Palladium-Catalysed Synthesis and Transformation of Quinolones

Palladium-catalysed reactions have had a large impact on synthetic organic chemistry and have found many applications in target-oriented synthesis. Their widespread use in organic synthesis is due to the mild conditions associated with the reactions together with their tolerance of a wide range of functional groups. Moreover, these types of reactions allow the rapid construction of complex molecules through multiple bond-forming reactions in a single step, the so-called tandem processes. Pd-catalysed reactions have been applied to the synthesis of a large number of natural products and bioactive compounds, some of them of complex molecular structures. This review article aims to present an overview of the most important Pd-catalysed reactions employed in the synthesis and transformations of quinolin-2(1H)-ones and quinolin-4(1H)-ones. These compounds are widely recognized by their diverse bioactivity, being privileged structures in medicinal chemistry and useful structural moieties for the development of new drug candidates. Furthermore, they hold significant interest due to their host–guest chemistry; applications in chemical, biochemical and environmental analyses and use in the development of new synthetic methods. In some cases, the quinolone formation step cannot be ascribed to a claimed Pd-catalysed reaction but this reaction is crucial to get the appropriate substrate for cyclization into the quinolone. Herein we present and discuss different economical, efficient and selective synthetic strategies to access quinolone-type compounds.


Introduction
Quinolin-2(1H)-ones and the isomeric quinolin-4(1H)-ones are benzo-α-and benzo-γ-pyridones, respectively, since they are constituted by a αor γ-pyridone o-fused with a benzene ring ( Figure 1). The quinolone motif is widely distributed in nature, being particularly found in alkaloids of Rutaceae family but can also be produced by different animal and bacterial species [1,2]. These compounds are privileged scaffolds in medicinal chemistry and are ubiquitous substructures associated with relevant biologically active natural products. For instance, quinolin-2(1H)-ones were reported as antiulcer (e.g., rebamipide), antihistaminic (e.g., repirinast) [3] and anticancer (e.g., tipifarnib) [4] agents and have also demonstrated activity as antivirals [5], for instance as inhibitors of HIV-1 reverse transcriptase [6,7]. In addition, they are useful intermediates in organic synthesis. Quinolin-4(1H)-ones are well-known as antibiotics (e.g., fluoroquinolones) and exhibit excellent antimicrobial activity (e.g., [8]). Moreover quinolin-4(1H)-ones possess other interesting biological properties such as antimalarial [9] and antitumoral [10,11] activities, among others. Up to now several methods for the synthesis of quinolones have been reported in the literature but the most commonly used involve the condensation of anilines with β-ketoesters followed by cyclization to give quinolin-2(1H)-ones (Conrad-Limpach-Knorr synthesis) or quinolin-4(1H)-ones (Conrad-Limpach classical methods leading to the formation of the C3-C4 bond include the Friedlander synthesis, Camps modification and Niementowski reaction [12][13][14]. Most of these conventional methods often require harsh conditions, tedious workup and purification procedures, are regioselectivity compromised and the variety of substrates is limited. The diversity of the quinolone-containing structures encountered, as well as their biological and pharmaceutical relevance, have motivated research aimed at the development of new economical, efficient and selective synthetic strategies to access these compounds. Recently transition metal-catalysed (TM-catalysed) procedures for the synthesis of such compounds and further transformations have been developed providing increased tolerance toward functional groups and leading generally to higher reaction yields [15]. Many of these methods have proven to be the most powerful and are currently applied in target-or diversityoriented syntheses. Among TM-catalysed reactions, Pd-catalysed reactions, especially cross-coupling reactions, have found wide application in organic synthesis. The use of Pd-catalysts to allow the rapid construction of complex molecules through multiple bond-forming reactions in a single step, the socalled tandem process, became a powerful tool for synthetic organic chemists. Such processes reduce the steps in the synthesis of certain molecules; thus, being attractive from the viewpoint of developing environmentally benign and economical synthetic methods. This review article is an attempt to compile the most important Pd-catalysed reactions that have been applied in the synthesis and transformation of quinolin-2(1H)-ones and quinolin-4(1H)-ones in the period ranging from 1990-2017. When describing the developments in this research field, emphasis will be given to the reaction conditions, including the catalysts, ligands and bases, the reaction's scope, selectivity and in some cases to the mechanism.

Heck Reaction
In 1978, Heck and co-workers described for the first time the synthesis of quinolin-2(1H)-ones from vinylic substitution of 1,2-disubstituted olefins with 2-iodoanilines [16]. Reaction of 2iodoanilines 1 with dimethyl maleate 2 using Pd(OAc)2 as catalyst and Et3N as base, in acetonitrile at 100 °C, afforded as expected from previous reaction with 4-iodoaniline, the Z intermediate amino esters which in situ cyclize to quinolin-2(1H)-ones 3 in moderate to good yields (72,55 and 30% for R = H, Br and OH, respectively) (Scheme 1). However, with diethyl fumarate the E intermediate amino ester was expected and cyclization should not occur without first isomerizing, since the βcarboxymethyl group was far from the amino group, although quinolin-2(1H)-one 3 was isolated in 47% yield along with 20% of aniline. In this case, isomerization of the intermediate should occur fairly easily or the σ-bonded Pd intermediate cyclizes readily in this reaction.

Heck Reaction
In 1978, Heck and co-workers described for the first time the synthesis of quinolin-2(1H)-ones from vinylic substitution of 1,2-disubstituted olefins with 2-iodoanilines [16]. Reaction of 2-iodoanilines 1 with dimethyl maleate 2 using Pd(OAc) 2 as catalyst and Et 3 N as base, in acetonitrile at 100 • C, afforded as expected from previous reaction with 4-iodoaniline, the Z intermediate amino esters which in situ cyclize to quinolin-2(1H)-ones 3 in moderate to good yields (72,55 and 30% for R = H, Br and OH, respectively) (Scheme 1). However, with diethyl fumarate the E intermediate amino ester was expected and cyclization should not occur without first isomerizing, since the β-carboxymethyl group was far from the amino group, although quinolin-2(1H)-one 3 was isolated in 47% yield along with 20% of aniline. In this case, isomerization of the intermediate should occur fairly easily or the σ-bonded Pd intermediate cyclizes readily in this reaction.
The intramolecular Heck cyclization of N-(hetero)arylcarboxamides afforded tricyclic fused quinolone derivatives (Scheme 12) [28]. These compounds were prepared by treatment of the acyl chlorides, generated in situ from the commercially available pyrrole-, thiophene-and furan-2/3-carboxylic acids 36, with the appropriate 2-iodoanilines 1, followed by N-methylation of the N-(hetero)arylcarboxamides 37 to avoid N-Pd complexation. Intramolecular Heck cyclization of 38 at the positions 2 or 3 of the heterocyclic nucleus with Pd(PPh 3 ) 4 as catalyst and KOAc as base afforded the corresponding tricyclic fused quinolones 39 in moderate to high yields (Scheme 12).
The intramolecular Heck cyclization of N-(hetero)arylcarboxamides afforded tricyclic fused quinolone derivatives (Scheme 12) [28]. These compounds were prepared by treatment of the acyl chlorides, generated in situ from the commercially available pyrrole-, thiophene-and furan-2/3carboxylic acids 36, with the appropriate 2-iodoanilines 1, followed by N-methylation of the N-(hetero)arylcarboxamides 37 to avoid N-Pd complexation. Intramolecular Heck cyclization of 38 at the positions 2 or 3 of the heterocyclic nucleus with Pd(PPh3)4 as catalyst and KOAc as base afforded the corresponding tricyclic fused quinolones 39 in moderate to high yields (Scheme 12).

Carbonylative Annulation
Both 3-and 4-substituted quinolin-2(1H)-ones 48 and 49 were obtained by Pd-catalysed carbonylative annulation of terminal alkynes 47 with 2-iodoaniline derivatives 46, in the presence of carbon monoxide (CO), pyridine (Py) and Pd(OAc)2 (Scheme 15) [31]. Terminal alkynes bearing alkyl, phenyl, silyl, hydroxy, ester and cyano substituents gave quinolin-2(1H)-ones in moderate yields. Only the 3-substituted quinolin-2(1H)-ones 48 were obtained in the reaction with phenylacetylene and triethylsilylacetylene. Removal of the carbamate-protecting group by treating the crude reaction with 1 M of ethanolic NaOH is necessary to avoid the formation of a mixture of deprotected and protected quinolin-2(1H)-ones. Both 3-and 4-substituted quinolin-2(1H)-ones 48 and 49 were obtained in the reactions with terminal alkynes bearing long alkyl chains. An increase in the size of the substituent on the triple bond improves the regioselectivity. Furthermore, the ratio of isomers is around 4 to 1 when functionalized acetylenes are used compared to the 2.2 to 1 ratio obtained in most of the reactions with 1-hexyne. The formation of quinolin-2(1H)-ones and not quinolin-4(1H)-ones shows that the key step in this process is the insertion of the terminal alkyne into the carbon-Pd bond instead of undergoing a Sonogashira-type coupling [32,33]. The authors have conducted an isotope labelling experiment to unambiguously prove this reactivity pattern. Scheme 13. Synthesis of quinolin-2(1H)-ones 41d by intramolecular Heck cyclization of acrylamides 40 [29].

Sonogashira Reaction
Pd-catalysed coupling of ethyl N-(2-ethynyl)malonanilide 42 with aryl, heteroaryl, vinyl halides or vinyl triflates 43 gave derivatives 44, which upon intramolecular cyclization, under basic conditions, afforded 3,4-disubstituted quinolin-2(1H)-ones 45 (Scheme 14) [30]. The mechanism of this carbocyclization involves an intramolecular nucleophilic attack of the carbanion, generated from 44, on the carbon-carbon triple bond giving, after protonation, a six-membered ring methylidene intermediate that isomerizes to the quinolin-2(1H)-one 45. The success of this cyclization step is determined by the nature of the substituent in the acetylenic moiety. Good yields were obtained with aromatic rings bearing electron-withdrawing substituents (60-75%) while no quinolin-2(1H)-ones were obtained with electron-donating p-methoxyphenyl or butyl groups. Later, the same authors reported the synthesis of 3,4-disubstituted quinolin-2(1H)-ones 51 and 52 by a ligand free Pd-catalysed annulation of internal alkynes 50 with N-substituted 2-iodoanilines 46 in the presence of CO (Scheme 15) [34]. The type of the substituent on the nitrogen was fundamental to obtain quinolin-2(1H)-ones in high yields. Better yields were obtained using mild electron-withdrawing substituents as p-toluenesulfonyl, trifluoroacetyl and alkoxycarbonyl. The nitrogen substituent is lost during the progress of the reaction affording N-unsubstituted quinolin-2(1H)-ones, except for aminocarbonyl and ethoxycarbonyl groups that originated the corresponding protected quinolin-2(1H)-one in 7% and 11% isolated yields, respectively. A wide variety of internal alkynes 50, bearing alkyl, aryl, heteroaryl, hydroxy and alkoxy substituents, were effective in this reaction; however, unsymmetrical alkynes originated mixtures of regioisomers 51 and 52, with low regioselectivity, owing to the two possible modes of alkyne insertion into the aryl-Pd bond. Electrondeficient alkynes are very poor substrates for the carbonylative annulation. Electron-rich 2iodoanilines can react as annulating agents but when the substitution is para to the iodine the yield is lower. Carbonylative annulation of electron-poor 2-iodoanilines gives the corresponding quinolin-2(1H)-ones in lower yields than the parent system. Later, the same authors reported the synthesis of 3,4-disubstituted quinolin-2(1H)-ones 51 and 52 by a ligand free Pd-catalysed annulation of internal alkynes 50 with N-substituted 2-iodoanilines 46 in the presence of CO (Scheme 15) [34]. The type of the substituent on the nitrogen was fundamental to obtain quinolin-2(1H)-ones in high yields. Better yields were obtained using mild electron-withdrawing substituents as p-toluenesulfonyl, trifluoroacetyl and alkoxycarbonyl. The nitrogen substituent is lost during the progress of the reaction affording N-unsubstituted quinolin-2(1H)-ones, except for aminocarbonyl and ethoxycarbonyl groups that originated the corresponding protected quinolin-2(1H)-one in 7% and 11% isolated yields, respectively. A wide variety of internal alkynes 50, bearing alkyl, aryl, heteroaryl, hydroxy and alkoxy substituents, were effective in this reaction; however, unsymmetrical alkynes originated mixtures of regioisomers 51 and 52, with low regioselectivity, owing to the two possible modes of alkyne insertion into the aryl-Pd bond. Electron-deficient alkynes are very poor substrates for the carbonylative annulation. Electron-rich 2-iodoanilines can react as annulating agents but when the substitution is para to the iodine the yield is lower. Carbonylative annulation of electron-poor 2-iodoanilines gives the corresponding quinolin-2(1H)-ones in lower yields than the parent system.
Pd-catalysed carbonylative annulation of unprotected 2-iodoanilines 1 and terminal alkynes 47, using the commercially available molybdenum hexacarbonyl [Mo(CO) 6 ] as a convenient and solid CO source, also afforded 3-and 4-substituted quinolin-2(1H)-ones 48 and 49, the latter ones as minor products [Scheme 15, (iv)] [35]. The reactions were conducted at 160 • C for 30 min under microwave irradiation. Et 3 N was the best base in terms of yield and regioselectivity. Pd(OAc) 2 exhibited good catalytic activity whereas 1,2-bis(diphenylphosphino)ethane (dppe) and tetrahydrofuran (THF) were the best ligand and solvent choice for regioselectivity and yields. Different substituted 2-iodoanilines and alkyl alkynes were used without significant loss in reaction yield or efficiency. Aryl-substituted alkynes gave only the 3-substituted quinolin-2(1H)-one 48 although the yield was moderate. Neither internal alkynes nor N-protected 2-iodoanilines can be used in this carbonylative annulation.
Protected iodoanilines 53 reacted with internal alkenes 54 or alkynes 56 and Mo(CO) 6 , affording 3,4-disubstituted (dihydro)quinolin-2(1H)-ones 55 and 57 (Scheme 16) [36]. The reaction is ligand-free and avoids the problematic use of gaseous CO. In addition, the annulation reactions proceed with insertion of unsaturated compounds into the arylpalladium bond in preference to insertion of CO where no isomeric quinolones were observed. For instance, norbornene adds to the arylpalladium intermediate in a cis-exo manner followed by CO insertion and intramolecular amination (Scheme 16). The slow CO liberation during the reaction also provides an efficient pressure of the gas to promote the carbonylative reaction. This protocol merges three Heck, carbonylation and amination reactions to construct two C-C and one C-N bonds in one pot. It is compatible with various amino protecting groups, such as ethoxycarbonyl, tosyl, sulfonyl and acyl groups; however, deprotection occurred during the reaction and workup procedure, affording the free quinolin-2(1H)-one. Nonetheless, it is important to note that the yields are better when using N-protected anilines and depend on the protecting group. Reactions of N-substituted anilines with dipropyl acetylene, 4-octyne and 5-decyne afforded the annulation product in moderate to very good yields. Unfortunately, diphenylacetylene did not participate in the annulation reaction with o-iodoaniline; only traces of the desired product were obtained.  [36].
Following the work of Larock, Jia and co-workers developed a protocol for the efficient synthesis of 4,5-fused tricyclic quinolin-2(1H)-ones 63 by intramolecular carbonylative annulation of alkynetethered o-iodoanilines 62 (Scheme 18) [38]. The use of PPh3 as ligand was found to be crucial for this reaction although its role is not clear. For most of the substrates tested, the reaction afforded a mixture of the N-protected and free (NH) fused quinolin-2(1H)-ones in different ratios. This problem was overwhelmed by treatment of the crude products with 1 M ethanolic NaOH to completely hydrolyse the N-substituted product thus obtaining only the expected fused quinolin-2(1H)-one 63. The electronic effect of the aryl groups on the internal alkyne on the reactivity was not significant. In addition, substrates leading to 7-and 8-membered ring fused quinolin-2(1H)-ones gave the desired products in good yields and the o-methyl substituent on 2-iodoaniline was well tolerated.
In 1979, Ban and co-workers described the Pd-catalysed carbonylation of vinyl bromides bearing an internal amide group 64 [39]. In the presence of the catalytic system Pd(OAc)2 and PPh3, the (Z)isomer 64 of the vinyl bromide smoothly gave quinolin-2(1H)-one 65 with loss of the N-acetyl group (Scheme 19). In the same reaction conditions, the corresponding (E)-isomer gave only 7.7% yield of the same quinolin-2(1H)-one 65 because palladation occurs at the position of the halogen atom of the vinyl halide. Following the work of Larock, Jia and co-workers developed a protocol for the efficient synthesis of 4,5-fused tricyclic quinolin-2(1H)-ones 63 by intramolecular carbonylative annulation of alkyne-tethered o-iodoanilines 62 (Scheme 18) [38]. The use of PPh 3 as ligand was found to be crucial for this reaction although its role is not clear. For most of the substrates tested, the reaction afforded a mixture of the N-protected and free (NH) fused quinolin-2(1H)-ones in different ratios. This problem was overwhelmed by treatment of the crude products with 1 M ethanolic NaOH to completely hydrolyse the N-substituted product thus obtaining only the expected fused quinolin-2(1H)-one 63. The electronic effect of the aryl groups on the internal alkyne on the reactivity was not significant. In addition, substrates leading to 7-and 8-membered ring fused quinolin-2(1H)-ones gave the desired products in good yields and the o-methyl substituent on 2-iodoaniline was well tolerated.
The mechanism proposed for the formation of compounds 80 seems to be initiated by the oxidative addition of one of the bromoarenes in 79 to a catalytically active Pd(0) complex. Then desymmetrisation of the amide groups of the resulting Pd(II) complex 81 occurs affording palladacycle 82. The subsequent C-N bond-forming reductive elimination yields monocyclized compound 80′ with regeneration of the Pd catalyst. Then intramolecular N-arylation of 80' affords the expected spirobis[3,4-dihydroquinolin-2(1H)-one] 80. According to the authors, the enantioselectivity is determined in the first cyclization. They also confirmed that a kinetic resolution process is involved in the second cyclization (Scheme 25) [44]. The mechanism proposed for the formation of compounds 80 seems to be initiated by the oxidative addition of one of the bromoarenes in 79 to a catalytically active Pd(0) complex. Then desymmetrisation of the amide groups of the resulting Pd(II) complex 81 occurs affording palladacycle 82. The subsequent C-N bond-forming reductive elimination yields monocyclized compound 80 with regeneration of the Pd catalyst. Then intramolecular N-arylation of 80 affords the expected spirobis[3,4-dihydroquinolin-2(1H)-one] 80. According to the authors, the enantioselectivity is determined in the first cyclization. They also confirmed that a kinetic resolution process is involved in the second cyclization (Scheme 25) [44].

