Indolylboronic Acids: Preparation and Applications

Indole derivatives are associated with a variety of both biological activities and applications in the field of material chemistry. A number of different strategies for synthesizing substituted indoles by means of the reactions of indolylboronic acids with electrophilic compounds are considered the methods of choice for modifying indoles because indolylboronic acids are easily available, stable, non-toxic and new reactions using indolylboronic acids have been described in the literature. Thus, the aim of this review is to summarize the methods available for the preparation of indolylboronic acids as well as their chemical transformations. The review covers the period 2010–2019.


Introduction
Indole is one of the simplest fused heterocyclic compounds known to act as a key scaffold of many naturally occurring molecules. For example, skatole (F1-1), melatonin (F1-2), serotonin (F1-3), and tryptamine (F1-4) are all well-known indole-based compounds ( Figure 1). The functionalization of indoles, including the determination of their biological activities, has been the subject of considerable scientific research interest. Indeed, substituted indoles have been reported as affinity probes for the 5-hydroxytryptamine receptor [1], selective tumor-associated carbonic anhydrase inhibitors [2], carboxamide spleen tyrosine kinase inhibitors [3], selective inhibitors with broad hepatitis C virus genotype activity [4], Nav1.7 inhibitors [5], and TNFα inhibitors [6]. Further, the indole skeleton, as a constituent of naturally occurring substances, has been modified to furnish (−)clavicipitic acid [7], breitfussin B [8], alstoscholarisines A and E [9], (+)-kopsihainanine A [10], and (−)-goniomitine [11]. The synthetic approaches for the preparation of substituted indoles can be divided into two main groups. The first group consists of methodologies involving both transition-metal-catalyzed and transition-metal-free cyclization strategies for ortho-substituted benzenes bearing the nitrogencontaining functional group, which are mostly substituted anilines (Scheme 1, route a). The cyclization pathway for the preparation of indoles is represented by the Baeyer-Emmerling [12], Bartoli [13], Fischer [14], Fukuyama [15], Gassman [16], and Larock [17] methods of indole synthesis. The synthetic approaches for the preparation of substituted indoles can be divided into two main groups. The first group consists of methodologies involving both transition-metal-catalyzed and transition-metal-free cyclization strategies for ortho-substituted benzenes bearing the nitrogencontaining functional group, which are mostly substituted anilines (Scheme 1, route a). The cyclization pathway for the preparation of indoles is represented by the Baeyer-Emmerling [12], Bartoli [13], Fischer [14], Fukuyama [15], Gassman [16], and Larock [17] methods of indole synthesis. The second approach to indole synthesis is based on the modification of already functionalized indoles by means of The second approach to indole synthesis is based on the modification of already functionalized indoles by means of traditional electrophilic [18,19] and nucleophilic [20] substitution reactions or transition-metal-catalyzed reactions of indolyl substrates (Scheme 1, route b) [21][22][23][24][25]. Transition metal-catalyzed cross-coupling reactions represent an indispensable tool for organic synthesis when considering the formation of C−C and C−heteroatom bonds. Among the available cross-coupling reactions, the Suzuki-Miyaura reaction [26,27] is the method of choice in terms of designing the construction of a C−C bond under mild reaction conditions. The Suzuki-Miyaura reaction involves a simple reaction between boronic acids S2-2 or boronates/trifluoroborates and electrophilic templates S2-1, as represented by halides, tosylates, triflates, or phosphates, in the presence of a base and transition metal catalyst. The good availability, low toxicity, and high stability of boronic acids all explain the widespread popularity of the Suzuki-Miyaura reaction. The reaction mechanism behind the Suzuki-Miyaura reaction involves a complex process [28] featuring oxidative addition, ligand substitution, transmetalation, and reductive elimination as the main reaction steps (Scheme 2). Two reaction pathways can be envisioned when designing the synthesis of substituted indoles by means of the Suzuki-Miyaura reaction. The first approach is based on the cross-coupling of arylor heteroarylboronic acids with electrophilic indolyl templates. Selected examples show how chloro- [29], bromo- [30], bromoindolyl phosphate [31], and triflates [32] are all capable of coupling with boronic acids under mild reaction conditions. Yet, a wide variety of allylic alcohols [33], heterocyclic halides [34], bromoenol phosphates [35], sulfones [36], and sulfonates [37] have been used as electrophilic templates in reactions with indolylboronic acids under Suzuki-Miyaura reaction conditions involving, for example EvanPhos [38] and tri-tert-butylphosphine ligand [39], nickel [40], Transition metal-catalyzed cross-coupling reactions represent an indispensable tool for organic synthesis when considering the formation of C−C and C−heteroatom bonds. Among the available cross-coupling reactions, the Suzuki-Miyaura reaction [26,27] is the method of choice in terms of designing the construction of a C−C bond under mild reaction conditions. The Suzuki-Miyaura reaction involves a simple reaction between boronic acids S2-2 or boronates/trifluoroborates and electrophilic templates S2-1, as represented by halides, tosylates, triflates, or phosphates, in the presence of a base and transition metal catalyst. The good availability, low toxicity, and high stability of boronic acids all explain the widespread popularity of the Suzuki-Miyaura reaction. The reaction mechanism behind the Suzuki-Miyaura reaction involves a complex process [28] featuring oxidative addition, ligand substitution, transmetalation, and reductive elimination as the main reaction steps (Scheme 2). The second approach to indole synthesis is based on the modification of already functionalized indoles by means of traditional electrophilic [18,19] and nucleophilic [20] substitution reactions or transition-metal-catalyzed reactions of indolyl substrates (Scheme 1, route b) [21][22][23][24][25]. Transition metal-catalyzed cross-coupling reactions represent an indispensable tool for organic synthesis when considering the formation of C−C and C−heteroatom bonds. Among the available cross-coupling reactions, the Suzuki-Miyaura reaction [26,27] is the method of choice in terms of designing the construction of a C−C bond under mild reaction conditions. The Suzuki-Miyaura reaction involves a simple reaction between boronic acids S2-2 or boronates/trifluoroborates and electrophilic templates S2-1, as represented by halides, tosylates, triflates, or phosphates, in the presence of a base and transition metal catalyst. The good availability, low toxicity, and high stability of boronic acids all explain the widespread popularity of the Suzuki-Miyaura reaction. The reaction mechanism behind the Suzuki-Miyaura reaction involves a complex process [28] featuring oxidative addition, ligand substitution, transmetalation, and reductive elimination as the main reaction steps (Scheme 2). Two reaction pathways can be envisioned when designing the synthesis of substituted indoles by means of the Suzuki-Miyaura reaction. The first approach is based on the cross-coupling of arylor heteroarylboronic acids with electrophilic indolyl templates. Selected examples show how chloro- [29], bromo- [30], bromoindolyl phosphate [31], and triflates [32] are all capable of coupling with boronic acids under mild reaction conditions. Yet, a wide variety of allylic alcohols [33], heterocyclic halides [34], bromoenol phosphates [35], sulfones [36], and sulfonates [37] have been used as electrophilic templates in reactions with indolylboronic acids under Suzuki-Miyaura reaction conditions involving, for example EvanPhos [38] and tri-tert-butylphosphine ligand [39], nickel [40], Two reaction pathways can be envisioned when designing the synthesis of substituted indoles by means of the Suzuki-Miyaura reaction. The first approach is based on the cross-coupling of aryl-or heteroarylboronic acids with electrophilic indolyl templates. Selected examples show how chloro- [29], bromo- [30], bromoindolyl