at a lowered catalytic loading [5 mol% Pd(OAc)₂/7.5 mol% Xantphos], whereas good product yields were obtained with a higher catalyst load [10 mol% Pd(OAc)₂/15 mol% Xantphos] when the chloro analogue was employed. Among the examples evaluated, silyl protection for the hydroxy groups appears better as compared to acetyl. The methodology has been evaluated via reactions with a variety of arylamines and by synthesis of biologically relevant deoxyadenosine and adenosine dimers. This is the first detailed analysis of aryl amination reactions of 6‐chloropurine nucleosides, and comparison of the two halogenated nucleoside substrates.     

Palladium‐Catalyzed and Hybrid Acids‐Assisted Synthesis of [60]Fulleroazepines in One Pot under Mild Conditions: Annulation of N‐Sulfonyl‐2‐aminobiaryls with [60]Fullerene through Sequential C‐H Bond Activation,C‐C and C‐N Bond Formation

An extraordinarily efficient hybrid acids‐assisted, palladium‐catalyzed and chelating‐group‐assisted C H bond activation of N‐sulfonyl‐2‐aminobiaryls and their annulations with [60]fullerene via sequential C C and C N bond formation at room temperature to afford [60]fulleroazepines is demonstrated. The formation of [60]fulleroazepines is highly regioselective and tolerant to both electron‐withdrawing and electron‐donating groups on the aryl moiety and the reaction gives monofunctionalized fullerenes in good yields (up to 54% isolated yield and 92% based on converted C₆₀).     

Palladium‐Catalysed Direct Desulfitative Arylation of Pyrroles using Benzenesulfonyl Chlorides as Alternative Coupling Partners

The reactivity of pyrrole derivatives for palladium‐catalysed desulfitative arylation has been investigated. 1‐Methyl‐, 1‐phenyl‐ and 1‐benzylpyrroles were successfully coupled with a variety of benzenesulfonyl chlorides using a phosphine‐free catalyst. Highly regioselective arylations at carbon C2 of pyrroles were observed in all cases. A wide variety of substituents on the benzenesulfonyl derivative was tolerated. It should be noted that even bromo‐ and iodo‐benzenesulfonyl chlorides were successfully coupled with pyrrole derivatives without cleavage of the C Br or C I bonds, allowing further transformations. Surprisingly, with indoles, mixtures of C2‐ and C3‐arylation products were obtained.

     

Zheda‐Phos for General α‐Monoarylation of Acetone with Aryl Chlorides

A new, readily available, and air‐stable monophosphine ligand, i.e., Zheda‐Phos , has been developed for the general and highly effective palladium‐catalyzed monoarylation of acetone with aryl chlorides. The reaction rate is of first‐order dependence with the aryl chloride.     

Oxaphosphole‐Based Monophosphorus Ligands for Palladium‐Catalyzed Amination Reactions

A novel class of C‐2‐substituted oxaphosphole‐based monophosphines 1–4 has been synthesized. Palladium complexes derived from these ligands and their C‐2‐unsubstituted analogs provide general catalysts for amination reactions of challenging aryl and heteroaryl halides with sterically hindered anilines and alkylamines.     

Palladium‐Catalyzed Regioselective ortho‐Acylation of Azoxybenzenes with Aldehyde Derivatives

An efficient strategy for the regioselective ortho‐acylation of azoxybenzenes with various aldehydes in the presence of palladium catalysts has been developed and furnishes good to excellent yields. The reaction proceeds smoothly and can tolerate a variety of functional groups.

     

Rhodium‐Catalyzed Oxidative ortho‐Acylation of Aryl Ketone O‐Methyl Oximes with Aryl and Alkyl Aldehydes

The rhodium‐catalyzed oxidative ortho‐acylation of aryl ketone O‐methyl oximes with aryl and alkyl aldehydes via C H bond activation is described. The cross‐coupling reaction exhibits high functional group tolerance and regioselectivity under relatively mild conditions and constitutes a versatile route to a diverse library of diaryl ketones, which are difficult to obtain by the classical Friedel–Crafts acylation. Moreover, this reaction proceeds via an unprecedented Rh‐catalyzed oxidative ortho‐acylation of aryl ketone O‐methyl oximes with highly electron‐deficient aryl aldehydes followed by a direct addition of the second ortho C H bond to aldehydes in a one‐pot reaction, to generate two C C bonds simultaneously.