Intramolecular C-H Alkenylation
Pd(II)-catalysed selective 6-endo intramolecular C-H alkenylation of N-phenylacrylamides 83, in the conditions shown in Scheme 26, allows the construction of the quinolin-2(1H)-one core 84 [45]. In all cases, the quinolin-2(1H)-one 84 was the unique isolated product and the formation of the indolin-2-one, due to a 5-exo cyclization, was not detected. The reaction was efficient with an unsubstituted alkene and substitution on the 3-position of the acrylamide is well tolerated, leading to 4-substituted quinolin-2(1H)-ones. However, the presence of an ester or ketone moiety led to the expected product in low isolated yields, 10% and 22%, respectively. A better yield of 30% was achieved for the ketone but in the absence of Cu(OAc)2. 2,3-Disubstituted acrylamides can also be used leading to 3,4-

Intramolecular C-H Alkenylation
Pd(II)-catalysed selective 6-endo intramolecular C-H alkenylation of N-phenylacrylamides 83, in the conditions shown in Scheme 26, allows the construction of the quinolin-2(1H)-one core 84 [45]. In all cases, the quinolin-2(1H)-one 84 was the unique isolated product and the formation of the indolin-2-one, due to a 5-exo cyclization, was not detected. The reaction was efficient with an unsubstituted alkene and substitution on the 3-position of the acrylamide is well tolerated, leading to 4-substituted quinolin-2(1H)-ones. However, the presence of an ester or ketone moiety led to the expected product in low isolated yields, 10% and 22%, respectively. A better yield of 30% was achieved for the ketone but in the absence of Cu(OAc) 2 . 2,3-Disubstituted acrylamides can also be used leading to 3,4-disubstituted quinolin2(1H)-ones. N-demethylated acrylamides also gave the corresponding quinolin-2(1H)-ones but in lower yields. Although acetic acid is a good solvent, the reaction can also be performed in aqueous media at room temperature, using a 2% aqueous solution of polyoxyethanyl-α-tocopheryl sebacate (PTS) or even in water, with good yields but for a prolonged reaction time (24 h

Intramolecular C-H Alkenylation
Pd(II)-catalysed selective 6-endo intramolecular C-H alkenylation of N-phenylacrylamides 83, in the conditions shown in Scheme 26, allows the construction of the quinolin-2(1H)-one core 84 [45]. In all cases, the quinolin-2(1H)-one 84 was the unique isolated product and the formation of the indolin-2-one, due to a 5-exo cyclization, was not detected. The reaction was efficient with an unsubstituted alkene and substitution on the 3-position of the acrylamide is well tolerated, leading to 4-substituted quinolin-2(1H)-ones. However, the presence of an ester or ketone moiety led to the expected product in low isolated yields, 10% and 22%, respectively. A better yield of 30% was achieved for the ketone but in the absence of Cu(OAc)2. 2,3-Disubstituted acrylamides can also be used leading to 3,4disubstituted quinolin2(1H)-ones. N-demethylated acrylamides also gave the corresponding quinolin-2(1H)-ones but in lower yields. Although acetic acid is a good solvent, the reaction can also be performed in aqueous media at room temperature, using a 2% aqueous solution of polyoxyethanyl-α-tocopheryl sebacate (PTS) or even in water, with good yields but for a prolonged reaction time (24 h). Scheme 26. Synthesis of quinolin-2(1H)-ones 84 by selective 6-endo intramolecular C-H alkenylation of N-phenylacrylamides 83 [45].
The mechanism of this intramolecular cyclization seems to involve an electrophilic palladation of the aromatic ring to form an aryl-Pd(II) intermediate (Scheme 27). This arylpalladium would undergo a syn insertion into the activated alkene moiety in a 6-endo mode, followed by β-hydride elimination to afford the quinolone framework. Given the (E)-configuration of the starting alkenes, the subsequent syn β-hydride elimination would require the prior epimerization of the α-carbon through the formation of an O-Pd intermediate.
The mechanism of this intramolecular cyclization seems to involve an electrophilic palladation of the aromatic ring to form an aryl-Pd(II) intermediate (Scheme 27). This arylpalladium would undergo a syn insertion into the activated alkene moiety in a 6-endo mode, followed by β-hydride elimination to afford the quinolone framework. Given the (E)-configuration of the starting alkenes, the subsequent syn β-hydride elimination would require the prior epimerization of the α-carbon through the formation of an O-Pd intermediate.

Intramolecular Amidation of C(sp 2 )-H Bonds
Pd-catalysed amidation of halo aromatics substituted in the o-position by a carbonyl functional group or its equivalent 85 with primary or secondary amides 86 gave substituted quinolin-2(1H)-ones 87 (Scheme 28) [46]. Both aryl bromides and chlorides are effective in this reaction but aryl chlorides required longer reaction times than bromides (6 h versus 2 h). On the other hand, electron-rich aryl bromides afforded the product in moderate yield (47%). The reaction was not limited to o-halo aldehydes; enolizable methyl ketones, such as 2-bromoacetophenone, 2-bromobenzophenone, methyl 2-bromobenzoate, methyl 2-bromo-5-phenylbenzoate, 2-bromobenzonitrile also coupled with 2-phenylacetamide to give 4-substituted quinolin-2(1H)-one derivatives 88 in moderate to good yields (33-74%). Primary aryl and heterocyclic acetamides worked well with the exception of 2-pyridylacetamide that did not react in the reaction conditions presented in Scheme 28. With the secondary amide, N-methyl-2-phenylacetamide, the product was obtained in good yield (60%) however, neither the more sterically demanding N-isopropyl-2-phenylacetamide nor the N-arylamide N-phenyl-2-phenylacetamide was coupled with 2-bromobenzaldehyde using these conditions. Primary and secondary alkyl amides, such as propionamide and 2-cyclopropylacetamide, undergo coupling but failed the in situ cyclization; in addition, other attempts to cyclize the coupling products in several acidic or basic conditions failed. 2-Methoxyacetamide and N-methylpropionamide were coupled with 2-bromobenzaldehydes but also failed the cyclization in the coupling reaction conditions. However, they cyclized into the expected quinolin-2(1H)-ones, in low yields (51% and 32%, respectively), by the addition of NaO-t-Bu in t-BuOH. [45].

Intramolecular Amidation of C(sp 2 )-H Bonds
Pd-catalysed amidation of halo aromatics substituted in the o-position by a carbonyl functional group or its equivalent 85 with primary or secondary amides 86 gave substituted quinolin-2(1H)-ones 87 (Scheme 28) [46]. Both aryl bromides and chlorides are effective in this reaction but aryl chlorides required longer reaction times than bromides (6 h versus 2 h). On the other hand, electron-rich aryl bromides afforded the product in moderate yield (47%). The reaction was not limited to o-halo aldehydes; enolizable methyl ketones, such as 2-bromoacetophenone, 2-bromobenzophenone, methyl 2-bromobenzoate, methyl 2-bromo-5-phenylbenzoate, 2-bromobenzonitrile also coupled with 2-phenylacetamide to give 4-substituted quinolin-2(1H)-one derivatives 88 in moderate to good yields (33-74%). Primary aryl and heterocyclic acetamides worked well with the exception of 2pyridylacetamide that did not react in the reaction conditions presented in Scheme 28. With the secondary amide, N-methyl-2-phenylacetamide, the product was obtained in good yield (60%) however, neither the more sterically demanding N-isopropyl-2-phenylacetamide nor the Narylamide N-phenyl-2-phenylacetamide was coupled with 2-bromobenzaldehyde using these conditions. Primary and secondary alkyl amides, such as propionamide and 2-cyclopropylacetamide, undergo coupling but failed the in situ cyclization; in addition, other attempts to cyclize the coupling products in several acidic or basic conditions failed. 2-Methoxyacetamide and Nmethylpropionamide were coupled with 2-bromobenzaldehydes but also failed the cyclization in the coupling reaction conditions. However, they cyclized into the expected quinolin-2(1H)-ones, in low yields (51% and 32%, respectively), by the addition of NaO-t-Bu in t-BuOH. Pd-catalysed intramolecular amidation of N-substituted-3,3-diarylacrylamides 89 was efficiently performed in the presence of a catalytic amount of PdCl 2 and Cu(OAc) 2 under O 2 atmosphere, affording a range of diversely substituted 4-arylquinolin-2(1H)-ones 90 and 91 (Scheme 29) [47,48]. The cyclization of the 3,3-diarylacrylamides having tosyl, acetyl or a t-butyl group on the nitrogen atom of the amide moiety proceeded with concomitant loss of the protecting group, whereas the use of free amide or alkyl amides led to the product in poor yields. The benzene ring is also a suitable substituent on the nitrogen atom and, in this case, the reaction yield increases as the electron density of the benzene ring decreases, suggesting that the nucleophilicity of the nitrogen atom plays an important role in the process. This method is applicable to a wide range of symmetrical 3,3-diarylacrylamides (R 2 = R 3 ) possessing various functional groups on the benzene ring (Scheme 29). Unsymmetrical substrates (R 2 = R 3 ) having a cyano group at the p-position of the benzene ring yielded only one regioisomer. In the case of the m-cyano substituted compounds the (E)-isomer was much more reactive than the (Z)-isomer (Scheme 29).
suitable substituent on the nitrogen atom and, in this case, the reaction yield increases as the electron density of the benzene ring decreases, suggesting that the nucleophilicity of the nitrogen atom plays an important role in the process. This method is applicable to a wide range of symmetrical 3,3diarylacrylamides (R 2 = R 3 ) possessing various functional groups on the benzene ring (Scheme 29). Unsymmetrical substrates (R 2 ≠ R 3 ) having a cyano group at the p-position of the benzene ring yielded only one regioisomer. In the case of the m-cyano substituted compounds the (E)-isomer was much more reactive than the (Z)-isomer (Scheme 29). Scheme 29. Synthesis of 4-arylquinolin-2(1H)-ones 90, 90′ and 91 by Pd-catalysed intramolecular amidation of 3,3-diarylacrylamides 89 [47,48].
A tandem process consisting of two mechanistically independent sequential Pd(II)-catalysed reactions, the oxidative Heck reaction of cinnamamides 92 with arylboron compounds (Ar′-"B") followed by the intramolecular C-H amidation reaction, represented a facile and novel route to various substituted 4-arylquinolin-2(1H)-one derivatives (Scheme 30) [48,49]. The coupling of Nmethoxycinnamamide 92 with phenylboronic acid using a catalytic combination of Pd(OAc)2/1,10phenanthroline, Cu(TFA)2·nH2O (200 mol%) and Ag2O (100 mol%) in AcOH successfully delivered the expected quinolin-2(1H)-one 93. In this case, demethoxylation unexpectedly occurred during the reaction, resulting in the formation of N-free quinolin-2(1H)-one 93 in fairly good yield (60%). The use of increased amounts of Ag2O (e.g., 300 mol% or more) completely inhibited demethoxylation and resulted in the formation of quinolin-2(1H)-one 94 in 52-81% yield (Scheme 30). The best result was obtained when 800 mol% of Ag2O was employed, affording 94 in high yields (81%). During the process, the use of a large excess of re-oxidants may inhibit the undesired N-O bond cleavage in which palladium and/or copper salt(s) are involved. This tandem process is also applicable to the synthesis of quinolin-2(1H)-ones via the formation of symmetrical 3,3-diarylacrylamides [48,49]. Reactions of cinnamamides with a methyl group or a halogen atom at the p-position of the benzene ring proceeded efficiently (59-76%), whereas that of cinnamamide with a methoxy group at the same A tandem process consisting of two mechanistically independent sequential Pd(II)-catalysed reactions, the oxidative Heck reaction of cinnamamides 92 with arylboron compounds (Ar -"B") followed by the intramolecular C-H amidation reaction, represented a facile and novel route to various substituted 4-arylquinolin-2(1H)-one derivatives (Scheme 30) [48,49]. The coupling of N-methoxycinnamamide 92 with phenylboronic acid using a catalytic combination of Pd(OAc) 2 /1,10-phenanthroline, Cu(TFA) 2 ·nH 2 O (200 mol%) and Ag 2 O (100 mol%) in AcOH successfully delivered the expected quinolin-2(1H)-one 93. In this case, demethoxylation unexpectedly occurred during the reaction, resulting in the formation of N-free quinolin-2(1H)-one 93 in fairly good yield (60%). The use of increased amounts of Ag 2 O (e.g., 300 mol% or more) completely inhibited demethoxylation and resulted in the formation of quinolin-2(1H)-one 94 in 52-81% yield (Scheme 30). The best result was obtained when 800 mol% of Ag 2 O was employed, affording 94 in high yields (81%). During the process, the use of a large excess of re-oxidants may inhibit the undesired N-O bond cleavage in which palladium and/or copper salt(s) are involved. This tandem process is also applicable to the synthesis of quinolin-2(1H)-ones via the formation of symmetrical 3,3-diarylacrylamides [48,49]. Reactions of cinnamamides with a methyl group or a halogen atom at the p-position of the benzene ring proceeded efficiently (59-76%), whereas that of cinnamamide with a methoxy group at the same position, resulted in the formation of the corresponding quinolin-2(1H)-one 95 (R 1 = 4-OMe) in only 12% yield, along with the recovery of the starting material in 85% yield. For cinnamamides with a methyl group at the m-position of the benzene ring, C-H cyclization occurred at the less-hindered site; in contrast, the introduction of a methyl group at the o-position of the benzene ring did not result in the formation of the coupling or cyclized product (Scheme 30).