phosphate [31], and triflates [32] are all capable of coupling with boronic acids under mild reaction conditions. Yet, a wide variety of allylic alcohols [33], heterocyclic halides [34], bromoenol phosphates [35], sulfones [36], and sulfonates [37] have been used as electrophilic templates in reactions with indolylboronic acids under Suzuki-Miyaura reaction conditions involving, for example EvanPhos [38] and tri-tert-butylphosphine ligand [39], nickel [40], and rhodium [41] catalysts, as well as  A decarboxylative cross-coupling represents an alternative procedure for the synthesis of indolylboronic acids. The borylation reaction can be performed by starting with either carboxylic acids [62] or thioester [63] under palladium or rhodium catalysis ( Table 2, entries 1 and 2). The decarboxylative indole borylation has also been performed under transition-metal-free conditions ( Table 2, entries 3 and 4). The reported protocols make use of N-hydroxyphthalimide esters, which are treated with pinB−Bpin under different conditions. Fu et al. [64] rely on the isonicotinate tertbutyl ester when refluxing in trifluorotoluene (TFT), while Glorius et al. [65] make use of pyridine 3 Br H-Bpin (2.5 equiv.) CuI (10 mol %), Fe(acac) 3   A decarboxylative cross-coupling represents an alternative procedure for the synthesis of indolylboronic acids. The borylation reaction can be performed by starting with either carboxylic acids [62] or thioester [63] under palladium or rhodium catalysis ( Table 2, entries 1 and 2). The decarboxylative indole borylation has also been performed under transition-metal-free conditions ( Table 2, entries 3 and 4). The reported protocols make use of N-hydroxyphthalimide esters, which are treated with pinB−Bpin under different conditions. Fu et al. [64] rely on the isonicotinate tertbutyl ester when refluxing in trifluorotoluene (TFT), while Glorius et al. [65] make use of pyridine  A decarboxylative cross-coupling represents an alternative procedure for the synthesis of indolylboronic acids. The borylation reaction can be performed by starting with either carboxylic acids [62] or thioester [63] under palladium or rhodium catalysis ( Table 2, entries 1 and 2). The decarboxylative indole borylation has also been performed under transition-metal-free conditions ( Table 2, entries 3 and 4). The reported protocols make use of N-hydroxyphthalimide esters, which are treated with pinB−Bpin under different conditions. Fu et al. [64] rely on the isonicotinate tertbutyl ester when refluxing in trifluorotoluene (TFT), while Glorius et al. [65] make use of pyridine  A decarboxylative cross-coupling represents an alternative procedure for the synthesis of indolylboronic acids. The borylation reaction can be performed by starting with either carboxylic acids [62] or thioester [63] under palladium or rhodium catalysis ( Table 2, entries 1 and 2). The decarboxylative indole borylation has also been performed under transition-metal-free conditions ( Table 2, entries 3 and 4). The reported protocols make use of N-hydroxyphthalimide esters, which are treated with pinB−Bpin under different conditions. Fu et al. [64] rely on the isonicotinate tertbutyl ester when refluxing in trifluorotoluene (TFT), while Glorius et al. [65] make use of pyridine  A decarboxylative cross-coupling represents an alternative procedure for the synthesis of indolylboronic acids. The borylation reaction can be performed by starting with either carboxylic acids [62] or thioester [63] under palladium or rhodium catalysis ( Table 2, entries 1 and 2). The decarboxylative indole borylation has also been performed under transition-metal-free conditions ( Table 2, entries 3 and 4). The reported protocols make use of N-hydroxyphthalimide esters, which are treated with pinB−Bpin under different conditions. Fu et al. [64] rely on the isonicotinate tertbutyl ester when refluxing in trifluorotoluene (TFT), while Glorius et al. [65] make use of pyridine  A decarboxylative cross-coupling represents an alternative procedure for the synthesis of indolylboronic acids. The borylation reaction can be performed by starting with either carboxylic acids [62] or thioester [63] under palladium or rhodium catalysis ( Table 2, entries 1 and 2). The decarboxylative indole borylation has also been performed under transition-metal-free conditions ( Table 2, entries 3 and 4). The reported protocols make use of N-hydroxyphthalimide esters, which are treated with pinB−Bpin under different conditions. Fu et al. [64] rely on the isonicotinate tertbutyl ester when refluxing in trifluorotoluene (TFT), while Glorius et al. [65] make use of pyridine  A decarboxylative cross-coupling represents an alternative procedure for the synthesis of indolylboronic acids. The borylation reaction can be performed by starting with either carboxylic acids [62] or thioester [63] under palladium or rhodium catalysis ( Table 2, entries 1 and 2). The decarboxylative indole borylation has also been performed under transition-metal-free conditions ( Table 2, entries 3 and 4). The reported protocols make use of N-hydroxyphthalimide esters, which are treated with pinB−Bpin under different conditions. Fu et al. [64] rely on the isonicotinate tertbutyl ester when refluxing in trifluorotoluene (TFT), while Glorius et al. [65] make use of pyridine  A decarboxylative cross-coupling represents an alternative procedure for the synthesis of indolylboronic acids. The borylation reaction can be performed by starting with either carboxylic acids [62] or thioester [63] under palladium or rhodium catalysis ( Table 2, entries 1 and 2). The decarboxylative indole borylation has also been performed under transition-metal-free conditions ( Table 2, entries 3 and 4). The reported protocols make use of N-hydroxyphthalimide esters, which are treated with pinB−Bpin under different conditions. Fu et al. [64] rely on the isonicotinate tertbutyl ester when refluxing in trifluorotoluene (TFT), while Glorius et al. [65] make use of pyridine  A decarboxylative cross-coupling represents an alternative procedure for the synthesis of indolylboronic acids. The borylation reaction can be performed by starting with either carboxylic acids [62] or thioester [63] under palladium or rhodium catalysis ( Table 2, entries 1 and 2). The decarboxylative indole borylation has also been performed under transition-metal-free conditions ( Table 2, entries 3 and 4). The reported protocols make use of N-hydroxyphthalimide esters, which are treated with pinB−Bpin under different conditions. Fu et al. [64] rely on the isonicotinate tertbutyl ester when refluxing in trifluorotoluene (TFT), while Glorius et al. [65] make use of pyridine A decarboxylative cross-coupling represents an alternative procedure for the synthesis of indolylboronic acids. The borylation reaction can be performed by starting with either carboxylic acids [62] or thioester [63] under palladium or rhodium catalysis ( Table 2, entries 1 and 2). The decarboxylative indole borylation has also been performed under transition-metal-free conditions ( Table 2, entries 3 and 4). The reported protocols make use of N-hydroxyphthalimide esters, which are treated with pinB−Bpin under different conditions. Fu et al. [64] rely on the isonicotinate tert-butyl ester when refluxing in trifluorotoluene (TFT), while Glorius et al. [65] make use of pyridine along with a 400-nm light-emitting diode (LED). A common feature of both decarboxylative borylations is the activation of pinB−Bpin by means of pyridine S7-1, thereby affording the ate complex S7-2 (Scheme 7). Next, the ate complex S7-2 undergoes a transformation into radical intermediates via electron transfer, and the formed radicals S7-3 [64] and S7-4 [65] are combined with the activated N-hydroxyphthalimide ester to accomplish the borylation sequence. The isolated yields of indolylboronic acid pinacol esters are moderate in all cases. along with a 400-nm light-emitting diode (LED). A common feature of both decarboxylative borylations is the activation of pinB−Bpin by means of pyridine S7-1, thereby affording the ate complex S7-2 (Scheme 7). Next, the ate complex S7-2 undergoes a transformation into radical intermediates via electron transfer, and the formed radicals S7-3 [64] and S7-4 [65] are combined with the activated N-hydroxyphthalimide ester to accomplish the borylation sequence. The isolated yields of indolylboronic acid pinacol esters are moderate in all cases.