Intramolecular Hydroarylation of C-C Triple Bonds
Various aryl alkynanilides 99, prepared from the corresponding alkynoic acids 97 and anilines 98, undergo fast intramolecular reaction, at room temperature, in the presence of a catalytic amount of Pd(OAc)2 in a mixed solvent containing TFA, affording quinolin-2(1H)-ones 100 in very good yields (82-91%), with more than 1000 turnover numbers (TON) to Pd (Scheme 31) [50]. The methodology tolerated a number of functional groups such as Br and CHO. On the basis of isotope experiments, a possible mechanism involving ethynyl chelation-assisted electrophilic metalation of aromatic C-H bonds by in situ generated cationic Pd(II) species was proposed. The involvement of vinyl-cationic species was also suggested [50]. On the other hand, it was demonstrated that the

Intramolecular Hydroarylation of C-C Triple Bonds
Various aryl alkynanilides 99, prepared from the corresponding alkynoic acids 97 and anilines 98, undergo fast intramolecular reaction, at room temperature, in the presence of a catalytic amount of Pd(OAc) 2 in a mixed solvent containing TFA, affording quinolin-2(1H)-ones 100 in very good yields (82-91%), with more than 1000 turnover numbers (TON) to Pd (Scheme 31) [50]. The methodology tolerated a number of functional groups such as Br and CHO. On the basis of isotope experiments, a possible mechanism involving ethynyl chelation-assisted electrophilic metalation of aromatic C-H bonds by in situ generated cationic Pd(II) species was proposed. The involvement of vinyl-cationic species was also suggested [50]. On the other hand, it was demonstrated that the intermolecular reaction of alkynoic acids 97 and anilines 98 did not afford quinolin-2(1H)-ones 100, presumably because the amino groups in anilines are converted in TFA to ammonium ions which act as electron-withdrawing groups and consequently deactivate the aromatic rings (Scheme 31) [50].

Other Reactions
Benzothieno[2,3-c]quinolin-6(5H)-ones 106 were prepared by one-pot three steps Pd-catalysed borylation, Suzuki coupling and amidation (lactamization), starting from o-haloanilines 104 and alkyl 3-bromobenzo[b]tiophene-2-carboxylates 105 (Scheme 33) [52]. The amidation reaction probably occurs in the Suzuki coupling intermediate, through a nucleophilic attack of the nitrogen atom of the amine on the carbonyl of the ester group, with loss of methanol or ethanol, giving the corresponding tetracyclic quinolone. The use of an electron-rich sterically hindered ligand, such as 2-(dicyclohexylphosphanyl)biphenyl and Ba(OH)2·8H2O as base, is convenient for sterically hindered substrates. In addition, the borylation should be performed in the component bearing an o-electrondonating group with the other Suzuki coupling component having an o-electron-withdrawing group. This method allows the use of two bromo components conveniently substituted as starting materials. The in situ Pd-catalysed borylation avoids the preparation and isolation of boronic acids or esters and occurs with atom economy. The borylation occurred either using o-bromo or o-chloroanilines enhancing the scope of the reaction.

Other Reactions
Benzothieno[2,3-c]quinolin-6(5H)-ones 106 were prepared by one-pot three steps Pd-catalysed borylation, Suzuki coupling and amidation (lactamization), starting from o-haloanilines 104 and alkyl 3-bromobenzo[b]tiophene-2-carboxylates 105 (Scheme 33) [52]. The amidation reaction probably occurs in the Suzuki coupling intermediate, through a nucleophilic attack of the nitrogen atom of the amine on the carbonyl of the ester group, with loss of methanol or ethanol, giving the corresponding tetracyclic quinolone. The use of an electron-rich sterically hindered ligand, such as 2-(dicyclohexylphosphanyl)biphenyl and Ba(OH) 2 ·8H 2 O as base, is convenient for sterically hindered substrates. In addition, the borylation should be performed in the component bearing an o-electron-donating group with the other Suzuki coupling component having an o-electron-withdrawing group. This method allows the use of two bromo components conveniently substituted as starting materials. The in situ Pd-catalysed borylation avoids the preparation and isolation of boronic acids or esters and occurs with atom economy. The borylation occurred either using o-bromo or o-chloroanilines enhancing the scope of the reaction. Scheme 32. Synthesis of 4-substituted quinolin-2(1H)-ones 103 and 103′ by Pd-catalysed [3 + 3] annulation between diarylamines 101 and α,β-unsaturated acids 102 [51]. Scheme 33. Synthesis of benzothieno[2,3-c]quinolin-6(5H)-ones 106 by one-pot three steps Pdcatalysed borylation, Suzuki coupling and amidation [52].
Liu and co-workers reported a concise and general strategy for the synthesis of quinolin-2(1H)ones 112 by a one-pot catalysed cascade that includes successive ammonolysis, C-H bond activation and cyclization reactions, using simple anilines 110 as substrates (Scheme 35) [54]. Under the optimized reaction conditions, a wide range of quinolin-2(1H)-ones 112 was prepared in good to excellent yields. Anilines containing electron-donating, electron-withdrawing groups or halogens as substituents are effective in the reaction. For m-toluidine and 3-trifluoromethylaniline, C−H bond activation occurred solely at p-position to the methyl or trifluoromethyl group to provide the corresponding products in 96% and 53% yields, respectively. However, the reactions with anilines bearing trifluoromethyl, nitro or carboxyl groups at the p-position, did not give the desired quinolin-2(1H)-ones. When using cinnamates, the electronic character of the substituents on the aryl ring significantly influenced the efficiency of the cyclization. Cinnamates with electron-donating groups on the aryl moiety displayed higher reactivity than those with electron-withdrawing groups. No product was obtained when using ethyl (2E)-3-(2-trifluoromethylphenyl)propenoate but heterocyclic substituents containing propenoate and alkyl-substituted propenoates, such as ethyl crotonate and ethyl methacrylate, afforded the desired quinolin-2(1H)-ones 112 in low to moderate yields (37-68%). The utility of this method was demonstrated by a formal synthesis of Tipifarnib, an orally active inhibitor of farnesylprotein transferase with potent activity against neoplastic diseases, antineoplastic activity in solid tumours, such as breast cancer and in haematological malignancies found in leukaemia (Scheme 35). A plausible mechanism for the formation of 108 starts with the oxidative addition of aryl halide 107 to Pd(0) followed by intramolecular ligand exchange to give a four-membered azapalladacycle. Further Pd rearrangement accompanied with cyclopropane ring opening gave the energetically favourable seven-membered azapalladacycle [53]. Finally, reductive elimination produces 2-methoxy-3,4-dihydroquinoline 108, with concomitant regeneration of the reactive Pd(0) species. The hydrolysis of 2-methoxy-3,4-dihydroquinolines 108 furnishes the 3,4-dihydroquinolin-2(1H)-ones 109 [53].
Liu and co-workers reported a concise and general strategy for the synthesis of quinolin-2(1H)-ones 112 by a one-pot catalysed cascade that includes successive ammonolysis, C-H bond activation and cyclization reactions, using simple anilines 110 as substrates (Scheme 35) [54]. Under the optimized reaction conditions, a wide range of quinolin-2(1H)-ones 112 was prepared in good to excellent yields. Anilines containing electron-donating, electron-withdrawing groups or halogens as substituents are effective in the reaction. For m-toluidine and 3-trifluoromethylaniline, C−H bond activation occurred solely at p-position to the methyl or trifluoromethyl group to provide the corresponding products in 96% and 53% yields, respectively. However, the reactions with anilines bearing trifluoromethyl, nitro or carboxyl groups at the p-position, did not give the desired quinolin-2(1H)-ones. When using cinnamates, the electronic character of the substituents on the aryl ring significantly influenced the efficiency of the cyclization. Cinnamates with electron-donating groups on the aryl moiety displayed higher reactivity than those with electron-withdrawing groups. No product was obtained when using ethyl (2E)-3-(2-trifluoromethylphenyl)propenoate but heterocyclic substituents containing propenoate and alkyl-substituted propenoates, such as ethyl crotonate and ethyl methacrylate, afforded the desired quinolin-2(1H)-ones 112 in low to moderate yields (37-68%). The utility of this method was demonstrated by a formal synthesis of Tipifarnib, an orally active inhibitor of farnesylprotein transferase with potent activity against neoplastic diseases, antineoplastic activity in solid tumours, such as breast cancer and in haematological malignancies found in leukaemia (Scheme 35).  3,3-Disubstituted-3,4-dihydroquinolin-2(1H)-ones 115 were synthesized from easily available ohalogenated acetylide derivatives 114 by the Pd-catalysed oxidative-addition-initiated activation and arylation of inert C(sp 3 )-H bonds (Scheme 37) [55]. Pd(OAc)2 and P(o-tol)3 were used as the catalyst and ligand, respectively, to improve the efficiency of the reaction. Polar solvents, such as N-methyl-2-pyrrolidone (NMP) gave the best results. The use of PivOH (Piv = pivaloyl) as additive is not essential; however the product was obtained in a slightly better yield in the presence of this additive.  3,3-Disubstituted-3,4-dihydroquinolin-2(1H)-ones 115 were synthesized from easily available ohalogenated acetylide derivatives 114 by the Pd-catalysed oxidative-addition-initiated activation and arylation of inert C(sp 3 )-H bonds (Scheme 37) [55]. Pd(OAc)2 and P(o-tol)3 were used as the catalyst and ligand, respectively, to improve the efficiency of the reaction. Polar solvents, such as N-methyl-2-pyrrolidone (NMP) gave the best results. The use of PivOH (Piv = pivaloyl) as additive is not essential; however the product was obtained in a slightly better yield in the presence of this additive. 3,3-Disubstituted-3,4-dihydroquinolin-2(1H)-ones 115 were synthesized from easily available o-halogenated acetylide derivatives 114 by the Pd-catalysed oxidative-addition-initiated activation and arylation of inert C(sp 3 )-H bonds (Scheme 37) [55]. Pd(OAc) 2 and P(o-tol) 3 were used as the catalyst and ligand, respectively, to improve the efficiency of the reaction. Polar solvents, such as N-methyl-2-pyrrolidone (NMP) gave the best results. The use of PivOH (Piv = pivaloyl) as additive is not essential; however the product was obtained in a slightly better yield in the presence of this additive. Regarding the reactivity of the C-X bonds, chloro-substituted substrates showed a low reactivity and iodo-substituted compounds also gave a lower yield than bromo-substituted ones. When there are substituents at 3-or 6-position, the cyclized products were obtained in low yields, which indicate that steric hindrance plays a key role in influencing the reaction efficiency. Furthermore, some sensitive functional groups, such as nitro, ester and acyl groups were not tolerated. Nonetheless, by changing the acyl group from the pivaloyl group to a 1-methylcyclopentanecarbonyl or a 1-methylcyclohexanecarbonyl group, it is possible to synthesize polycyclic compounds with spiro-centres. However, in the presence of a C(sp 2 )-H bond located at a suitable position for intramolecular C-H activation, the desired product of the inert C(sp 3 )-H activation could not be observed. A further advantage of this reaction is that it could be performed in air. Mechanistic studies showed that a relatively rare seven-membered palladacycle is a key intermediate of the catalytic cycle [55]. Regarding the reactivity of the C-X bonds, chloro-substituted substrates showed a low reactivity and iodo-substituted compounds also gave a lower yield than bromo-substituted ones. When there are substituents at 3-or 6-position, the cyclized products were obtained in low yields, which indicate that steric hindrance plays a key role in influencing the reaction efficiency. Furthermore, some sensitive functional groups, such as nitro, ester and acyl groups were not tolerated. Nonetheless, by changing the acyl group from the pivaloyl group to a 1-methylcyclopentanecarbonyl or a 1methylcyclohexanecarbonyl group, it is possible to synthesize polycyclic compounds with spirocentres. However, in the presence of a C(sp 2 )-H bond located at a suitable position for intramolecular C-H activation, the desired product of the inert C(sp 3 )-H activation could not be observed. A further advantage of this reaction is that it could be performed in air. Mechanistic studies showed that a relatively rare seven-membered palladacycle is a key intermediate of the catalytic cycle [55]. A wide range of α-carbamoyl ketene dithioacetals 116 readily reacted with arynes 117 to selectively afford functionalized quinolin-2(1H)-ones 118 in high yields under neutral reaction conditions by a C-S activation/aryne insertion/intramolecular coupling sequence catalysed by Pd(OAc)2 (Scheme 38) [56]. The use of dppf, as a ligand, dramatically improved the aryne annulation and both palladium and the ligand play a key role in the insertion of benzyne into a C-S bond. Other phosphine-containing ligands, such as PCy3 (Cy = cyclohexyl), PPh3 and Xantphos, were found to be less efficient than dppf for this annulation. Additionally, either decreasing the amount of the catalyst or lowering the reaction temperature resulted in unsatisfactory yields of 118a (R 1 = Me, R 2 = 4-NO2C6H4, R 3 = Bn, R 4 = H). The reaction scope is quite general, however for dithioacetals which do not have a substituent at the α-position (R 2 = H) the reaction was more complex and the quinolin-2(1H)-one 118 (R 2 = H) was obtained in a low yield (27%), along with quinolin-2(1H)-one 118 (R 2 = Ph) that results from the first α-phenylation of the dithioacetal (R 2 = H) with benzyne by a Pd-catalysed α-C-H activation and subsequent annulation with the benzyne. Finally, the reaction was found to be sensitive to substrates 116 bearing a free NH2; in this case, the obtained product was only detected by NMR and HRMS-ESI studies of the reaction mixture after 18 h of reaction time. When the unsymmetrical aryne 4-methoxy-2-(trimethylsilyl)-phenyl trifluoromethanesulfonate was employed, a mixture of two isomeric quinolin-2(1H)-ones was obtained [56]. A wide range of α-carbamoyl ketene dithioacetals 116 readily reacted with arynes 117 to selectively afford functionalized quinolin-2(1H)-ones 118 in high yields under neutral reaction conditions by a C-S activation/aryne insertion/intramolecular coupling sequence catalysed by Pd(OAc) 2 (Scheme 38) [56]. The use of dppf, as a ligand, dramatically improved the aryne annulation and both palladium and the ligand play a key role in the insertion of benzyne into a C-S bond. Other phosphine-containing ligands, such as PCy 3 (Cy = cyclohexyl), PPh 3 and Xantphos, were found to be less efficient than dppf for this annulation. Additionally, either decreasing the amount of the catalyst or lowering the reaction temperature resulted in unsatisfactory yields of 118a (R 1 = Me, R 2 = 4-NO 2 C 6 H 4 , R 3 = Bn, R 4 = H). The reaction scope is quite general, however for dithioacetals which do not have a substituent at the α-position (R 2 = H) the reaction was more complex and the quinolin-2(1H)-one 118 (R 2 = H) was obtained in a low yield (27%), along with quinolin-2(1H)-one 118 (R 2 = Ph) that results from the first α-phenylation of the dithioacetal (R 2 = H) with benzyne by a Pd-catalysed α-C-H activation and subsequent annulation with the benzyne. Finally, the reaction was found to be sensitive to substrates 116 bearing a free NH 2 ; in this case, the obtained product was only detected by NMR and HRMS-ESI studies of the reaction mixture after 18 h of reaction time. When the unsymmetrical aryne 4-methoxy-2-(trimethylsilyl)-phenyl trifluoromethanesulfonate was employed, a mixture of two isomeric quinolin-2(1H)-ones was obtained [56].
The Pd-catalysed oxidative annulation of electron-deficient acrylamides 119 with benzyne precursors 120, in the presence of Pd(OAc)2, Cu(OAc)2 and CsF, in a mixture of dioxane and DMSO as solvent at 80 °C, allowed the formation of quinolin-2(1H)-one 121 in good yields (Scheme 39) [57]. Pd(PPh3)4 can also be employed but the product is generated in lower yield. Tetrabutylammonium bromide (TBAB) was found to be an important additive leading to highly improved yields. Acrylamides 119 bearing alkyl or aromatic substituents at α-position are good substrates in the reaction with benzyne. Cyclic substrates also react efficiently to give the expected fused-quinolin-2(1H)-ones 121 in moderate to good yields (55-74%) but cinnamide and crotonyl amide did not react. Substituted arynes bearing both electron-donating and electron-withdrawing substituents reacted with acrylamide 119: R 1 = Ph, R 2 = H, generating the corresponding quinolin-2(1H)-ones 121 in low to moderate yield (35-61%); with the asymmetric aryne, a 1:1 mixture of regioisomers was obtained. The methoxy group on the nitrogen atom is a very important protecting group. It was easily removed by NaH to give free quinolin-2(1H)-one 121 in 93% yield. The oxidative annulation of an Nmethylacrylamide with benzyne gave the corresponding quinolin-2(1H)-one in only 25% yield under the same reaction conditions. Although two possible reaction pathways for the oxidative annulation are possible [57], the most probable one involves the N-H activation of acrylamide 119 followed by aminopalladation of intermediate 122 to benzyne originating the palladium intermediate 123, which went through a Hecktype reaction, insertion to the electron-deficient double bond and subsequent β-hydrogen elimination, producing the expected quinolin-2(1H)-one 121 (Scheme 40).
Pd-catalysed intermolecular aminocarbonylation/intramolecular amidation cascade sequences were employed to efficiently and selectively convert a range of 2-(2-haloalkenyl)aryl halides 124 to the corresponding quinolin-2(1H)-ones 126 (Scheme 41) [58]. In the presence of Pd2(dba)3 and Cs2CO3 a variety of ligands, such as P(i-Pr)2 127, diphosphine dppp 128 and P(t-Bu)3 129, efficiently delivered quinolin-2(1H)-ones 126 in reasonable yields. Alkyl amines and p-methoxybenzylamine were suitable N-nucleophiles for this reaction. With allylamine, the reaction was performed at 50 °C for 2 h before heating at 100 °C. With O-phenylethanolamine CO atmosphere had to be removed after 3 h of reaction in the standard conditions. The use of p-anisidine required Xantphos as ligand and afforded the N-arylquinolone in only 33% yield.
The Pd-catalysed oxidative annulation of electron-deficient acrylamides 119 with benzyne precursors 120, in the presence of Pd(OAc) 2 , Cu(OAc) 2 and CsF, in a mixture of dioxane and DMSO as solvent at 80 • C, allowed the formation of quinolin-2(1H)-one 121 in good yields (Scheme 39) [57]. Pd(PPh 3 ) 4 can also be employed but the product is generated in lower yield. Tetrabutylammonium bromide (TBAB) was found to be an important additive leading to highly improved yields. Acrylamides 119 bearing alkyl or aromatic substituents at α-position are good substrates in the reaction with benzyne. Cyclic substrates also react efficiently to give the expected fused-quinolin-2(1H)-ones 121 in moderate to good yields (55-74%) but cinnamide and crotonyl amide did not react. Substituted arynes bearing both electron-donating and electron-withdrawing substituents reacted with acrylamide 119: R 1 = Ph, R 2 = H, generating the corresponding quinolin-2(1H)-ones 121 in low to moderate yield (35-61%); with the asymmetric aryne, a 1:1 mixture of regioisomers was obtained. The methoxy group on the nitrogen atom is a very important protecting group. It was easily removed by NaH to give free quinolin-2(1H)-one 121 in 93% yield. The oxidative annulation of an N-methylacrylamide with benzyne gave the corresponding quinolin-2(1H)-one in only 25% yield under the same reaction conditions. Although two possible reaction pathways for the oxidative annulation are possible [57], the most probable one involves the N-H activation of acrylamide 119 followed by aminopalladation of intermediate 122 to benzyne originating the palladium intermediate 123, which went through a Heck-type reaction, insertion to the electron-deficient double bond and subsequent β-hydrogen elimination, producing the expected quinolin-2(1H)-one 121 (Scheme 40). Scheme 39. Synthesis of quinolones 121 by Pd-oxidative annulation between acrylamides 119 and arynes 120 [57].
A better yield was obtained following a discrete two-step process involving isolation of the intermediate N-arylamide and then re-subjection of the amide to ring closure conditions. Xantphos was employed as the ligand for both steps and allowed the isolation of the corresponding quinolin-2(1H)-one in 65% yield for the two steps. A range of electron-donating and electron-withdrawing Pd-catalysed intermolecular aminocarbonylation/intramolecular amidation cascade sequences were employed to efficiently and selectively convert a range of 2-(2-haloalkenyl)aryl halides 124 to the corresponding quinolin-2(1H)-ones 126 (Scheme 41) [58]. In the presence of Pd 2 (dba) 3 and Cs 2 CO 3 a variety of ligands, such as P(i-Pr) 2 127, diphosphine dppp 128 and P(t-Bu) 3 129, efficiently delivered quinolin-2(1H)-ones 126 in reasonable yields. Alkyl amines and p-methoxybenzylamine were suitable N-nucleophiles for this reaction. With allylamine, the reaction was performed at 50 • C for 2 h before heating at 100 • C. With O-phenylethanolamine CO atmosphere had to be removed after 3 h of reaction in the standard conditions. The use of p-anisidine required Xantphos as ligand and afforded the N-arylquinolone in only 33% yield. Scheme 39. Synthesis of quinolones 121 by Pd-oxidative annulation between acrylamides 119 and arynes 120 [57].
A better yield was obtained following a discrete two-step process involving isolation of the intermediate N-arylamide and then re-subjection of the amide to ring closure conditions. Xantphos was employed as the ligand for both steps and allowed the isolation of the corresponding quinolin-2(1H)-one in 65% yield for the two steps. A range of electron-donating and electron-withdrawing Scheme 41. Synthesis of quinolin-2(1H)-ones 126 by Pd-catalysed aminocarbonylation/ intramolecular amidation cascade sequence starting from 2-(2-haloalkenyl)aryl halides 124 [58].
A better yield was obtained following a discrete two-step process involving isolation of the intermediate N-arylamide and then re-subjection of the amide to ring closure conditions. Xantphos was employed as the ligand for both steps and allowed the isolation of the corresponding quinolin-2(1H)-one in 65% yield for the two steps. A range of electron-donating and electron-withdrawing substituents are tolerated in the aryl ring of the dihalide substrate. This method also allows the synthesis of quinolin-2(1H)-ones having aryl or styryl substituents at C-3 position.
Isoquinoline derivatives can be obtained using the same conditions but delaying the introduction of the CO atmosphere [58]. A limitation of this approach is the requirement to employ a sterically demanding N-nucleophile, as the use of less hindered coupling partners results in competitive indole formation.
substituents are tolerated in the aryl ring of the dihalide substrate. This method also allows the synthesis of quinolin-2(1H)-ones having aryl or styryl substituents at C-3 position.
Isoquinoline derivatives can be obtained using the same conditions but delaying the introduction of the CO atmosphere [58]. A limitation of this approach is the requirement to employ a sterically demanding N-nucleophile, as the use of less hindered coupling partners results in competitive indole formation.
The Pd-catalysed carbonylative coupling of 2-haloanilines 139 with terminal arylacetylenes 47, initially reported by Torii and Kalinin [32,33,62], appears to be the most versatile method for the synthesis of 2-substituted quinolin-4(1H)-ones 141. The desired compounds were obtained in good yields using either PdCl 2 (PPh 3 ) 2 or PdCl 2 (dppf) and an excess of Et 2 NH which acts as solvent and base and plays a key role in the cyclization step (Scheme 44). 2-Iodoanilines are preferred to 2-bromoanilines and react both as a free base and in the hydrochloride form although the latter in lower yield [62]. The reaction of arylacetylenes generally gave better yields than aliphatic acetylenes, which may be due to the acidity of the acetylene proton. Functional groups, such as thiophenyl, acetal, tetrahydropyran (THP), ester, keto and ether, tolerate the reaction conditions. When the nitrogen of the anilines has a substituent, decrease of the nucleophilicity retards the cyclization. In fact, reaction with alkylated aniline, under the same reaction conditions, led to the corresponding enamine 142 as main product (52%) and only 20% of quinolin-4(1H)-one 141 was obtained, although subsequent treatment of the enamine with sodium hydride in THF led to quinolin-4(1H)-one 141 quantitatively [32,33]. Decrease of CO pressure or temperature drops the reaction yield. The Pd-catalysed carbonylative coupling of 2-haloanilines 139 with terminal arylacetylenes 47, initially reported by Torii and Kalinin [32,33], appears to be the most versatile method for the synthesis of 2-substituted quinolin-4(1H)-ones 141. The desired compounds were obtained in good yields using either PdCl2(PPh3)2 or PdCl2(dppf) and an excess of Et2NH which acts as solvent and base and plays a key role in the cyclization step (Scheme 44). 2-Iodoanilines are preferred to 2bromoanilines and react both as a free base and in the hydrochloride form although the latter in lower yield [62]. The reaction of arylacetylenes generally gave better yields than aliphatic acetylenes, which may be due to the acidity of the acetylene proton. Functional groups, such as thiophenyl, acetal, tetrahydropyran (THP), ester, keto and ether, tolerate the reaction conditions. When the nitrogen of the anilines has a substituent, decrease of the nucleophilicity retards the cyclization. In fact, reaction with alkylated aniline, under the same reaction conditions, led to the corresponding enamine 142 as main product (52%) and only 20% of quinolin-4(1H)-one 141 was obtained, although subsequent treatment of the enamine with sodium hydride in THF led to quinolin-4(1H)-one 141 quantitatively [32,33]. Decrease of CO pressure or temperature drops the reaction yield. Pd-catalysed carbonylative Sonogashira coupling of 2-iodo-5-methoxyaniline 144 with thiazolylacetylene 143 afforded quinolin-4(1H)-one 146, a key substructure of the hepatitis C virus NS3 protease inhibitor BILN2061 (Scheme 45) [63]. This approach may also provide a practical and general access to polysubstituted quinolones related to structure 146. Pd-catalysed carbonylative Sonogashira coupling of 2-iodo-5-methoxyaniline 144 with thiazolylacetylene 143 afforded quinolin-4(1H)-one 146, a key substructure of the hepatitis C virus NS3 protease inhibitor BILN2061 (Scheme 45) [63]. This approach may also provide a practical and general access to polysubstituted quinolones related to structure 146. Scheme 44. Synthesis of 2-substituted quinolin-4(1H)-ones 141 by Pd-catalysed carbonylative coupling of 2-haloanilines 139 with terminal acetylenes 47 [32,33,62].
Pd-catalysed carbonylative Sonogashira coupling of 2-iodo-5-methoxyaniline 144 with thiazolylacetylene 143 afforded quinolin-4(1H)-one 146, a key substructure of the hepatitis C virus NS3 protease inhibitor BILN2061 (Scheme 45) [63]. This approach may also provide a practical and general access to polysubstituted quinolones related to structure 146. Pd-catalysed carbonylative Sonogashira coupling between 2-iodoanilines 1, alkynes 47 and CO (5 bar), using Et 3 N as the base in the presence of PdCl 2 (dppp) [dppp = 1,3-bis(diphenylphosphino)propane] as catalyst selectively afforded intermediate 147. In a second step, an organocatalyzed cyclization occurs after the addition of Et 2 NH to give the expected quinolin-4(1H)-ones 148 in high selectivity and yields [Scheme 46, (i)] [64]. Although successful, this one-pot two-step multi-catalysis method suffers from the need of homogenous catalysts, which are tedious to remove and could result in high Pd and ligand contamination of the final products that is not acceptable when dealing with animal and human health. The use of heterogeneous catalysts associating the [Pd(PNP)]@SBA-15 catalyst to a grafted amine catalyst as [NH 2 ]@SBA-3 in a one-pot tandem [Pd/amine] mode allowed, for example, the selective synthesis of 2-phenylquinolin-4(1H)-one in a suitable 61% isolated yield [Scheme 46, (ii)] [65]. This approach resulted in a strong decrease of Pd-contamination in the final products as only 3 to 5 ppm of Pd was found in the crude quinolin-4(1H)-ones, while 40 ppm was measured when using homogeneous catalytic system. The overall reaction time was also reduced from 7 to 3 days (in the same reaction conditions).
Recycling of the {[Pd(PNP)]@SBA-15/[NH 2 ]@SBA-3} catalyst mixture was successful for 3 runs [66]. Pd-catalysed carbonylative Sonogashira coupling between 2-iodoanilines 1, alkynes 47 and CO (5 bar), using Et3N as the base in the presence of PdCl2(dppp) [dppp = 1,3bis(diphenylphosphino)propane] as catalyst selectively afforded intermediate 147. In a second step, an organocatalyzed cyclization occurs after the addition of Et2NH to give the expected quinolin-4(1H)-ones 148 in high selectivity and yields [Scheme 46, (i)] [64]. Although successful, this one-pot two-step multi-catalysis method suffers from the need of homogenous catalysts, which are tedious to remove and could result in high Pd and ligand contamination of the final products that is not acceptable when dealing with animal and human health. The use of heterogeneous catalysts associating the [Pd(PNP)]@SBA-15 catalyst to a grafted amine catalyst as [NH2]@SBA-3 in a one-pot tandem [Pd/amine] mode allowed, for example, the selective synthesis of 2-phenylquinolin-4(1H)one in a suitable 61% isolated yield [Scheme 46, (ii)] [65]. This approach resulted in a strong decrease of Pd-contamination in the final products as only 3 to 5 ppm of Pd was found in the crude quinolin-4(1H)-ones, while 40 ppm was measured when using homogeneous catalytic system. The overall reaction time was also reduced from 7 to 3 days (in the same reaction conditions Two different protocols were developed for the Sonogashira coupling of 2-iodoanilines 1 with alkynes 47 and cyclization toward functionalized quinolin-4(1H)-ones 149 (Scheme 47) [67]. In the first protocol (Method A), quinolin-4(1H)-ones 149 were obtained after 20 min of microwave (MW) heating at 120 °C using Mo(CO)6, Pd2(dba)3 with an excess dppf, as ligand and Cs2CO3 in diethylamine. The reaction scope is quite general, however, when using 2-iodo-4-nitroaniline, the corresponding product was obtained in low yield, due to the thermally induced nitro group reduction by Mo(CO)6. To overcome this limitation, a second protocol (Method B) was developed using milder conditions, extending the scope of the reaction to reduction-prone or other sensitive groups, such as nitro and bromo substituents. The coupling reaction was performed at room temperature using a different catalytic system, Mo(CO)6, Pd(OAc)2, [HP(t-Bu)3]BF4 followed by the addition of diethylamine to promote the cyclization of the arylalkynone intermediate 150. The formation of quinolin-2(1H)-ones was never detected using these two methods, on contrary to the previous observations of Chen and co-workers [35], who reported a Mo(CO)6 protocol for the formation quinolin-2(1H)-ones starting from 1 and 47. Two different protocols were developed for the Sonogashira coupling of 2-iodoanilines 1 with alkynes 47 and cyclization toward functionalized quinolin-4(1H)-ones 149 (Scheme 47) [67]. In the first protocol (Method A), quinolin-4(1H)-ones 149 were obtained after 20 min of microwave (MW) heating at 120 • C using Mo(CO) 6 , Pd 2 (dba) 3 with an excess dppf, as ligand and Cs 2 CO 3 in diethylamine. The reaction scope is quite general, however, when using 2-iodo-4-nitroaniline, the corresponding product was obtained in low yield, due to the thermally induced nitro group reduction by Mo(CO) 6 . To overcome this limitation, a second protocol (Method B) was developed using milder conditions, extending the scope of the reaction to reduction-prone or other sensitive groups, such as nitro and bromo substituents. The coupling reaction was performed at room temperature using a different catalytic system, Mo(CO) 6 , Pd(OAc) 2 , [HP(t-Bu) 3 ]BF 4 followed by the addition of diethylamine to promote the cyclization of the arylalkynone intermediate 150.
The formation of quinolin-2(1H)-ones was never detected using these two methods, on contrary to the previous observations of Chen and co-workers [35], who reported a Mo(CO) 6 protocol for the formation quinolin-2(1H)-ones starting from 1 and 47.