Transition-Metal-Catalyzed Borylation of Indoles by Means of C-H Activation
Since the discovery of the iridium-mediated C−H borylation reactions of aromatic substrates by Iverson and Smith [66], as well as the later improvement of the reaction conditions into iridiumcatalyzed C−H borylation with B2pin2 or HBpin by Hartwig [67], the transition-metal-catalyzed borylation reactions have become one of the most versatile tools for the synthesis of borylated aromatic compounds. Heteroarenes, similar to indoles, can also undergo C−H borylation. The site selectivity of the reaction is an issue, as theoretically up to seven different sites can undergo C−H functionalization. Typically, in the case of unsubstituted indoles, the site selectivity is driven by electronic effects, as the reaction proceeds most readily at the C2 position where the C−H bond is the most acidic, and therefore, the most reactive. It is important to note, however, that selectivity can be overridden by steric factors. Several transition metals can be used for the borylation reactions of indoles, including iridium, platinum, nickel, and cobalt, although iridium-based catalytic systems with bipyridine ligands remain the most prevalent. In recent years, several site-selective and nonselective C−H borylation protocols of indoles have been developed, principally focusing on the recyclability of the expensive catalysts and site selectivity. Several boron sources can be used for the transition-metal-catalyzed C−H borylations of arenes (Scheme 8). The most common sources, namely along with a 400-nm light-emitting diode (LED). A common feature of both decarboxylative borylations is the activation of pinB−Bpin by means of pyridine S7-1, thereby affording the ate complex S7-2 (Scheme 7). Next, the ate complex S7-2 undergoes a transformation into radical intermediates via electron transfer, and the formed radicals S7-3 [64] and S7-4 [65] are combined with the activated N-hydroxyphthalimide ester to accomplish the borylation sequence. The isolated yields of indolylboronic acid pinacol esters are moderate in all cases.

Transition-Metal-Catalyzed Borylation of Indoles by Means of C-H Activation
Since the discovery of the iridium-mediated C−H borylation reactions of aromatic substrates by Iverson and Smith [66], as well as the later improvement of the reaction conditions into iridiumcatalyzed C−H borylation with B2pin2 or HBpin by Hartwig [67], the transition-metal-catalyzed borylation reactions have become one of the most versatile tools for the synthesis of borylated aromatic compounds. Heteroarenes, similar to indoles, can also undergo C−H borylation. The site selectivity of the reaction is an issue, as theoretically up to seven different sites can undergo C−H functionalization. Typically, in the case of unsubstituted indoles, the site selectivity is driven by electronic effects, as the reaction proceeds most readily at the C2 position where the C−H bond is the most acidic, and therefore, the most reactive. It is important to note, however, that selectivity can be overridden by steric factors. Several transition metals can be used for the borylation reactions of indoles, including iridium, platinum, nickel, and cobalt, although iridium-based catalytic systems with bipyridine ligands remain the most prevalent. In recent years, several site-selective and nonselective C−H borylation protocols of indoles have been developed, principally focusing on the recyclability of the expensive catalysts and site selectivity. Several boron sources can be used for the transition-metal-catalyzed C−H borylations of arenes (Scheme 8). The most common sources, namely along with a 400-nm light-emitting diode (LED). A common feature of both decarboxylative borylations is the activation of pinB−Bpin by means of pyridine S7-1, thereby affording the ate complex S7-2 (Scheme 7). Next, the ate complex S7-2 undergoes a transformation into radical intermediates via electron transfer, and the formed radicals S7-3 [64] and S7-4 [65] are combined with the activated N-hydroxyphthalimide ester to accomplish the borylation sequence. The isolated yields of indolylboronic acid pinacol esters are moderate in all cases.

Transition-Metal-Catalyzed Borylation of Indoles by Means of C-H Activation
Since the discovery of the iridium-mediated C−H borylation reactions of aromatic substrates by Iverson and Smith [66], as well as the later improvement of the reaction conditions into iridiumcatalyzed C−H borylation with B2pin2 or HBpin by Hartwig [67], the transition-metal-catalyzed borylation reactions have become one of the most versatile tools for the synthesis of borylated aromatic compounds. Heteroarenes, similar to indoles, can also undergo C−H borylation. The site selectivity of the reaction is an issue, as theoretically up to seven different sites can undergo C−H functionalization. Typically, in the case of unsubstituted indoles, the site selectivity is driven by electronic effects, as the reaction proceeds most readily at the C2 position where the C−H bond is the most acidic, and therefore, the most reactive. It is important to note, however, that selectivity can be overridden by steric factors. Several transition metals can be used for the borylation reactions of indoles, including iridium, platinum, nickel, and cobalt, although iridium-based catalytic systems with bipyridine ligands remain the most prevalent. In recent years, several site-selective and nonselective C−H borylation protocols of indoles have been developed, principally focusing on the recyclability of the expensive catalysts and site selectivity. Several boron sources can be used for the transition-metal-catalyzed C−H borylations of arenes (Scheme 8). The most common sources, namely 3 ONPhth along with a 400-nm light-emitting diode (LED). A common feature of both decarboxylative borylations is the activation of pinB−Bpin by means of pyridine S7-1, thereby affording the ate complex S7-2 (Scheme 7). Next, the ate complex S7-2 undergoes a transformation into radical intermediates via electron transfer, and the formed radicals S7-3 [64] and S7-4 [65] are combined with the activated N-hydroxyphthalimide ester to accomplish the borylation sequence. The isolated yields of indolylboronic acid pinacol esters are moderate in all cases.

Transition-Metal-Catalyzed Borylation of Indoles by Means of C-H Activation
Since the discovery of the iridium-mediated C−H borylation reactions of aromatic substrates by Iverson and Smith [66], as well as the later improvement of the reaction conditions into iridiumcatalyzed C−H borylation with B2pin2 or HBpin by Hartwig [67], the transition-metal-catalyzed borylation reactions have become one of the most versatile tools for the synthesis of borylated aromatic compounds. Heteroarenes, similar to indoles, can also undergo C−H borylation. The site selectivity of the reaction is an issue, as theoretically up to seven different sites can undergo C−H functionalization. Typically, in the case of unsubstituted indoles, the site selectivity is driven by electronic effects, as the reaction proceeds most readily at the C2 position where the C−H bond is the most acidic, and therefore, the most reactive. It is important to note, however, that selectivity can be overridden by steric factors. Several transition metals can be used for the borylation reactions of indoles, including iridium, platinum, nickel, and cobalt, although iridium-based catalytic systems with bipyridine ligands remain the most prevalent. In recent years, several site-selective and nonselective C−H borylation protocols of indoles have been developed, principally focusing on the recyclability of the expensive catalysts and site selectivity. Several boron sources can be used for the transition-metal-catalyzed C−H borylations of arenes (Scheme 8). The most common sources, namely along with a 400-nm light-emitting diode (LED). A common feature of both decarboxylative borylations is the activation of pinB−Bpin by means of pyridine S7-1, thereby affording the ate complex S7-2 (Scheme 7). Next, the ate complex S7-2 undergoes a transformation into radical intermediates via electron transfer, and the formed radicals S7-3 [64] and S7-4 [65] are combined with the activated N-hydroxyphthalimide ester to accomplish the borylation sequence. The isolated yields of indolylboronic acid pinacol esters are moderate in all cases.