Buchwald-Hartwig Reaction
An efficient Pd-catalysed tandem amination approach, starting from easily accessible 2-haloaryl acetylenic ketones 151 and primary amines 125, involving a sequential double C-N bond formation, furnished functionalized quinolin-4(1H)-ones 152 in good to excellent yields in one step (Scheme 48) [68]. The reaction of 151 (X = Br, R 1 =H) with aniline in the presence of Pd(PPh3)4 in 1,4-dioxane, using K2CO3 as base, gave the corresponding quinolin-4(1H)-one 152 in 71% yield. A similar result was obtained using the PdCl2(dppf)-CH2Cl2 complex as catalyst. Improvements were made using Pd2(dba)3-CHCl3 as catalyst combined with Xantphos or dppp, however PPh3 proved to be the best ligand affording quinolin-4(1H)-one 152 in 84% yield. A range of commercially available aryl amines can be employed to give the corresponding products in moderate to good yields (61-93%). Even those with active amino or hydroxy groups remain intact under the reaction conditions. However, with aliphatic amines such as butylamine the product was obtained in moderate yield (42%). This reaction is also compatible with different types of ynones substituted with aryl and pyridyl groups.
Two pathways were proposed for this reaction (Scheme 49), which may involve either oxidative addition of Pd (0)

Buchwald-Hartwig Reaction
An efficient Pd-catalysed tandem amination approach, starting from easily accessible 2-haloaryl acetylenic ketones 151 and primary amines 125, involving a sequential double C-N bond formation, furnished functionalized quinolin-4(1H)-ones 152 in good to excellent yields in one step (Scheme 48) [68]. The reaction of 151 (X = Br, R 1 =H) with aniline in the presence of Pd(PPh 3 ) 4 in 1,4-dioxane, using K 2 CO 3 as base, gave the corresponding quinolin-4(1H)-one 152 in 71% yield. A similar result was obtained using the PdCl 2 (dppf)-CH 2 Cl 2 complex as catalyst. Improvements were made using Pd 2 (dba) 3 -CHCl 3 as catalyst combined with Xantphos or dppp, however PPh 3 proved to be the best ligand affording quinolin-4(1H)-one 152 in 84% yield. A range of commercially available aryl amines can be employed to give the corresponding products in moderate to good yields (61-93%). Even those with active amino or hydroxy groups remain intact under the reaction conditions. However, with aliphatic amines such as butylamine the product was obtained in moderate yield (42%). This reaction is also compatible with different types of ynones substituted with aryl and pyridyl groups.

Buchwald-Hartwig Reaction
An efficient Pd-catalysed tandem amination approach, starting from easily accessible 2-haloaryl acetylenic ketones 151 and primary amines 125, involving a sequential double C-N bond formation, furnished functionalized quinolin-4(1H)-ones 152 in good to excellent yields in one step (Scheme 48) [68]. The reaction of 151 (X = Br, R 1 =H) with aniline in the presence of Pd(PPh3)4 in 1,4-dioxane, using K2CO3 as base, gave the corresponding quinolin-4(1H)-one 152 in 71% yield. A similar result was obtained using the PdCl2(dppf)-CH2Cl2 complex as catalyst. Improvements were made using Pd2(dba)3-CHCl3 as catalyst combined with Xantphos or dppp, however PPh3 proved to be the best ligand affording quinolin-4(1H)-one 152 in 84% yield. A range of commercially available aryl amines can be employed to give the corresponding products in moderate to good yields (61-93%). Even those with active amino or hydroxy groups remain intact under the reaction conditions. However, with aliphatic amines such as butylamine the product was obtained in moderate yield (42%). This reaction is also compatible with different types of ynones substituted with aryl and pyridyl groups.
Two pathways were proposed for this reaction (Scheme 49), which may involve either oxidative addition of Pd (0)  Both pathways will go through intermediates IV and V, followed by reductive elimination of Pd(0) to give the desired quinolin-4(1H)-one 152. Based on some experiments conducted by Xu and Zhao [68], path A could be the major pathway to afford the target quinolone.  [68], path A could be the major pathway to afford the target quinolone. An efficient Pd-catalysed tandem amination protocol for the synthesis of 1,2-disubstituted quinolin-4(1H)-ones 154 was developed starting from easily accessible chalcones 153 and primary amines 125, in which the Pd-catalyst [Pd(OAc)2] plays a dual role, namely, in the Buchwald-Hartwig coupling and catalytic dehydrogenation (Scheme 50) [69]. Pd2(dba)3 that was a good catalyst in the Pd-catalysed tandem amination of 2-haloaryl acetylenic ketones 151 and primary amines 125 [68] was less effective than Pd(OAc)2 in this transformation (55% and 74%, respectively). The procedure using PPh3 as a ligand in refluxing anhydrous 1,4-dioxane and K2CO3 as base was efficient with aromatic, heteroaromatic and aliphatic amines. Arylamines containing electron-donating groups gave higher yields (79-87%) than those with electron-withdrawing groups (54-78%) and aliphatic amines gave the expected quinolin-4(1H)-ones 154 in slightly lower yields (45-52%). Different functional groups (R 1 and R 2 ) of chalcones 153 were all compatible with the reaction conditions. Due to the low oxidative addition reactivity of the C-Cl bond, 2-chloro-substituted chalcones gave quinolin-4(1H)-ones 154 in lower yield than the corresponding bromo-derivatives, even upon raised temperature.
(24% and 37%, respectively) [Scheme 53, (i)]. Carbonylative heterocyclization of other functionalized enamines 165 resulted in the successful formation of the desired products 166 in 82% and 87% yield; furthermore, the hydrolysis of lactone 166 may provide other intriguing quinolin-4(1H)-one carboxylic acids [72]. This method is of practical importance because of the wide choice of the group R 3 in addition to the fact that the benzene ring may carry a diverse number of substituents. Under similar conditions but using CO at atmospheric pressure, Stanforth and co-workers reported the synthesis of three 2-trifluoromethylated quinolin-4(1H)-ones in 54-77% yield [Scheme 53, (ii)] [73,74].  [75,76]. Formation of the compound 168 is quite intriguing and it was described as arising from some sort of rearrangement, probably via intermediate formation of a benzoxazine derivative. A reasonable mechanistic hypothesis was proposed by the authors but requires further investigation [45,75,76]. The nature of the substituent was found to be crucial for the product formation. In the case of an unsubstituted urea 167 quinolin-4(1H)-one 168 was the only isolated reaction product; but when it is substituted, no quinolin-4(1H)-one was obtained [75]. Pd-catalysed cyclization-alkoxycarbonylation of 1-[(2-trimethylsilyl-ethynyl)phenyl]urea 167 using Pd/C-Bu4NI as catalyst in the presence of KF, for the in situ deprotection, gave quinolin-4(1H)one 168 (Scheme 54) [75,76]. Formation of the compound 168 is quite intriguing and it was described as arising from some sort of rearrangement, probably via intermediate formation of a benzoxazine derivative. A reasonable mechanistic hypothesis was proposed by the authors but requires further investigation [45,75,76]. The nature of the substituent was found to be crucial for the product formation. In the case of an unsubstituted urea 167 quinolin-4(1H)-one 168 was the only isolated reaction product; but when it is substituted, no quinolin-4(1H)-one was obtained [75]. aroylquinolin-4(1H)-one derivative 171 is obtained with an N-(2-iodoaryl)-β-enaminone containing a bromine substituent in the aniline moiety. The synthesis of 2-substituted-3-aroylquinolin-4(1H)-ones 171 is also possible without isolation of the enaminone intermediate by adding Pd2(dba)3, XPhos, Cs2CO3, MeCN and CO (20 atm) to the crude mixture derived from the reaction of 2-iodoanilines 1 with α,β-ynones 169 after evaporation of the volatile materials. Under these conditions 171a (R 1 = H, Ar 1 = Ar 2 = Ph) was isolated in 61% overall yield. Highly functionalized 2,3-dihydroquinolin-4(1H)-ones 173 were obtained in one step, with moderate to good yields, by Pd-catalysed intermolecular cyclocarbonylation of 2-iodoanilines 1 with diethyl ethoxycarbonylbutendienoate 172 (Scheme 56) [78]. The method involves a Michael addition and subsequent carbonylation reactions using the catalytic system of Pd 2 (dba) 3 /2-(di-t-butylphosphino)biphenyl in MeCN at 80 • C under 500 psi of CO. Solvents like CH 2 Cl 2 or THF promote the formation of the Michael addition product 174, in more than 80% yield, being the unique reaction product since no carbonylation occurs. In general, better yields were obtained with electron-donating phosphines, such as trialkylphosphines and dialkylarylphosphines; however, 2-(di-t-butylphosphino)biphenyl was the better ligand. Xantphos behaved differently promoting the formation of 175 much more selectively than when using any other ligands. The reaction is sensitive to the electronic nature of the substituents at the p-position relatively to the iodide group. Highly electron-donating or electron-withdrawing groups, such as methoxy and chlorine, afforded 173 in lower yields (39% and 26%, respectively). Additionally, substituents have influence on the rate of the carbonylation and Michael addition steps and both can take place independently. Thus, a favourable balance of the rate between these two reactions is important to achieve successful results. In the reaction of 1 with a tetrasubstituted olefin the initial Michael addition cannot take place, probably due to steric effects and therefore no product was isolated. Other types of Michael acceptors 172c, 172d and 172e were tested leading to unsatisfactory yields, even after a brief screening (of phosphines and bases) to optimize the reaction conditions (14-35%). reaction product since no carbonylation occurs. In general, better yields were obtained with electrondonating phosphines, such as trialkylphosphines and dialkylarylphosphines; however, 2-(di-tbutylphosphino)biphenyl was the better ligand. Xantphos behaved differently promoting the formation of 175 much more selectively than when using any other ligands. The reaction is sensitive to the electronic nature of the substituents at the p-position relatively to the iodide group. Highly electron-donating or electron-withdrawing groups, such as methoxy and chlorine, afforded 173 in lower yields (39% and 26%, respectively). Additionally, substituents have influence on the rate of the carbonylation and Michael addition steps and both can take place independently. Thus, a favourable balance of the rate between these two reactions is important to achieve successful results. In the reaction of 1 with a tetrasubstituted olefin the initial Michael addition cannot take place, probably due to steric effects and therefore no product was isolated. Other types of Michael acceptors 172c, 172d and 172e were tested leading to unsatisfactory yields, even after a brief screening (of phosphines and bases) to optimize the reaction conditions (14-35%). Quinolin-4(1H)-ones 177 were obtained by a Pd(0)-catalysed termolecular queuing process involving oxidative addition to aryl iodide 176, followed by carbonylation, allene insertion and capture of the resulting п-allyl-Pd(II) species by an internal N-nucleophile [79]. CO at atmospheric pressure was used in contrast to Alper′s similar reported cascades [80], which were performed at high pressures of CO (20 atm). Under optimal conditions, using allene (1 atm) and CO (1 atm), a (3 + 1 + 2)-cycloaddition reaction of 2-iodo-1-tosylaniline occurred giving quinolin-4(1H)-ones 177 in good yields (55-99%) (Scheme 58). Substituents are tolerated on both the allene and the aryl iodide allowing access to a variety of heterocycles with s-cis-enone moieties.
In the first step of the catalytic cycle, the Pd(0) catalyst undergoes oxidative addition to the aryl iodide 176 bond followed by coordination and insertion of CO. Then addition of acyl-Pd(II) intermediate I to the allene at the central carbon atom originated a п-allyl-Pd(II) species II which undergoes nucleophilic attack by the internal nucleophile to give the enone product 177 (Scheme 59) [79]. These authors also described the one-pot quinolin-4(1H)-one synthesis-Michael addition starting from 2-iodo-1-tosylaniline 176, CO (1 atm) and allene (1atm) in toluene at 45 °C during 48 h. CO was released before the addition of the nucleophile and subsequent Michael addition completed after further 24 h (Scheme 60) [79]. Both aliphatic and heteroaromatic N-nucleophiles were effective and in the case of 1,2,4-triazole only the 1-substituted triazole was observed. As the obtained Michael adducts were sensitive to retro-Michael addition, their reduction with LiAlH4 was performed without prior isolation, obtaining the corresponding γ-amino alcohols 178 as single stereoisomers. Scheme 57. Probable reaction mechanism for the formation of quinolin-4(1H)-ones 173 [78].
In the first step of the catalytic cycle, the Pd(0) catalyst undergoes oxidative addition to the aryl iodide 176 bond followed by coordination and insertion of CO. Then addition of acyl-Pd(II) intermediate I to the allene at the central carbon atom originated a п-allyl-Pd(II) species II which undergoes nucleophilic attack by the internal nucleophile to give the enone product 177 (Scheme 59) [79]. These authors also described the one-pot quinolin-4(1H)-one synthesis-Michael addition starting from 2-iodo-1-tosylaniline 176, CO (1 atm) and allene (1atm) in toluene at 45 °C during 48 h. CO was released before the addition of the nucleophile and subsequent Michael addition completed after further 24 h (Scheme 60) [79]. Both aliphatic and heteroaromatic N-nucleophiles were effective and in the case of 1,2,4-triazole only the 1-substituted triazole was observed. As the obtained Michael adducts were sensitive to retro-Michael addition, their reduction with LiAlH4 was performed without prior isolation, obtaining the corresponding γ-amino alcohols 178 as single stereoisomers. In the first step of the catalytic cycle, the Pd(0) catalyst undergoes oxidative addition to the aryl iodide 176 bond followed by coordination and insertion of CO. Then addition of acyl-Pd(II) intermediate I to the allene at the central carbon atom originated a п-allyl-Pd(II) species II which undergoes nucleophilic attack by the internal nucleophile to give the enone product 177 (Scheme 59) [79]. These authors also described the one-pot quinolin-4(1H)-one synthesis-Michael addition starting from 2-iodo-1-tosylaniline 176, CO (1 atm) and allene (1atm) in toluene at 45 • C during 48 h. CO was released before the addition of the nucleophile and subsequent Michael addition completed after further 24 h (Scheme 60) [79]. Both aliphatic and heteroaromatic N-nucleophiles were effective and in the case of 1,2,4-triazole only the 1-substituted triazole was observed. As the obtained Michael adducts were sensitive to retro-Michael addition, their reduction with LiAlH 4 was performed without prior isolation, obtaining the corresponding γ-amino alcohols 178 as single stereoisomers.

Oxidative Carbonylation
Ley and co-workers synthesized quinolin-4(1H)-ones 182 via Pd-catalysed oxidative carbonylation starting from simple and commercially available amines 179 and ketones 180 using CO at atmospheric pressure (Scheme 61) [81]. First, an imine 181 is formed from ketone and amine by dehydration condensation. Then, enamine derived from imine/enamine isomerization, undergoes electrophilic attack by Pd(II) to form an intermediate which undergoes intramolecular C−H activation and CO insertion. Subsequent reductive elimination affords the final product and releases Pd(0), which is oxidized by copper and O2 to regenerate Pd(II) and complete the catalytic cycle [81]. From different palladium salts, Pd(dba)2 was found to be the best option and the use of Xantphos as a ligand improves the product yield. CuBr(Me2S), PhCO2Na and KI are necessary for the reaction which could also proceed smoothly to give the desired product under nonexplosive conditions (CO/O2 = 15/1). For m-substituted anilines 179 the reaction with acetophenones gave the desired products in moderate to good yields but with poor selectivity. However, this protocol provides a straightforward route to access useful quinolin-4(1H)-ones from inexpensive chemicals. As a wide range of functional groups is well tolerated, various ketones, heterocyclic ketones and amines are workable substrates that can be employed to generate quinolin-4(1H)-ones in good yields. Scheme 59. Proposed reaction mechanism for the formation of quinolin-4(1H)-ones 177 [79].

Oxidative Carbonylation
Ley and co-workers synthesized quinolin-4(1H)-ones 182 via Pd-catalysed oxidative carbonylation starting from simple and commercially available amines 179 and ketones 180 using CO at atmospheric pressure (Scheme 61) [81]. First, an imine 181 is formed from ketone and amine by dehydration condensation. Then, enamine derived from imine/enamine isomerization, undergoes electrophilic attack by Pd(II) to form an intermediate which undergoes intramolecular C−H activation and CO insertion. Subsequent reductive elimination affords the final product and releases Pd(0), which is oxidized by copper and O2 to regenerate Pd(II) and complete the catalytic cycle [81]. From different palladium salts, Pd(dba)2 was found to be the best option and the use of Xantphos as a ligand improves the product yield. CuBr(Me2S), PhCO2Na and KI are necessary for the reaction which could also proceed smoothly to give the desired product under nonexplosive conditions (CO/O2 = 15/1). For m-substituted anilines 179 the reaction with acetophenones gave the desired products in moderate to good yields but with poor selectivity. However, this protocol provides a straightforward route to access useful quinolin-4(1H)-ones from inexpensive chemicals. As a wide range of functional groups is well tolerated, various ketones, heterocyclic ketones and amines are workable substrates that can be employed to generate quinolin-4(1H)-ones in good yields.