Transition-Metal-Catalyzed Borylation of Indoles by Means of C-H Activation
Since the discovery of the iridium-mediated C−H borylation reactions of aromatic substrates by Iverson and Smith [66], as well as the later improvement of the reaction conditions into iridiumcatalyzed C−H borylation with B2pin2 or HBpin by Hartwig [67], the transition-metal-catalyzed borylation reactions have become one of the most versatile tools for the synthesis of borylated aromatic compounds. Heteroarenes, similar to indoles, can also undergo C−H borylation. The site selectivity of the reaction is an issue, as theoretically up to seven different sites can undergo C−H functionalization. Typically, in the case of unsubstituted indoles, the site selectivity is driven by electronic effects, as the reaction proceeds most readily at the C2 position where the C−H bond is the most acidic, and therefore, the most reactive. It is important to note, however, that selectivity can be overridden by steric factors. Several transition metals can be used for the borylation reactions of indoles, including iridium, platinum, nickel, and cobalt, although iridium-based catalytic systems with bipyridine ligands remain the most prevalent. In recent years, several site-selective and nonselective C−H borylation protocols of indoles have been developed, principally focusing on the recyclability of the expensive catalysts and site selectivity. Several boron sources can be used for the transition-metal-catalyzed C−H borylations of arenes (Scheme 8). The most common sources, namely 4 ONPhth pinB−Bpin (3.5 equiv.), pyridine (1.5 equiv.) Cs 2 CO 3 (0.5 equiv.), EtOAc, 35 • C, 400 nm, 24 h along with a 400-nm light-emitting diode (LED). A common feature of both decarboxylative borylations is the activation of pinB−Bpin by means of pyridine S7-1, thereby affording the ate complex S7-2 (Scheme 7). Next, the ate complex S7-2 undergoes a transformation into radical intermediates via electron transfer, and the formed radicals S7-3 [64] and S7-4 [65] are combined with the activated N-hydroxyphthalimide ester to accomplish the borylation sequence. The isolated yields of indolylboronic acid pinacol esters are moderate in all cases.

Transition-Metal-Catalyzed Borylation of Indoles by Means of C-H Activation
Since the discovery of the iridium-mediated C−H borylation reactions of aromatic substrates by Iverson and Smith [66], as well as the later improvement of the reaction conditions into iridiumcatalyzed C−H borylation with B2pin2 or HBpin by Hartwig [67], the transition-metal-catalyzed borylation reactions have become one of the most versatile tools for the synthesis of borylated aromatic compounds. Heteroarenes, similar to indoles, can also undergo C−H borylation. The site selectivity of the reaction is an issue, as theoretically up to seven different sites can undergo C−H functionalization. Typically, in the case of unsubstituted indoles, the site selectivity is driven by electronic effects, as the reaction proceeds most readily at the C2 position where the C−H bond is the most acidic, and therefore, the most reactive. It is important to note, however, that selectivity can be overridden by steric factors. Several transition metals can be used for the borylation reactions of indoles, including iridium, platinum, nickel, and cobalt, although iridium-based catalytic systems with bipyridine ligands remain the most prevalent. In recent years, several site-selective and nonselective C−H borylation protocols of indoles have been developed, principally focusing on the recyclability of the expensive catalysts and site selectivity. Several boron sources can be used for the transition-metal-catalyzed C−H borylations of arenes (Scheme 8). The most common sources, namely along with a 400-nm light-emitting diode (LED). A common feature of both decarboxylative borylations is the activation of pinB−Bpin by means of pyridine S7-1, thereby affording the ate complex S7-2 (Scheme 7). Next, the ate complex S7-2 undergoes a transformation into radical intermediates via electron transfer, and the formed radicals S7-3 [64] and S7-4 [65] are combined with the activated N-hydroxyphthalimide ester to accomplish the borylation sequence. The isolated yields of indolylboronic acid pinacol esters are moderate in all cases.

Transition-Metal-Catalyzed Borylation of Indoles by Means of C-H Activation
Since the discovery of the iridium-mediated C−H borylation reactions of aromatic substrates by Iverson and Smith [66], as well as the later improvement of the reaction conditions into iridiumcatalyzed C−H borylation with B2pin2 or HBpin by Hartwig [67], the transition-metal-catalyzed borylation reactions have become one of the most versatile tools for the synthesis of borylated aromatic compounds. Heteroarenes, similar to indoles, can also undergo C−H borylation. The site selectivity of the reaction is an issue, as theoretically up to seven different sites can undergo C−H functionalization. Typically, in the case of unsubstituted indoles, the site selectivity is driven by electronic effects, as the reaction proceeds most readily at the C2 position where the C−H bond is the most acidic, and therefore, the most reactive. It is important to note, however, that selectivity can be overridden by steric factors. Several transition metals can be used for the borylation reactions of indoles, including iridium, platinum, nickel, and cobalt, although iridium-based catalytic systems with bipyridine ligands remain the most prevalent. In recent years, several site-selective and nonselective C−H borylation protocols of indoles have been developed, principally focusing on the recyclability of the expensive catalysts and site selectivity. Several boron sources can be used for the transition-metal-catalyzed C−H borylations of arenes (Scheme 8). The most common sources, namely Scheme 7. A mechanistic proposal for transition-metal-free borylation.