Oxidative Carbonylation
Ley and co-workers synthesized quinolin-4(1H)-ones 182 via Pd-catalysed oxidative carbonylation starting from simple and commercially available amines 179 and ketones 180 using CO at atmospheric pressure (Scheme 61) [81]. First, an imine 181 is formed from ketone and amine by dehydration condensation. Then, enamine derived from imine/enamine isomerization, undergoes electrophilic attack by Pd(II) to form an intermediate which undergoes intramolecular C−H activation and CO insertion. Subsequent reductive elimination affords the final product and releases Pd(0), which is oxidized by copper and O 2 to regenerate Pd(II) and complete the catalytic cycle [81]. From different palladium salts, Pd(dba) 2 was found to be the best option and the use of Xantphos as a ligand improves the product yield. CuBr(Me 2 S), PhCO 2 Na and KI are necessary for the reaction which could also proceed smoothly to give the desired product under nonexplosive conditions (CO/O 2 = 15/1). For m-substituted anilines 179 the reaction with acetophenones gave the desired products in moderate to good yields but with poor selectivity. However, this protocol provides a straightforward route to access useful quinolin-4(1H)-ones from inexpensive chemicals. As a wide range of functional groups is well tolerated, various ketones, heterocyclic ketones and amines are workable substrates that can be employed to generate quinolin-4(1H)-ones in good yields.
could also proceed smoothly to give the desired product under nonexplosive conditions (CO/O2 = 15/1). For m-substituted anilines 179 the reaction with acetophenones gave the desired products in moderate to good yields but with poor selectivity. However, this protocol provides a straightforward route to access useful quinolin-4(1H)-ones from inexpensive chemicals. As a wide range of functional groups is well tolerated, various ketones, heterocyclic ketones and amines are workable substrates that can be employed to generate quinolin-4(1H)-ones in good yields.
The regioselective Pd-catalysed intramolecular N-arylation of (Z)-enamine 186 afforded quinolin-4(1H)-one 187 in 88% yield, which was further reduced to the corresponding 2,3dihydroquinolin-4(1H)-one 188 (Scheme 63) [83]. Pd-catalysed allylic amination-thiazolium salt-catalysed Stetter reaction between 2-aminobenzaldehydes 189 and allylic acetates 190 is an interesting method to prepare 3-substituted 2,3-dihydroquinolin-4(1H)-ones 192 (Scheme 64) [84,85]. The key to the success of this method is the compatibility of the second catalysis with the conditions of the first Pd-catalysis. Under optimized conditions, the one-pot sequential two-step multi-catalytic cascade process afforded 2,3-dihydroquinolin-4(1H)-ones 192 in excellent yields (94-99%). This procedure tolerates 2-aminobenzaldehydes 189 bearing electron-donating and electron-withdrawing substituents on the aromatic ring, although, in contrast to that of γ-acetoxy-α,β-unsaturated esters 190 (R 2 = CO 2 Et, CO 2 t-Bu) the reaction did not proceed for γ-acetoxy-α,β-unsaturated nitrile 190 (R 2  Pd(0)-catalysed intramolecular coupling of β-(2-iodoanilino)esters 193 afforded several 2,3dihydroquinolin-4(1H)-ones 194 in moderate to good yields (Scheme 65) [86]. The use of Pd(PPh3)4 as the catalyst and Cs2CO3 as base in THF resulted exclusively in the reduction product 195. In contrast, using K3PO4 as base in combination with Et3N and toluene led to an increase in the yield of dihydroquinolin-4(1H)-ones 194. These compounds 194 resulted from the nucleophilic substitution at the alkoxycarbonyl group. Substituents on the aromatic ring have little effect on the carbopalladation reaction evidencing that the nucleophilicity of the aryl-Pd species does not appear to be affected by the electronic properties of the substituent. The low yield for the product derived from 193 (R 1 = CO2Me) is mainly a consequence of an increase in the rate of the competitive retro-Michael fragmentation of the β-aminoester. Benzyl ester counterpart of 193 (R 4 = Bn) can also be used as substrate; however, the desired product is formed in better yields when using methyl ester (R 4 = Me) (50% and 65%, respectively). The reaction of amino esters 193 without α-hydrogen atoms to the carbonyl group proceeded smoothly to give exclusively the corresponding dihydroquinolin-4(1H)ones 194 in high yields (79-88%). On the other hand, no competition between nucleophilic attack at the carbonyl group and α-arylation was observed in the reactions of amino esters 193 which contain α-hydrogen atoms to the carbonyl group; however, dihydroquinolin-4(1H)-ones 194 (35-67%) were obtained together with the reduction products 195 (25-45%).  4 as the catalyst and Cs 2 CO 3 as base in THF resulted exclusively in the reduction product 195. In contrast, using K 3 PO 4 as base in combination with Et 3 N and toluene led to an increase in the yield of dihydroquinolin-4(1H)-ones 194. These compounds 194 resulted from the nucleophilic substitution at the alkoxycarbonyl group. Substituents on the aromatic ring have little effect on the carbopalladation reaction evidencing that the nucleophilicity of the aryl-Pd species does not appear to be affected by the electronic properties of the substituent. The low yield for the product derived from 193 (R 1 = CO 2 Me) is mainly a consequence of an increase in the rate of the competitive retro-Michael fragmentation of the β-aminoester. Benzyl ester counterpart of 193 (R 4 = Bn) can also be used as substrate; however, the desired product is formed in better yields when using methyl ester (R 4 = Me) (50% and 65%, respectively). The reaction of amino esters 193 without α-hydrogen atoms to the carbonyl group proceeded smoothly to give exclusively the corresponding dihydroquinolin-4(1H)-ones 194 in high yields (79-88%). On the other hand, no competition between nucleophilic attack at the carbonyl group and α-arylation was observed in the reactions of amino esters 193 which contain α-hydrogen atoms to the carbonyl group; however, dihydroquinolin-4(1H)-ones 194 (35-67%) were obtained together with the reduction products 195 (25-45%).
The intramolecular Heck reaction of the benzylallylquinolin-2(1H)-one precursor 207 originated a benzoxocine-fused quinolin-2(1H)-one 208 (Scheme 70) [91]. The reaction led to the regioselective formation of the 8-exo cyclization product 208 and no 9-endo product was observed in this case. Majumdar and co-workers reported a Pd-catalysed intramolecular Heck reaction of inactivated allylic quinolin-2(1H)-ones 209 that led to the formation of quinolin-2(1H)-one annulated benzoazocines 210 (Scheme 71) [92]. The intramolecular Heck reaction afforded exclusively the endocyclic product 210 in good yields. Once exclusively cyclization via the 8-exo mode is unusual, in this case, it was suggested that the formation of the endo-cyclic products may occur via two possible pathways; the 8-exo mode of cyclization followed by double-bond isomerization, or, alternatively, a double-bond isomerization prior to the Heck reaction leading to the subsequent 8-endo-Heck cyclization (Scheme 71) [92]. Majumdar and co-workers reported a Pd-catalysed intramolecular Heck reaction of inactivated allylic quinolin-2(1H)-ones 209 that led to the formation of quinolin-2(1H)-one annulated benzoazocines 210 (Scheme 71) [92]. The intramolecular Heck reaction afforded exclusively the endo-cyclic product 210 in good yields. Once exclusively cyclization via the 8-exo mode is unusual, in this case, it was suggested that the formation of the endo-cyclic products may occur via two possible pathways; the 8-exo mode of cyclization followed by double-bond isomerization, or, alternatively, a double-bond isomerization prior to the Heck reaction leading to the subsequent 8-endo-Heck cyclization (Scheme 71) [92]. Later, the same authors described the synthesis of quinolin-2(1H)-one annulated benzazocinones 212 by applying the same methodology to inactivated allylic quinolin-2(1H)-ones 211 (Scheme 72) [93]. In this case, the optimal reaction conditions required Pd(PPh3)4 as the catalyst. This highly regioselective ligand-free Heck coupling reaction leads exclusively to the expected 8-exo-Heck product 212, in good yields, without any contamination of the 9-endo-Heck or 8-exo-isomerized product. The formation of the 8-exo-Heck product is favoured because of the lower steric and transannular interactions. These authors have also prepared two quinolin-2(1H)-one annulated benzazoninones 214 starting from inactivated allylic quinolin-2(1H)-ones 213 (Scheme 72) [94]. The Heck reaction proceeded in reasonably good yields with shorter reaction times and only the product corresponding to the 9-exo mode of cyclization was obtained. Later, the same authors described the synthesis of quinolin-2(1H)-one annulated benzazocinones 212 by applying the same methodology to inactivated allylic quinolin-2(1H)-ones 211 (Scheme 72) [93]. In this case, the optimal reaction conditions required Pd(PPh 3 ) 4 as the catalyst. This highly regioselective ligand-free Heck coupling reaction leads exclusively to the expected 8-exo-Heck product 212, in good yields, without any contamination of the 9-endo-Heck or 8-exo-isomerized product. The formation of the 8-exo-Heck product is favoured because of the lower steric and transannular interactions. These authors have also prepared two quinolin-2(1H)-one annulated benzazoninones 214 starting from inactivated allylic quinolin-2(1H)-ones 213 (Scheme 72) [94]. The Heck reaction proceeded in reasonably good yields with shorter reaction times and only the product corresponding to the 9-exo mode of cyclization was obtained.

Sonogashira Reaction
Sequential coupling and cyclization reactions of aryl halides with (trimethylsilyl)acetylene with concurrent elimination of the trimethylsilyl (TMS) substituent furnished pyrrolo[3,2-f ]quinolin-7(6H)-ones 246 in excellent yields (Scheme 82) [108]. Acetylenic amines possessing an electron-donating group on the nitrogen atom also underwent Cu(I)-catalysed cyclization. Quinolones 243 were prepared from commercially available quinolines [109,110], then brominated and the resulting bromo-derivatives 244 were transformed into the required precursors for heteroannulation 245 by a Sonogashira coupling with (trimethylsilyl)acetylene using PdCl 2 (PPh 3 ) 2 as catalyst and CuI as the co-catalyst in THF/DMF mixed solvent containing Et 3 N. The reactions were optimized by smoothly heating the reaction in a sealed tube. Heteroannulation of the acetylenic amines to give 246 was achieved by refluxing the precursors 245 in DMF in the presence of 50 mol% of CuI. Another work reported the synthesis of acetylenic amines 245 and 247 by Sonogashira coupling of the corresponding 6-amino-5-bromoquinolin-2(1H)-ones 244 with (trimethylsilyl)acetylene or phenylacetylene, respectively. Both reactions were performed using PdCl 2 (PPh 3 ) 2 as catalyst and CuI as co-catalyst, although in slightly different experimental conditions (Scheme 82) [111].
The reaction was performed using molybdenum hexacarbonyl as a solid source of CO and Herrmann's palladacycle in combination with Fu s salt [(t-Bu) 3 PH.BF 4 ] as a catalyst system, in acetonitrile at 170 • C for 25 min. affording the expected amide 280 in 61% yield (Scheme 88) [88,89].

Other Reactions
Quinolin-2(1H)-ones 283 were functionalized at the 3-position through an intermolecular C-H alkenylation reaction with acrylates or acrylamide, in the presence of Pd(OAc)2 and AgOAc as oxidant, leading to the corresponding 3-alkenyl-4-substituted-quinolin-2(1H)-ones 284 in good yields and with complete regio-and stereoselectivity, even with 4-unsubstituted quinolin-2(1H)-ones (Scheme 90) [45]. Quinolin-2(1H)-one-based diaryl methane derivatives 292 and 293 were prepared via basic alumina supported Pd-catalysed cross-coupling of halogenated quinolones 287-290 (X = Cl, Br, I) with freshly prepared benzyl indium organometallic reagent 291, using microwave heating (Scheme 92) [118]. Only 0.5 mol% of Pd(PPh3)4 with basic alumina could afford high yield of product just in 10 min. Increase of the reaction time did not alter the product yield. No addition of base from outside is required to promote the catalytic reaction in basic alumina, which itself acts as the base during the course of the reaction, whereas neutral alumina or silica gels are very ineffective in absence of base. When the reaction was performed using an oil bath at 120 °C low yield of product was achieved even after overnight heating. Basic alumina can be reused after calcinations at 150 °C for 5 h (after washing with water and acetone) and could be recycled at least 3-4 times with minimum loss on its activity. The procedure offers a broad synthetic route for the construction of new polynuclear heteroaromatic systems having potential biological activity.

Other Reactions
Quinolin-2(1H)-ones 283 were functionalized at the 3-position through an intermolecular C-H alkenylation reaction with acrylates or acrylamide, in the presence of Pd(OAc)2 and AgOAc as oxidant, leading to the corresponding 3-alkenyl-4-substituted-quinolin-2(1H)-ones 284 in good yields and with complete regio-and stereoselectivity, even with 4-unsubstituted quinolin-2(1H)-ones (Scheme 90) [45]. Quinolin-2(1H)-one-based diaryl methane derivatives 292 and 293 were prepared via basic alumina supported Pd-catalysed cross-coupling of halogenated quinolones 287-290 (X = Cl, Br, I) with freshly prepared benzyl indium organometallic reagent 291, using microwave heating (Scheme 92) [118]. Only 0.5 mol% of Pd(PPh3)4 with basic alumina could afford high yield of product just in 10 min. Increase of the reaction time did not alter the product yield. No addition of base from outside is required to promote the catalytic reaction in basic alumina, which itself acts as the base during the course of the reaction, whereas neutral alumina or silica gels are very ineffective in absence of base. When the reaction was performed using an oil bath at 120 °C low yield of product was achieved even after overnight heating. Basic alumina can be reused after calcinations at 150 °C for 5 h (after washing with water and acetone) and could be recycled at least 3-4 times with minimum loss on its activity. The procedure offers a broad synthetic route for the construction of new polynuclear heteroaromatic systems having potential biological activity. Quinolin-2(1H)-one-based diaryl methane derivatives 292 and 293 were prepared via basic alumina supported Pd-catalysed cross-coupling of halogenated quinolones 287-290 (X = Cl, Br, I) with freshly prepared benzyl indium organometallic reagent 291, using microwave heating (Scheme 92) [118]. Only 0.5 mol% of Pd(PPh 3 ) 4 with basic alumina could afford high yield of product just in 10 min. Increase of the reaction time did not alter the product yield. No addition of base from outside is required to promote the catalytic reaction in basic alumina, which itself acts as the base during the course of the reaction, whereas neutral alumina or silica gels are very ineffective in absence of base. When the reaction was performed using an oil bath at 120 • C low yield of product was achieved even after overnight heating. Basic alumina can be reused after calcinations at 150 • C for 5 h (after washing with water and acetone) and could be recycled at least 3-4 times with minimum loss on its activity. The procedure offers a broad synthetic route for the construction of new polynuclear heteroaromatic systems having potential biological activity.

Heck Reaction
The  [120,121], in aqueous media, using Pd(OAc)2 as catalyst and TBAB as phase transfer catalyst in the presence of an inorganic base [122]. Butyl acrylate was also used as a coupling partner to give a different 3-substituted quinolin-4(1H)-one 298 (Scheme 93) [122]. This methodology is environmentally friendly, due to the use of water as solvent and there is no need for costly and toxic phosphine ligands. Yields were dependent on the amount of styrene or acrylate and on the electronic and steric effects of the substituents on the styrene moiety. Moreover, neutral and electron-donating substituents favoured the formation of the branched isomer. In general, yields were moderate to good and in most cases better than those obtained by the conventional procedures that used organic solvents. In addition, ohmic heating proved to be more efficient than conventional and microwave heating.