Transition-Metal-Catalyzed Borylation of Indoles by Means of C-H Activation
Since the discovery of the iridium-mediated C−H borylation reactions of aromatic substrates by Iverson and Smith [66], as well as the later improvement of the reaction conditions into iridium-catalyzed C−H borylation with B 2 pin 2 or HBpin by Hartwig [67], the transition-metal-catalyzed borylation reactions have become one of the most versatile tools for the synthesis of borylated aromatic compounds. Heteroarenes, similar to indoles, can also undergo C−H borylation. The site selectivity of the reaction is an issue, as theoretically up to seven different sites can undergo C−H functionalization. Typically, in the case of unsubstituted indoles, the site selectivity is driven by electronic effects, as the reaction proceeds most readily at the C2 position where the C−H bond is the most acidic, and therefore, the most reactive. It is important to note, however, that selectivity can be overridden by steric factors. Several transition metals can be used for the borylation reactions of indoles, including iridium, platinum, nickel, and cobalt, although iridium-based catalytic systems with bipyridine ligands remain the most prevalent. In recent years, several site-selective and non-selective C−H borylation protocols of indoles have been developed, principally focusing on the recyclability of the expensive catalysts and site selectivity. Several boron sources can be used for the transition-metal-catalyzed C−H borylations of arenes (Scheme 8). The most common sources, namely HBpin (S8-1) and B 2 pin 2 (S8-2), were established by Hartwig in relation to the transition-metal-catalyzed C2 borylation of indoles in the early 2000s [68].
Chattopadhyay recently developed L-shaped ligands for the selective borylation of the remote sites (meta and para) of aromatic esters [71] and amides [72], and the protocol could also be applied to indoles. Indoles that lacked the ester-or amide-directing group did not undergo the borylation reaction, most likely due to the preferential complexation of the indole NH group to the catalyst, thus inhibiting the borylation. Interestingly, following the introduction of the directing group onto the indole scaffold, the borylation proceeded without meta-or para-selectivity, but always into the C2 position (S10-1b,2b,3b), which suggests that electronic effects in the case of indoles S10-1a,2a,3a played a crucial role in the site selectivity (Scheme 10). Exchanging the L-shaped ligands for simple tbdpy ligands under these reaction conditions resulted in the formation of complex mixtures of unselectively borylated indoles.
Chattopadhyay recently developed L-shaped ligands for the selective borylation of the remote sites (meta and para) of aromatic esters [71] and amides [72], and the protocol could also be applied to indoles. Indoles that lacked the ester-or amide-directing group did not undergo the borylation reaction, most likely due to the preferential complexation of the indole NH group to the catalyst, thus inhibiting the borylation. Interestingly, following the introduction of the directing group onto the indole scaffold, the borylation proceeded without meta-or para-selectivity, but always into the C2 position (S10-1b,2b,3b), which suggests that electronic effects in the case of indoles S10-1a,2a,3a played a crucial role in the site selectivity (Scheme 10). Exchanging the L-shaped ligands for simple tbdpy ligands under these reaction conditions resulted in the formation of complex mixtures of unselectively borylated indoles. Chattopadhyay recently developed L-shaped ligands for the selective borylation of the remote sites (meta and para) of aromatic esters [71] and amides [72], and the protocol could also be applied to indoles. Indoles that lacked the ester-or amide-directing group did not undergo the borylation reaction, most likely due to the preferential complexation of the indole NH group to the catalyst, thus inhibiting the borylation. Interestingly, following the introduction of the directing group onto the indole scaffold, the borylation proceeded without metaor para-selectivity, but always into the C2 position (S10-1b,2b,3b), which suggests that electronic effects in the case of indoles S10-1a,2a,3a played a crucial role in the site selectivity (Scheme 10). Exchanging the L-shaped ligands for simple tbdpy ligands under these reaction conditions resulted in the formation of complex mixtures of unselectively borylated indoles. As shown above, the ester and amide functional groups remain stable during the iridiumcatalyzed C−H borylation, although the aldehyde group is not stable. Therefore, Ito and Ishiyama developed a protocol whereby heteroaromatic pentafluorophenyl aldimines undergo iridiumcatalyzed C−H borylation in moderate to high yields, with one example being the indole substrate S11-1 [73]. The aldimine functional group serves as both a directing group and a protection group, and it can be easily hydrolyzed so as to produce aldehydes (Scheme 11). Scheme 11. Aldimine-directed borylation of the protected indolyl aldehyde S11-1.
In an effort to enhance the prospects of catalyst recovery and recycling, several groups have developed iridium-based heterogeneous catalysts for the C−H borylation of aromatic and heteroaromatic compounds. For instance, Jones et al. prepared and applied the mesoporous silicasupported bipyridine-based iridium catalyst bpy-SBA-15-Ir (S12-1) for the borylation of indole (Scheme 12) [74]. The catalyst did not reach a turnover number (TON) higher than 136, although it could be repeatedly reused following simple filtration with only the gradual loss of activity with subsequent runs. Similarly, Inagaki developed the heterogeneous catalyst Ir-bpy-PMO (S12-2), which in combination with the inexpensive boron source HBpin facilitated the C−H borylation of aromatic and heteroaromatic compounds, while the catalytic activity of Ir-bpy-PMO was comparable to that of homogenous catalytic systems (Scheme 12) [75]. Another example of a heterogeneous catalyst for C−H borylation reactions is based on the covalent triazine framework (CTF) prepared by Van Der Voort et al. They developed a bipyridine-based CTF and then metalated it with the Ir(I) complex so as to prepare an air-stable catalyst (S12-3) for the C−H borylation of various aromatic compounds, including indole [76]. The borylation reactions proceeded in non-polar solvent under mild reaction conditions, and the catalyst could be recycled at least five times with only a small decrease in activity (Scheme 12). Excellent results have been achieved with heterogeneous catalysis when using the bipyridine-based metal-organic framework (mBPV-MOF-Ir) (S12-4) and the 1,10-phenanthrolinebased metal-organic framework (mPT-MOF-Ir) catalysts developed by Lin et al. [77]. They used them for the C−H borylation of various aromatic and heteroaromatic substrates with very low catalyst loadings and excellent isolated yields of borylated products. Although prolonged reaction periods and high temperatures were required to achieve full conversion, the products were obtained by As shown above, the ester and amide functional groups remain stable during the iridium-catalyzed C−H borylation, although the aldehyde group is not stable. Therefore, Ito and Ishiyama developed a protocol whereby heteroaromatic pentafluorophenyl aldimines undergo iridium-catalyzed C−H borylation in moderate to high yields, with one example being the indole substrate S11-1 [73]. The aldimine functional group serves as both a directing group and a protection group, and it can be easily hydrolyzed so as to produce aldehydes (Scheme 11). As shown above, the ester and amide functional groups remain stable during the iridiumcatalyzed C−H borylation, although the aldehyde group is not stable. Therefore, Ito and Ishiyama developed a protocol whereby heteroaromatic pentafluorophenyl aldimines undergo iridiumcatalyzed C−H borylation in moderate to high yields, with one example being the indole substrate S11-1 [73]. The aldimine functional group serves as both a directing group and a protection group, and it can be easily hydrolyzed so as to produce aldehydes (Scheme 11). Scheme 11. Aldimine-directed borylation of the protected indolyl aldehyde S11-1.
In an effort to enhance the prospects of catalyst recovery and recycling, several groups have developed iridium-based heterogeneous catalysts for the C−H borylation of aromatic and heteroaromatic compounds. For instance, Jones et al. prepared and applied the mesoporous silicasupported bipyridine-based iridium catalyst bpy-SBA-15-Ir (S12-1) for the borylation of indole (Scheme 12) [74]. The catalyst did not reach a turnover number (TON) higher than 136, although it could be repeatedly reused following simple filtration with only the gradual loss of activity with subsequent runs. Similarly, Inagaki developed the heterogeneous catalyst Ir-bpy-PMO (S12-2), which in combination with the inexpensive boron source HBpin facilitated the C−H borylation of aromatic and heteroaromatic compounds, while the catalytic activity of Ir-bpy-PMO was comparable to that of homogenous catalytic systems (Scheme 12) [75]. Another example of a heterogeneous catalyst for C−H borylation reactions is based on the covalent triazine framework (CTF) prepared by Van Der Voort et al. They developed a bipyridine-based CTF and then metalated it with the Ir(I) complex so as to prepare an air-stable catalyst (S12-3) for the C−H borylation of various aromatic compounds, including indole [76]. The borylation reactions proceeded in non-polar solvent under mild reaction conditions, and the catalyst could be recycled at least five times with only a small decrease in activity (Scheme 12). Excellent results have been achieved with heterogeneous catalysis when using the bipyridine-based metal-organic framework (mBPV-MOF-Ir) (S12-4) and the 1,10-phenanthrolinebased metal-organic framework (mPT-MOF-Ir) catalysts developed by Lin et al. [77]. They used them for the C−H borylation of various aromatic and heteroaromatic substrates with very low catalyst loadings and excellent isolated yields of borylated products. Although prolonged reaction periods and high temperatures were required to achieve full conversion, the products were obtained by Scheme 11. Aldimine-directed borylation of the protected indolyl aldehyde S11-1.
In an effort to enhance the prospects of catalyst recovery and recycling, several groups have developed iridium-based heterogeneous catalysts for the C−H borylation of aromatic and heteroaromatic compounds. For instance, Jones et al. prepared and applied the mesoporous silicasupported bipyridine-based iridium catalyst bpy-SBA-15-Ir (S12-1) for the borylation of indole (Scheme 12) [74]. The catalyst did not reach a turnover number (TON) higher than 136, although it could be repeatedly reused following simple filtration with only the gradual loss of activity with subsequent runs. Similarly, Inagaki developed the heterogeneous catalyst Ir-bpy-PMO (S12-2), which in combination with the inexpensive boron source HBpin facilitated the C−H borylation of aromatic and heteroaromatic compounds, while the catalytic activity of Ir-bpy-PMO was comparable to that of homogenous catalytic systems (Scheme 12) [75]. Another example of a heterogeneous catalyst for C−H borylation reactions is based on the covalent triazine framework (CTF) prepared by Van Der Voort et al. They developed a bipyridine-based CTF and then metalated it with the Ir(I) complex so as to prepare an air-stable catalyst (S12-3) for the C−H borylation of various aromatic compounds, including indole [76]. The borylation reactions proceeded in non-polar solvent under mild reaction conditions, and the catalyst could be recycled at least five times with only a small decrease in activity (Scheme 12). Excellent results have been achieved with heterogeneous catalysis when using the bipyridine-based metal-organic framework (mBPV-MOF-Ir) (S12-4) and the 1,10-phenanthroline-based metal-organic framework (mPT-MOF-Ir) catalysts developed by Lin et al. [77]. They used them for the C−H borylation of various aromatic and heteroaromatic substrates with very low catalyst loadings and excellent isolated yields of borylated products. Although prolonged reaction periods and high temperatures were required to achieve full conversion, the products were obtained by removing the catalyst via simple centrifugation and the catalysts could be recycled at least 15 times with no apparent loss of activity (Scheme 12). When using the mBPV-MOF-Ir catalyst, a TON of 9000 was achieved for the borylation of indole and the leached iridium content was found to be 0.3 ppm. Very recently, the first-of-its-kind mechanochemical iridium-catalyzed C−H borylation of indoles S13-1 was described by Kubota and Ito. The borylation reaction took place in a steel jar in an air atmosphere while the starting compounds were ground by a steel ball for 99 min [78]. The authors report that the careful selection of the grinding apparatus was vital if the reaction was to give results. For substrates with melting points higher than 70 °C, liquid-assisted grinding (LAG) was needed, although a catalytic amount of the organic solvent was sufficient. Several variously substituted 2indolyl boronates S13-2 were prepared in this way. The isolated yields (in parentheses) differed substantially from the NMR yields of the products due to the reported fast hydrolysis on silica gel (Scheme 13).
In an effort to render transition-metal-catalyzed borylation more economically feasible, several methods based on more abundant metals, such as cobalt, nickel, and platinum, have been developed in recent years. Some of the developed protocols are also applicable for indoles, although in most cases, only a very narrow indole substrate scope was tested. In the identified publications, only indoles with unsubstituted C2 positions were tested; therefore, the borylation proceeded selectively into the C2 position in all cases. Very recently, the first-of-its-kind mechanochemical iridium-catalyzed C−H borylation of indoles S13-1 was described by Kubota and Ito. The borylation reaction took place in a steel jar in an air atmosphere while the starting compounds were ground by a steel ball for 99 min [78]. The authors report that the careful selection of the grinding apparatus was vital if the reaction was to give results. For substrates with melting points higher than 70 • C, liquid-assisted grinding (LAG) was needed, although a catalytic amount of the organic solvent was sufficient. Several variously substituted 2-indolyl boronates S13-2 were prepared in this way. The isolated yields (in parentheses) differed substantially from the NMR yields of the products due to the reported fast hydrolysis on silica gel (Scheme 13).
In an effort to render transition-metal-catalyzed borylation more economically feasible, several methods based on more abundant metals, such as cobalt, nickel, and platinum, have been developed in recent years. Some of the developed protocols are also applicable for indoles, although in most cases, only a very narrow indole substrate scope was tested. In the identified publications, only indoles with unsubstituted C2 positions were tested; therefore, the borylation proceeded selectively into the C2 position in all cases. Chirik used a series of pincer-type ligand cobalt complexes for the development of the cobaltcatalyzed borylation of aromatic compounds [79]. The complex S14-3 proved to be effective in terms of the selective borylation of indole S14-1 into the C2 position (Scheme 14). Later, Chirik broadened his application of the cobalt complexes for C−H borylation by means of the preparation and evaluation of a new, air-stable and easily preparable cobalt precatalyst, namely ( Ar Tpy)Co(OAc)2 (S14-4), which was also applicable for the borylation of indoles (Scheme 14) [80]. Recently, Smith and Maleczka have shown that a cobalt-based catalyst supported by NHC ligands (S14-5) can also be used for the borylation of benzylic and heteroaromatic compounds, including the indole S14-1, in moderate yields (Scheme 14) [81].
Nickel-catalyzed C2 borylations of various arenes and heteroarenes have been developed by the Chatani group [82]. In this instance, the catalytic system consisted of the transition metal and an NHC ligand. The reaction proceeded selectively into the C2 position in the case of indoles with nitrogen atoms variously substituted by the alkyl or benzyl groups (S15-1). Similar selectivity was achieved when positions 3 and 5 were substituted by the methyl (S15-2) or halogen and methoxy groups (S15-3), respectively (Scheme 15). The authors managed to employ cheap and air-stable Ni(OAc)2 rather than Ni(cod)2 for the gram-scale preparations, and they achieved excellent results. Similar conditions were used for the borylation of indoles under platinum catalysis conditions, although HBpin proved to be unreactive; therefore, B2pin2 was used as the boron source [83]. The reaction with B2pin2 proceeded selectively at the 2 position, and it offered the indoles S16-2 in moderate to very good yields (Scheme 16). Iwasawa also applied platinum catalysis for the borylation of indoles using the PSiN-pincer platinum complex, albeit with diminished selectivity [84]. Chirik used a series of pincer-type ligand cobalt complexes for the development of the cobalt-catalyzed borylation of aromatic compounds [79]. The complex S14-3 proved to be effective in terms of the selective borylation of indole S14-1 into the C2 position (Scheme 14). Later, Chirik broadened his application of the cobalt complexes for C−H borylation by means of the preparation and evaluation of a new, air-stable and easily preparable cobalt precatalyst, namely ( Ar Tpy)Co(OAc) 2 (S14-4), which was also applicable for the borylation of indoles (Scheme 14) [80]. Recently, Smith and Maleczka have shown that a cobalt-based catalyst supported by NHC ligands (S14-5) can also be used for the borylation of benzylic and heteroaromatic compounds, including the indole S14-1, in moderate yields (Scheme 14) [81]. Chirik used a series of pincer-type ligand cobalt complexes for the development of the cobaltcatalyzed borylation of aromatic compounds [79]. The complex S14-3 proved to be effective in terms of the selective borylation of indole S14-1 into the C2 position (Scheme 14). Later, Chirik broadened his application of the cobalt complexes for C−H borylation by means of the preparation and evaluation of a new, air-stable and easily preparable cobalt precatalyst, namely ( Ar Tpy)Co(OAc)2 (S14-4), which was also applicable for the borylation of indoles (Scheme 14) [80]. Recently, Smith and Maleczka have shown that a cobalt-based catalyst supported by NHC ligands (S14-5) can also be used for the borylation of benzylic and heteroaromatic compounds, including the indole S14-1, in moderate yields (Scheme 14) [81].
Nickel-catalyzed C2 borylations of various arenes and heteroarenes have been developed by the Chatani group [82]. In this instance, the catalytic system consisted of the transition metal and an NHC ligand. The reaction proceeded selectively into the C2 position in the case of indoles with nitrogen atoms variously substituted by the alkyl or benzyl groups (S15-1). Similar selectivity was achieved when positions 3 and 5 were substituted by the methyl (S15-2) or halogen and methoxy groups (S15-3), respectively (Scheme 15). The authors managed to employ cheap and air-stable Ni(OAc)2 rather than Ni(cod)2 for the gram-scale preparations, and they achieved excellent results. Similar conditions were used for the borylation of indoles under platinum catalysis conditions, although HBpin proved to be unreactive; therefore, B2pin2 was used as the boron source [83]. The reaction with B2pin2 proceeded selectively at the 2 position, and it offered the indoles S16-2 in moderate to very good yields (Scheme 16). Iwasawa also applied platinum catalysis for the borylation of indoles using the PSiN-pincer platinum complex, albeit with diminished selectivity [84]. Nickel-catalyzed C2 borylations of various arenes and heteroarenes have been developed by the Chatani group [82]. In this instance, the catalytic system consisted of the transition metal and an NHC ligand. The reaction proceeded selectively into the C2 position in the case of indoles with nitrogen atoms variously substituted by the alkyl or benzyl groups (S15-1). Similar selectivity was achieved when positions 3 and 5 were substituted by the methyl (S15-2) or halogen and methoxy groups (S15-3), respectively (Scheme 15). The authors managed to employ cheap and air-stable Ni(OAc) 2 rather than Ni(cod) 2 for the gram-scale preparations, and they achieved excellent results. Similar conditions were used for the borylation of indoles under platinum catalysis conditions, although HBpin proved to be unreactive; therefore, B 2 pin 2 was used as the boron source [83]. The reaction with B 2 pin 2 proceeded selectively at the 2 position, and it offered the indoles S16-2 in moderate to very good yields (Scheme 16). Iwasawa also applied platinum catalysis for the borylation of indoles using the PSiN-pincer platinum complex, albeit with diminished selectivity [84].