Heck Reaction
The  3 ] [tol = 4-methylphenyl(tolyl)] or the base (NaOAc or K 2 CO 3 ) did not improve the yields; instead when P(o-tol) 3 was used, the branched regioisomer 3-(1-phenylethenyl)quinolin-4(1H)-one 297 was obtained as the main product (296: 10%; 297: 16%). This Heck procedure revealed to be efficient only when 3-iodoquinolin-4(1H)-one was N-methylated. The Heck reaction of 3-iodo-1-methylquinolin-4(1H)-one 294 led to the (E)-1-methyl-3-styrylquinolin-4(1H)-one 296 in better yield (55%) although the branched regioisomer 297 was also isolated (14%). When the reaction was performed under MW, shortening of the reaction time occurred but lower yields were obtained (40% in 1.5 h). The best catalyst found for the unsubstituted styrene [Pd(PPh 3 ) 4 ] did not work well with substituted styrenes, except for styrene 295 [R 2 = NO 2 ; R 3 = H (CH: 65%; MW: 45%]. For other styrenes 295, PdCl 2 proved to be more efficient (R 2 = H; R 3 = OMe, CH: 59%, MW: 36%; R 2 = R 3 = OMe, CH: 55%, MW: 30%; R 2 = H; R 3 = F, CH: 56%; MW: 48%). Later, Silva and co-workers have performed the Heck reaction of 3-iodoquinolin-4(1H)-ones 294 with styrene derivatives 295 in an ohmic heating (ΩH) reactor [120,121], in aqueous media, using Pd(OAc) 2 as catalyst and TBAB as phase transfer catalyst in the presence of an inorganic base [122]. Butyl acrylate was also used as a coupling partner to give a different 3-substituted quinolin-4(1H)-one 298 (Scheme 93) [122]. This methodology is environmentally friendly, due to the use of water as solvent and there is no need for costly and toxic phosphine ligands. Yields were dependent on the amount of styrene or acrylate and on the electronic and steric effects of the substituents on the styrene moiety. Moreover, neutral and electron-donating substituents favoured the formation of the branched isomer. In general, yields were moderate to good and in most cases better than those obtained by the conventional procedures that used organic solvents. In addition, ohmic heating proved to be more efficient than conventional and microwave heating.
The 6-bromoquinolin-4(1H)-one 317 was converted to the corresponding vinyl derivative 318 via a Suzuki coupling with potassium vinyltrifluoroborate (Scheme 99) [130]. Potential bioactive 3-arylquinolin-4(1H)-ones 320 were synthesized, using ohmic heating, following an efficient and ligand-free protocol for the Suzuki−Miyaura coupling of 1-substituted-3iodoquinolin-4(1H)-ones 294 with several arylboronic acids 319, in water, using Pd(OAc)2 as a catalyst and TBAB as the phase transfer catalyst (Scheme 100) [131]. The reaction is sensitive to the electronic and steric effects of the substituents in the arylboronic acid; in general, arylboronic acids having electron-donating substituents gave better yields. However, the extensive substrate generality, ease of execution and short reaction time make this method exploitable for the generation of libraries of substituted 3-arylquinolin-4(1H)-ones 320. The reaction of 294 (R 1 = Me) with phenylboronic acid was also performed in classical heating conditions and using microwave irradiation but, for a reaction Scheme 98. Synthesis of trisubstituted quinolin-4(1H)-ones 316 by sequential Suzuki-Miyaura (i, ii) or one-pot double Suzuki-Miyaura (i, iii) reactions of 1-substituted-6-bromo-3-iodoquinolin-4(1H)-ones 314 with arylboronic acids [129]. Potential bioactive 3-arylquinolin-4(1H)-ones 320 were synthesized, using ohmic heating, following an efficient and ligand-free protocol for the Suzuki−Miyaura coupling of 1-substituted-3iodoquinolin-4(1H)-ones 294 with several arylboronic acids 319, in water, using Pd(OAc)2 as a catalyst and TBAB as the phase transfer catalyst (Scheme 100) [131]. The reaction is sensitive to the electronic and steric effects of the substituents in the arylboronic acid; in general, arylboronic acids having electron-donating substituents gave better yields. However, the extensive substrate generality, ease of execution and short reaction time make this method exploitable for the generation of libraries of substituted 3-arylquinolin-4(1H)-ones 320. The reaction of 294 (R 1 = Me) with phenylboronic acid was also performed in classical heating conditions and using microwave irradiation but, for a reaction Scheme 99.
Potential bioactive 3-arylquinolin-4(1H)-ones 320 were synthesized, using ohmic heating, following an efficient and ligand-free protocol for the Suzuki−Miyaura coupling of 1-substituted-3-iodoquinolin-4(1H)-ones 294 with several arylboronic acids 319, in water, using Pd(OAc) 2 as a catalyst and TBAB as the phase transfer catalyst (Scheme 100) [131]. The reaction is sensitive to the electronic and steric effects of the substituents in the arylboronic acid; in general, arylboronic acids having electron-donating substituents gave better yields. However, the extensive substrate generality, ease of execution and short reaction time make this method exploitable for the generation of libraries of substituted 3-arylquinolin-4(1H)-ones 320. The reaction of 294 (R 1 = Me) with phenylboronic acid was also performed in classical heating conditions and using microwave irradiation but, for a reaction time of 15 min, ohmic heating was the most efficient heating method [131].
After a simple workup, the Pd/catalyst-H 2 O-TBAB system could be reused for at least seven cycles without significant loss of activity [131].  [131]. After a simple workup, the Pd/catalyst-H2O-TBAB system could be reused for at least seven cycles without significant loss of activity [131].  [132]. Quinolones 322 bearing N-ethyl substituent were more reactive than those bearing N-ribonucleosides providing the corresponding porphyrinquinolin-4(1H)-one conjugates 323 in very good yields (82-89%). The other conjugates 323 were isolated in lower yields (50-51%) but nearly 50% of the starting porphyrin 321 was recovered in both cases. Attempts to improve these yields (e.g., by increasing the reaction time and by increasing the number of equivalents of the bromoquinolin-4(1H)-ones) were not successful, probably due to steric effects caused by the ribofuranosyl group. Basic hydrolysis and deprotection of the ribose moieties ester and benzoyl groups in conjugates 323 followed by the acid demetallation afforded the corresponding conjugates that were evaluated as singlet oxygen generators. Scheme 101. Synthesis of porphyrin-quinolin-4(1H)-one conjugates 323 by Suzuki-Miyaura reaction of β-borylated porphyrin 321 with 6-or 7-bromoquinolin-4(1H)-ones 322 [132].
The enantioselective conjugate addition of arylboronic acids 319 to N-carboxybenzyl(Cbz)quinolin-4(1H)-ones 324 utilizing the Pd/PyOX catalyst system, under an atmosphere of air, afforded novel 2-aryl-2,3-dihydroquinolin-4(1H)-ones 325 with high enantioselectivity in moderate to excellent yields (Scheme 102) [133]. Nitrogen-containing heteroaromatic and simpler boronic acid derivatives were successfully employed as nucleophiles in the 1,4-addition to quinolin-4(1H)-ones. Alkyl-and halogen-substituted boronic acids gave reasonable yields (45-65%) and enantioselectivities (67-89% ee) and disubstituted boronic acids were also well tolerated and gave similar results. More sterically demanding boronic acids led to lower product yield.  [132]. Quinolones 322 bearing N-ethyl substituent were more reactive than those bearing N-ribonucleosides providing the corresponding porphyrin-quinolin-4(1H)-one conjugates 323 in very good yields (82-89%). The other conjugates 323 were isolated in lower yields (50-51%) but nearly 50% of the starting porphyrin 321 was recovered in both cases. Attempts to improve these yields (e.g., by increasing the reaction time and by increasing the number of equivalents of the bromoquinolin-4(1H)-ones) were not successful, probably due to steric effects caused by the ribofuranosyl group. Basic hydrolysis and deprotection of the ribose moieties ester and benzoyl groups in conjugates 323 followed by the acid demetallation afforded the corresponding conjugates that were evaluated as singlet oxygen generators.  [131]. After a simple workup, the Pd/catalyst-H2O-TBAB system could be reused for at least seven cycles without significant loss of activity [131].  [132]. Quinolones 322 bearing N-ethyl substituent were more reactive than those bearing N-ribonucleosides providing the corresponding porphyrinquinolin-4(1H)-one conjugates 323 in very good yields (82-89%). The other conjugates 323 were isolated in lower yields (50-51%) but nearly 50% of the starting porphyrin 321 was recovered in both cases. Attempts to improve these yields (e.g., by increasing the reaction time and by increasing the number of equivalents of the bromoquinolin-4(1H)-ones) were not successful, probably due to steric effects caused by the ribofuranosyl group. Basic hydrolysis and deprotection of the ribose moieties ester and benzoyl groups in conjugates 323 followed by the acid demetallation afforded the corresponding conjugates that were evaluated as singlet oxygen generators. Scheme 101. Synthesis of porphyrin-quinolin-4(1H)-one conjugates 323 by Suzuki-Miyaura reaction of β-borylated porphyrin 321 with 6-or 7-bromoquinolin-4(1H)-ones 322 [132].

Sonogashira Reaction
The tandem coupling-cyclization process, involving Sonogashira reaction followed by the electrophilic or transition-metal-mediated cyclization of the resulting alkynes, having a suitable nucleophilic group in the proximity of the triple bond, generated diverse 2-substituted furo [3,2c]quinolines 327 (Scheme 103) [134,135]. Better yields were obtained when using Pd(PPh3)4 (85%) or PdCl2(PPh3)2 (80%) instead of Pd/C-PPh3 (70%), although the latter is cheaper. DMF was found to be a better solvent when compared to THF or MeCN and CuI is crucial in this reaction; otherwise only de-iodinated product is formed. The absence of PPh3 when using Pd/C resulted in a poor yield (22%). Good yields of the furo[3,2-c]quinolines 327 were obtained regardless the nature of terminal alkynes used. The key features of the present tandem-coupling-cyclization process are the transition-metalmediated activation of the triple bond of the 3-alkynyl quinoline generated in situ followed by an intramolecular attack of the oxygen on the activated triple bond with subsequent proton transfer and release of the metal ion to give the desired furoquinolines 327. The NH of the quinolin-4(1H)-one ring has a critical role facilitating the participation of C-4 quinoline oxygen in the cyclization step. Indeed, when 3-iodo-1-methyl-4-oxo-1,4-dihydroquinoline-2-carboxylic acid methyl esters 326 reacted with terminal alkynes, under the same conditions, only 3-alkynylquinolin-4(1H)-ones 328 were isolated as a result of a normal Sonogashira coupling reaction and formation of furoquinolines 327 was not observed, even in trace amounts (Scheme 103). Diverse macrolone derivatives, which possess high antibacterial activity, were prepared starting from 6-iodoquinolin-4(1H)-ones 305 via Sonogashira reaction [125,136,137]. For example, macrolones 330 were prepared by Sonogashira reaction of 6-iodoquinolin-4(1H)-ones 305 with macrolides 329. Then, Pd/C catalysed hydrogenation was performed to obtain the desirable macrolones 331 (Scheme 104) [125].

Sonogashira Reaction
The tandem coupling-cyclization process, involving Sonogashira reaction followed by the electrophilic or transition-metal-mediated cyclization of the resulting alkynes, having a suitable nucleophilic group in the proximity of the triple bond, generated diverse 2-substituted furo [3,2-c]quinolines 327 (Scheme 103) [134,135]. Better yields were obtained when using Pd(PPh 3 ) 4 (85%) or PdCl 2 (PPh 3 ) 2 (80%) instead of Pd/C-PPh 3 (70%), although the latter is cheaper. DMF was found to be a better solvent when compared to THF or MeCN and CuI is crucial in this reaction; otherwise only de-iodinated product is formed. The absence of PPh 3 when using Pd/C resulted in a poor yield (22%). Good yields of the furo[3,2-c]quinolines 327 were obtained regardless the nature of terminal alkynes used. The key features of the present tandem-coupling-cyclization process are the transition-metal-mediated activation of the triple bond of the 3-alkynyl quinoline generated in situ followed by an intramolecular attack of the oxygen on the activated triple bond with subsequent proton transfer and release of the metal ion to give the desired furoquinolines 327. The NH of the quinolin-4(1H)-one ring has a critical role facilitating the participation of C-4 quinoline oxygen in the cyclization step. Indeed, when 3-iodo-1-methyl-4-oxo-1,4-dihydroquinoline-2-carboxylic acid methyl esters 326 reacted with terminal alkynes, under the same conditions, only 3-alkynylquinolin-4(1H)-ones 328 were isolated as a result of a normal Sonogashira coupling reaction and formation of furoquinolines 327 was not observed, even in trace amounts (Scheme 103).

Sonogashira Reaction
The tandem coupling-cyclization process, involving Sonogashira reaction followed by the electrophilic or transition-metal-mediated cyclization of the resulting alkynes, having a suitable nucleophilic group in the proximity of the triple bond, generated diverse 2-substituted furo [3,2c]quinolines 327 (Scheme 103) [134,135]. Better yields were obtained when using Pd(PPh3)4 (85%) or PdCl2(PPh3)2 (80%) instead of Pd/C-PPh3 (70%), although the latter is cheaper. DMF was found to be a better solvent when compared to THF or MeCN and CuI is crucial in this reaction; otherwise only de-iodinated product is formed. The absence of PPh3 when using Pd/C resulted in a poor yield (22%). Good yields of the furo[3,2-c]quinolines 327 were obtained regardless the nature of terminal alkynes used. The key features of the present tandem-coupling-cyclization process are the transition-metalmediated activation of the triple bond of the 3-alkynyl quinoline generated in situ followed by an intramolecular attack of the oxygen on the activated triple bond with subsequent proton transfer and release of the metal ion to give the desired furoquinolines 327. The NH of the quinolin-4(1H)-one ring has a critical role facilitating the participation of C-4 quinoline oxygen in the cyclization step. Indeed, when 3-iodo-1-methyl-4-oxo-1,4-dihydroquinoline-2-carboxylic acid methyl esters 326 reacted with terminal alkynes, under the same conditions, only 3-alkynylquinolin-4(1H)-ones 328 were isolated as a result of a normal Sonogashira coupling reaction and formation of furoquinolines 327 was not observed, even in trace amounts (Scheme 103). Diverse macrolone derivatives, which possess high antibacterial activity, were prepared starting from 6-iodoquinolin-4(1H)-ones 305 via Sonogashira reaction [125,136,137]. For example, macrolones 330 were prepared by Sonogashira reaction of 6-iodoquinolin-4(1H)-ones 305 with macrolides 329. Then, Pd/C catalysed hydrogenation was performed to obtain the desirable macrolones 331 (Scheme 104) [125]. Diverse macrolone derivatives, which possess high antibacterial activity, were prepared starting from 6-iodoquinolin-4(1H)-ones 305 via Sonogashira reaction [125,136,137]. For example, macrolones 330 were prepared by Sonogashira reaction of 6-iodoquinolin-4(1H)-ones 305 with macrolides 329. Then, Pd/C catalysed hydrogenation was performed to obtain the desirable macrolones 331 (Scheme 104) [125]. Scheme 104. Synthesis of macrolones 331 via Sonogashira reaction of macrolide 329 with 6iodoquinolin-4(1H)-ones 305 followed by Pd/C hydrogenation [125].
The Sonogashira reaction of 6-bromo-3-iodoquinolin-4(1H)-ones 314 with TMSA afforded the expected coupling products in very satisfactory yields, with no further conversion to furo[3,2c]quinoline derivatives (Scheme 106) [129]. Suzuki and Sonogashira cross-coupling reactions at 6position of substrates 338 yielded the trisubstituted quinolin-4(1H)-ones 339. In general, harder conditions were necessary to functionalize the 6-position due to the lower reactivity of bromine compared to iodine but, on the other hand, the increased structural complexity made substrates 338 more prone to decomposition and side products' formation. Therefore, cross-coupling reactions at 6position proceeded with slightly lower efficiency, leading to products 339 in moderate to low yields. Scheme 105. Synthesis of macrolones 336 and 337 via Sonogashira reaction followed by Pd/C hydrogenation and hydrolysis of the corresponding esters 336 [125].
The Sonogashira reaction of 6-bromo-3-iodoquinolin-4(1H)-ones 314 with TMSA afforded the expected coupling products in very satisfactory yields, with no further conversion to furo[3,2-c]quinoline derivatives (Scheme 106) [129]. Suzuki and Sonogashira cross-coupling reactions at 6-position of substrates 338 yielded the trisubstituted quinolin-4(1H)-ones 339. In general, harder conditions were necessary to functionalize the 6-position due to the lower reactivity of bromine compared to iodine but, on the other hand, the increased structural complexity made substrates 338 more prone to decomposition and side products' formation. Therefore, cross-coupling reactions at 6-position proceeded with slightly lower efficiency, leading to products 339 in moderate to low yields.  [125].
The Sonogashira reaction of 6-bromo-3-iodoquinolin-4(1H)-ones 314 with TMSA afforded the expected coupling products in very satisfactory yields, with no further conversion to furo[3,2c]quinoline derivatives (Scheme 106) [129]. Suzuki and Sonogashira cross-coupling reactions at 6position of substrates 338 yielded the trisubstituted quinolin-4(1H)-ones 339. In general, harder conditions were necessary to functionalize the 6-position due to the lower reactivity of bromine compared to iodine but, on the other hand, the increased structural complexity made substrates 338 more prone to decomposition and side products' formation. Therefore, cross-coupling reactions at 6position proceeded with slightly lower efficiency, leading to products 339 in moderate to low yields. Scheme 105. Synthesis of macrolones 336 and 337 via Sonogashira reaction followed by Pd/C hydrogenation and hydrolysis of the corresponding esters 336 [125].
Pd-catalysed amination reactions of 6-bromoquinolin-4(1H)-ones 322 containing N-ethyl, Npentyl and N-ribofuranosyl substituents with (2-amino-5,10,15,20-tetraphenylporphyrinato) nickel(II) 358 followed by demetallation, allowed the access to porphyrin-quinolin-4(1H)-one conjugates 361 and 362 (Scheme 111) [143]. The use of Pd(OAc)2 in combination with rac-BINAP, as the ligand, led to complete consumption of starting material 322 and to the formation of the conjugates 359 in moderate to very good yields (63-89%). The yields were lower and longer reaction time was required in the case of quinolones having bulky groups, such as pentyl and ribofuranosyl groups, probably due to steric effects. The formation of the by-products 360 is promoted by the transfer of a rac-BINAP phenyl group to the metal ion centre followed by a reductive-elimination step during the catalytic cycle. The conjugates 361a demonstrated good to high capability to generate singlet oxygen evidencing potential application in the inactivation of the Gram-positive bacteria Staphylococcus aureus [143].
Pd-catalysed amination reactions of 6-bromoquinolin-4(1H)-ones 322 containing N-ethyl, N-pentyl and N-ribofuranosyl substituents with (2-amino-5,10,15,20-tetraphenylporphyrinato) nickel(II) 358 followed by demetallation, allowed the access to porphyrin-quinolin-4(1H)-one conjugates 361 and 362 (Scheme 111) [143]. The use of Pd(OAc) 2 in combination with rac-BINAP, as the ligand, led to complete consumption of starting material 322 and to the formation of the conjugates 359 in moderate to very good yields (63-89%). The yields were lower and longer reaction time was required in the case of quinolones having bulky groups, such as pentyl and ribofuranosyl groups, probably due to steric effects. The formation of the by-products 360 is promoted by the transfer of a rac-BINAP phenyl group to the metal ion centre followed by a reductive-elimination step during the catalytic cycle. The conjugates 361a demonstrated good to high capability to generate singlet oxygen evidencing potential application in the inactivation of the Gram-positive bacteria Staphylococcus aureus [143]. Scheme 113. Pd-catalysed aminocarbonylation of 6-bromo-3-iodoquinolin-4(1H)-ones 314 [129].