C3-Selective Borylation
In 2013, Oestreich reported the new and synthetically useful C3-selective borylation of indoles S17-1 by means of the catalytic generation of borenium ions from HBpin [85]. The protocol required no added base, as H2 was released as the sole by-product and allowed to install the Bpin group onto the indole substrate via a SEAr reaction mechanism. Over the course of the reaction, the B−H bond is split by the ruthenium(II) thiolate complex, thereby affording ruthenium(II) hydride and borenium ions, which undergo an attack by the most nucleophilic site of the indole substrate. The subsequent deprotonation offers C3-borylated indoles in moderate to high yields (Scheme 17). Scheme 17. Ruthenium-catalyzed C3 borylation with HBpin, including the outlined mechanism.
The regioselectivity of the iridium-catalyzed C−H borylation of indoles can be altered by installing a bulky group onto the indole substrate. The tert-butoxycarbonyl (Boc) group can be used

C3-Selective Borylation
In 2013, Oestreich reported the new and synthetically useful C3-selective borylation of indoles S17-1 by means of the catalytic generation of borenium ions from HBpin [85]. The protocol required no added base, as H2 was released as the sole by-product and allowed to install the Bpin group onto the indole substrate via a SEAr reaction mechanism. Over the course of the reaction, the B−H bond is split by the ruthenium(II) thiolate complex, thereby affording ruthenium(II) hydride and borenium ions, which undergo an attack by the most nucleophilic site of the indole substrate. The subsequent deprotonation offers C3-borylated indoles in moderate to high yields (Scheme 17). Scheme 17. Ruthenium-catalyzed C3 borylation with HBpin, including the outlined mechanism.
The regioselectivity of the iridium-catalyzed C−H borylation of indoles can be altered by installing a bulky group onto the indole substrate. The tert-butoxycarbonyl (Boc) group can be used

C3-Selective Borylation
In 2013, Oestreich reported the new and synthetically useful C3-selective borylation of indoles S17-1 by means of the catalytic generation of borenium ions from HBpin [85]. The protocol required no added base, as H 2 was released as the sole by-product and allowed to install the Bpin group onto the indole substrate via a S E Ar reaction mechanism. Over the course of the reaction, the B−H bond is split by the ruthenium(II) thiolate complex, thereby affording ruthenium(II) hydride and borenium ions, which undergo an attack by the most nucleophilic site of the indole substrate. The subsequent deprotonation offers C3-borylated indoles in moderate to high yields (Scheme 17).