Other Reactions
Pd-catalysed 3-alkenylation of quinolin-4(1H)-ones 365 with compounds 366 was efficiently achieved with 1% catalyst loading affording 3-substituted-quinolin-4(1H)-ones 367 (Scheme 114) [144]. From a series of tested catalysts [Pd(OAc)2, PdCl2, Pd(TFA)2], PdCl2 was the most efficient at low loadings. The addition of Cu(OAc) (10 mol%) was necessary to achieve high yield of the product. The presence of O2 in the reaction medium, which acts as a co-oxidant, is favourable. Regarding the reaction scope, a substituent is required on the nitrogen; coupling of free (NH) quinolone with acrylate gave no product. The presence of electron-donating groups at the C-6 position provided high yields while electron-withdrawing groups gave lower yields; however, high yield was obtained when CF3 group was at that position and with halogens (6-F, 6-Cl and 6-Br). 8-Substituted quinolones have a similar reactivity as 6-substituted ones but generally with lower yields, probably due to steric effects. Even the 6,7-(methylenedioxy)-substituted quinolone gave the product in modest yield. Terminal acrylates, N,N-dimethylacrylamide, styrene and 2-vinylnaphthalene gave the corresponding products in high yields while modest to reasonable yields were obtained with acrylic acid, sterically hindered acrylates, diethyl fumarate, methacrylonitrile, vinyl phosphonate and methyl vinyl sulfone. An efficient and practical metal-catalysed decarboxylative cross-coupling reaction of quinolin-4(1H)-one 3-carboxylic acids 368 with various (hetero)-aryl halides was described (Scheme 115) [145]. An extensive screening of various reaction parameters (Pd, ligand, solvent, base and temperature) showed that PdI2, Pd(OAc)2 and PdCl2 were less effective than PdBr2. The nature of the phosphine ligand has an important influence on the reaction selectivity and optimal reaction conditions of 368 (R 1 = Ph; R 2 = H) with 4-iodoanisole involved the combination of the bidentate phosphine DPEphos with PdBr2 in toluene/dimethylacetamide (DMA) at 150 °C. The use of microwave irradiation provided shortening of reaction time and increase of quinolin-4(1H)-ones 369 yield (MW: 1 h, 81%; CH: 8 h, 77% and 1 h, 60%). The bimetallic system PdBr2/Ag2CO3 is necessary for the coupling to occur; no product could be formed in the absence of PdBr2 or when Ag2CO3 was replaced by other bases. Using optimal conditions under microwave irradiation, electron-rich and electron-deficient, o-, m-and p-substituted aryl iodides and bromides, all efficiently underwent decarboxylative coupling in good yields (40-99%) and the coupling with heterocyclic halides was also successful (40% for 3bromocoumarin and 57% for 3-bromoquinolin-2(1H)-one). Both N-alkyl-and N-arylquinolin-4(1H)-Scheme 113. Pd-catalysed aminocarbonylation of 6-bromo-3-iodoquinolin-4(1H)-ones 314 [129].

Other Reactions
Pd-catalysed 3-alkenylation of quinolin-4(1H)-ones 365 with compounds 366 was efficiently achieved with 1% catalyst loading affording 3-substituted-quinolin-4(1H)-ones 367 (Scheme 114) [144]. From a series of tested catalysts [Pd(OAc) 2 , PdCl 2 , Pd(TFA) 2 ], PdCl 2 was the most efficient at low loadings. The addition of Cu(OAc) (10 mol%) was necessary to achieve high yield of the product. The presence of O 2 in the reaction medium, which acts as a co-oxidant, is favourable. Regarding the reaction scope, a substituent is required on the nitrogen; coupling of free (NH) quinolone with acrylate gave no product. The presence of electron-donating groups at the C-6 position provided high yields while electron-withdrawing groups gave lower yields; however, high yield was obtained when CF 3 group was at that position and with halogens (6-F, 6-Cl and 6-Br). 8-Substituted quinolones have a similar reactivity as 6-substituted ones but generally with lower yields, probably due to steric effects. Even the 6,7-(methylenedioxy)-substituted quinolone gave the product in modest yield. Terminal acrylates, N,N-dimethylacrylamide, styrene and 2-vinylnaphthalene gave the corresponding products in high yields while modest to reasonable yields were obtained with acrylic acid, sterically hindered acrylates, diethyl fumarate, methacrylonitrile, vinyl phosphonate and methyl vinyl sulfone.

Other Reactions
Pd-catalysed 3-alkenylation of quinolin-4(1H)-ones 365 with compounds 366 was efficiently achieved with 1% catalyst loading affording 3-substituted-quinolin-4(1H)-ones 367 (Scheme 114) [144]. From a series of tested catalysts [Pd(OAc)2, PdCl2, Pd(TFA)2], PdCl2 was the most efficient at low loadings. The addition of Cu(OAc) (10 mol%) was necessary to achieve high yield of the product. The presence of O2 in the reaction medium, which acts as a co-oxidant, is favourable. Regarding the reaction scope, a substituent is required on the nitrogen; coupling of free (NH) quinolone with acrylate gave no product. The presence of electron-donating groups at the C-6 position provided high yields while electron-withdrawing groups gave lower yields; however, high yield was obtained when CF3 group was at that position and with halogens (6-F, 6-Cl and 6-Br). 8-Substituted quinolones have a similar reactivity as 6-substituted ones but generally with lower yields, probably due to steric effects. Even the 6,7-(methylenedioxy)-substituted quinolone gave the product in modest yield. Terminal acrylates, N,N-dimethylacrylamide, styrene and 2-vinylnaphthalene gave the corresponding products in high yields while modest to reasonable yields were obtained with acrylic acid, sterically hindered acrylates, diethyl fumarate, methacrylonitrile, vinyl phosphonate and methyl vinyl sulfone. Scheme 114. Direct 3-alkenylation of quinolin-4(1H)-ones 365 [144].
An efficient and practical metal-catalysed decarboxylative cross-coupling reaction of quinolin-4(1H)-one 3-carboxylic acids 368 with various (hetero)-aryl halides was described (Scheme 115) [145]. An extensive screening of various reaction parameters (Pd, ligand, solvent, base and temperature) showed that PdI 2 , Pd(OAc) 2 and PdCl 2 were less effective than PdBr 2 . The nature of the phosphine ligand has an important influence on the reaction selectivity and optimal reaction conditions of 368 (R 1 = Ph; R 2 = H) with 4-iodoanisole involved the combination of the bidentate phosphine DPEphos with PdBr 2 in toluene/dimethylacetamide (DMA) at 150 • C. The use of microwave irradiation provided shortening of reaction time and increase of quinolin-4(1H)-ones 369 yield (MW: 1 h, 81%; CH: 8 h, 77% and 1 h, 60%). The bimetallic system PdBr 2 /Ag 2 CO 3 is necessary for the coupling to occur; no product could be formed in the absence of PdBr 2 or when Ag 2 CO 3 was replaced by other bases. Using optimal conditions under microwave irradiation, electron-rich and electron-deficient, o-, mand p-substituted aryl iodides and bromides, all efficiently underwent decarboxylative coupling in good yields (40-99%) and the coupling with heterocyclic halides was also successful (40% for 3-bromocoumarin and 57% for 3-bromoquinolin-2(1H)-one). Both N-alkyland N-arylquinolin-4(1H)-one 3-carboxylic acids 368 having electron-donating or electron-withdrawing groups on the aromatic nucleus led to the formation of the corresponding coupled products 369 in good yields (60-90%). Excellent chemical selectivity was observed for 368 (R 2 = Cl) preserving the C-Cl bond, which could undergo further metal-catalysed functionalization reactions. This protocol is an attractive alternative to the existing methods for the synthesis of 3-(hetero)-arylquinolin-4(1H)-ones 369 and was also applied to the synthesis of 1-methyl-3-phenylquinolin-2(1H)-one (44%).
Molecules 2019, 24, 228 64 of 75 one 3-carboxylic acids 368 having electron-donating or electron-withdrawing groups on the aromatic nucleus led to the formation of the corresponding coupled products 369 in good yields (60-90%). Excellent chemical selectivity was observed for 368 (R 2 = Cl) preserving the C-Cl bond, which could undergo further metal-catalysed functionalization reactions. This protocol is an attractive alternative to the existing methods for the synthesis of 3-(hetero)-arylquinolin-4(1H)-ones 369 and was also applied to the synthesis of 1-methyl-3-phenylquinolin-2(1H)-one (44%).
The ligand-free palladium-catalysed decarboxylative functionalization of quinolinone-3carboxylic acids 370 and 372 with aryl halides afforded biologically important 3-arylquinolin-4(1H)ones 371 and 373 in moderate to high yields (Scheme 116) [146]. The reaction proceeded smoothly under an argon atmosphere at relatively low temperature by using Pd(OAc)2 as the catalyst and Ag2CO3 as the oxidant. Aryl iodides gave better results than aryl bromides and various functionalities were compatible under the reaction conditions. Electronic effects strongly influenced the reaction. The coupling of aryl iodides bearing electron-donating substituents provided the corresponding products in high yields but iodobenzene derivatives with electron-deficient groups were significantly less reactive.
Pd-catalysed direct thioetherification of quinolone derivatives 370 and 376 with diaryl disulfides 374 via decarboxylative C-S cross-couplings proceeded smoothly under air in the presence of Pd(OAc)2 and Ag2CO3 in DMSO (Scheme 117) [147]. The solvent has an important role in the reaction, DMSO being superior to other solvents and no product was isolated when the reaction was performed under argon or nitrogen atmosphere. Disulfides 374 substituted with electronwithdrawing groups gave the product in lower yields. In addition, when some radical scavengers such as TEMPO or HQ were used in this C-S coupling, the reaction was inhibited and no product was detected. The reaction mechanism initiates with the formation of an organometallic species via decarboxylation by reaction with the silver salt. Subsequently, the Pd(II) reacts with the diaryl disulfides to generate a Pd(II) species. Then, an aryl-Pd(II) species was produced by way of a transmetalation reaction between the organometallic and Pd(II) species. Finally, the reductive elimination of the aryl Pd(II) afforded the target product and Pd(0) species, which can be oxidized to Pd(II) by oxygen and continue the catalytic cycle [147]. This protocol is an alternative to existing approaches to construct aryl sulphides of quinolone derivatives which may be used as important intermediates in the synthesis of new drug candidates. Scheme 115. Metal-catalysed decarboxylative coupling of quinolin-4(1H)-one 3-carboxylic acids 368 with (hetero)-aryl halides [145].
The ligand-free palladium-catalysed decarboxylative functionalization of quinolinone-3-carboxylic acids 370 and 372 with aryl halides afforded biologically important 3-arylquinolin-4(1H)-ones 371 and 373 in moderate to high yields (Scheme 116) [146]. The reaction proceeded smoothly under an argon atmosphere at relatively low temperature by using Pd(OAc) 2 as the catalyst and Ag 2 CO 3 as the oxidant. Aryl iodides gave better results than aryl bromides and various functionalities were compatible under the reaction conditions. Electronic effects strongly influenced the reaction. The coupling of aryl iodides bearing electron-donating substituents provided the corresponding products in high yields but iodobenzene derivatives with electron-deficient groups were significantly less reactive. Pd-catalysed direct thioetherification of quinolone derivatives 370 and 376 with diaryl disulfides 374 via decarboxylative C-S cross-couplings proceeded smoothly under air in the presence of Pd(OAc) 2 and Ag 2 CO 3 in DMSO (Scheme 117) [147]. The solvent has an important role in the reaction, DMSO being superior to other solvents and no product was isolated when the reaction was performed under argon or nitrogen atmosphere. Disulfides 374 substituted with electron-withdrawing groups gave the product in lower yields. In addition, when some radical scavengers such as TEMPO or HQ were used

Conclusions
Pd-catalysed reactions are of paramount importance in the synthesis and transformation of quinolin-2(1H)-ones and quinolin-4(1H)-ones, as it was evidenced by the several examples presented along these review article. In some of these examples, especially in the synthesis of quinolones, the claimed Pd-catalysed reaction is crucial for the formation of the appropriate substrate for cyclization into the desired quinolone, in spite of not being used in the cyclization step.
Among the Pd-catalysed reactions developed for the synthesis and transformation of quinolones, the cross-coupling reactions, which require the use of an already activated counterpart, for instance a halogenated derivative, which is coupled to another appropriate substrate, are the most common. More recently, several works have been focused on the development of protocols for direct C-H functionalization, thus allowing the construction of more complex and highly substituted quinolone derivatives in a more straightforward way. In addition, efforts have been made to develop new protocols for already known Pd-catalysed reactions, aiming to meet the green chemistry requirements and to facilitate the reactions scale-up. Some important advances have been achieved in this area by replacing homogeneous Pd-catalysts by heterogeneous Pd-catalysts, by using ligand-free conditions or room temperature. Another interesting example, in the carbonylation reactions, is the replacement of gaseous CO by more convenient solid sources of CO, such as molybdenum hexacarbonyl [Mo(CO) 6 ], facilitating the reactions' scale-up. All the Pd-catalysed reactions herein presented have profoundly changed the protocols for the construction of various quinolone-type compounds, some of them of recognized importance due to their relevant biological activities. In spite of the great advances of Pd-catalysed reactions achieved in the last 20 years, this field of research is still wide-open for innovation and will continue to advance as even more versatile transformations are developed.