C3-Selective Borylation
In 2013, Oestreich reported the new and synthetically useful C3-selective borylation of indoles S17-1 by means of the catalytic generation of borenium ions from HBpin [85]. The protocol required no added base, as H2 was released as the sole by-product and allowed to install the Bpin group onto the indole substrate via a SEAr reaction mechanism. Over the course of the reaction, the B−H bond is split by the ruthenium(II) thiolate complex, thereby affording ruthenium(II) hydride and borenium ions, which undergo an attack by the most nucleophilic site of the indole substrate. The subsequent deprotonation offers C3-borylated indoles in moderate to high yields (Scheme 17). Scheme 17. Ruthenium-catalyzed C3 borylation with HBpin, including the outlined mechanism.
The regioselectivity of the iridium-catalyzed C−H borylation of indoles can be altered by installing a bulky group onto the indole substrate. The tert-butoxycarbonyl (Boc) group can be used Scheme 17. Ruthenium-catalyzed C3 borylation with HBpin, including the outlined mechanism.
The regioselectivity of the iridium-catalyzed C−H borylation of indoles can be altered by installing a bulky group onto the indole substrate. The tert-butoxycarbonyl (Boc) group can be used in this way for nitrogen-containing heterocycles such as pyrroles, indoles, azaindoles, and pyrazoles where the N-Boc-protected pyrroles and indole S18-1 are selectively borylated into the 3 position [86]. However, the installation and removal of the directing group extend the time required for the overall procedure. Therefore, it is desirable to use a directing group that can be installed and removed without requiring the isolation of the intermediates. The protocol developed by Smith and Maleczka can be used as an example here, with the Bpin group serving as a traceless directing group for the selective C−H borylation of indoles into the 3 position (Scheme 18) [87]. The indole S18-2 is smoothly converted into the N-borylated indole S18-3 by means of the reaction with HBpin. The addition of Et 3 N is essential if the reaction is to proceed, as the coordination of the lone nitrogen pair with the boron center in the HBpin renders the B−H bond hydridic enough to react with as weak an acid as S18-2. The addition of the iridium catalyst into the reaction mixture causes the C−H borylation to proceed in the C3 position, while the aqueous workup gives 3-borylated indole S18-4 in a 57% yield (Scheme 18).
Molecules 2019, 24, x FOR PEER REVIEW 12 of 46 in this way for nitrogen-containing heterocycles such as pyrroles, indoles, azaindoles, and pyrazoles where the N-Boc-protected pyrroles and indole S18-1 are selectively borylated into the 3 position [86]. However, the installation and removal of the directing group extend the time required for the overall procedure. Therefore, it is desirable to use a directing group that can be installed and removed without requiring the isolation of the intermediates. The protocol developed by Smith and Maleczka can be used as an example here, with the Bpin group serving as a traceless directing group for the selective C−H borylation of indoles into the 3 position (Scheme 18) [87]. The indole S18-2 is smoothly converted into the N-borylated indole S18-3 by means of the reaction with HBpin. The addition of Et3N is essential if the reaction is to proceed, as the coordination of the lone nitrogen pair with the boron center in the HBpin renders the B−H bond hydridic enough to react with as weak an acid as S18-2. The addition of the iridium catalyst into the reaction mixture causes the C−H borylation to proceed in the C3 position, while the aqueous workup gives 3-borylated indole S18-4 in a 57% yield (Scheme 18).

Scheme 18.
Stepwise and traceless protecting group protocols that complement C3 borylations of indoles.
Colacot et al. studied the causes of prior inconsistent results and diminished the catalytic activity of the Ir complexes formed in situ using the simple and cheap ligand 1,10-phenanthroline. They determined that catalytically inactive cationic [Ir(COD)(phen)] + Cl -(S19-2) is rapidly formed in noncoordinating solvents, thereby diminishing the reactivity (Scheme 19). The authors managed to isolate the active complex [Ir(Cl)(COD)(phen)] (S19-1) and to utilize it for the selective borylation of the Boc-protected indoles S19-3. They achieved excellent results and then applied the catalyst based on the cheap ligand for the one-pot total synthesis of meridianin G (S19-4), thereby achieving an excellent overall yield [88].

Scheme 18.
Stepwise and traceless protecting group protocols that complement C3 borylations of indoles.
Colacot et al. studied the causes of prior inconsistent results and diminished the catalytic activity of the Ir complexes formed in situ using the simple and cheap ligand 1,10-phenanthroline. They determined that catalytically inactive cationic [Ir(COD)(phen)] + Cl -(S19-2) is rapidly formed in non-coordinating solvents, thereby diminishing the reactivity (Scheme 19). The authors managed to isolate the active complex [Ir(Cl)(COD)(phen)] (S19-1) and to utilize it for the selective borylation of the Boc-protected indoles S19-3. They achieved excellent results and then applied the catalyst based on the cheap ligand for the one-pot total synthesis of meridianin G (S19-4), thereby achieving an excellent overall yield [88].

C6-, C7-Selective Borylation
Only one example of the selective C6-borylation of indoles can be found in the literature, and even it is not strictly C6-selective but rather C6-preferential. It was developed by Baran et al. in an attempt to achieve the first total syntheses of verruculogen and fumitremorgin A. The C6 selectivity is achieved by means of the careful substrate selection of only 3-substituted indoles S20-1 and the protection of the indole nitrogen by the robust TIPS group, thereby disabling the C−H activation reaction in the otherwise more reactive positions C2, C3, or C7 [89]. By optimizing the reaction conditions, the authors achieved good isolated yields of S20-3 as well as up to 14:1 C6:C5 selectivity on a limited substrate scope (Scheme 20). Scheme 20. C6-preferential iridium-catalyzed borylation of 3-substituted indoles.
Selective transition-metal-catalyzed C−H functionalization at the 7-position typically requires a substituent to be present at the 2-position so as to block reactivity at that site [90][91][92]. An example from the recent literature was developed by Takai, who exploited the iridium-catalyzed silylation of Scheme 19. C3-selective borylation of Boc-protected indoles based on the cheap 1,10-phenanthroline ligand.

C6-, C7-Selective Borylation
Only one example of the selective C6-borylation of indoles can be found in the literature, and even it is not strictly C6-selective but rather C6-preferential. It was developed by Baran et al. in an attempt to achieve the first total syntheses of verruculogen and fumitremorgin A. The C6 selectivity is achieved by means of the careful substrate selection of only 3-substituted indoles S20-1 and the protection of the indole nitrogen by the robust TIPS group, thereby disabling the C−H activation reaction in the otherwise more reactive positions C2, C3, or C7 [89]. By optimizing the reaction conditions, the authors achieved good isolated yields of S20-3 as well as up to 14:1 C6:C5 selectivity on a limited substrate scope (Scheme 20).

C6-, C7-Selective Borylation
Only one example of the selective C6-borylation of indoles can be found in the literature, and even it is not strictly C6-selective but rather C6-preferential. It was developed by Baran et al. in an attempt to achieve the first total syntheses of verruculogen and fumitremorgin A. The C6 selectivity is achieved by means of the careful substrate selection of only 3-substituted indoles S20-1 and the protection of the indole nitrogen by the robust TIPS group, thereby disabling the C−H activation reaction in the otherwise more reactive positions C2, C3, or C7 [89]. By optimizing the reaction conditions, the authors achieved good isolated yields of S20-3 as well as up to 14:1 C6:C5 selectivity on a limited substrate scope (Scheme 20). Scheme 20. C6-preferential iridium-catalyzed borylation of 3-substituted indoles.
Selective transition-metal-catalyzed C−H functionalization at the 7-position typically requires a substituent to be present at the 2-position so as to block reactivity at that site [90][91][92]. An example from the recent literature was developed by Takai, who exploited the iridium-catalyzed silylation of Scheme 20. C6-preferential iridium-catalyzed borylation of 3-substituted indoles.
Selective transition-metal-catalyzed C−H functionalization at the 7-position typically requires a substituent to be present at the 2-position so as to block reactivity at that site [90][91][92]. An example from the recent literature was developed by Takai, who exploited the iridium-catalyzed silylation of indole (S21-1) to functionalize the 2-position, followed by iridium-catalyzed borylation in the 7-position in a one-pot manner so as to prepare S21-2 (Scheme 21). indole (S21-1) to functionalize the 2-position, followed by iridium-catalyzed borylation in the 7position in a one-pot manner so as to prepare S21-2 (Scheme 21).
The requirement for an occupied 2-position can be avoided by means of the introduction of a silyl-directing group onto the nitrogen atom, as demonstrated by Hartwig in his one-pot protocol consisting of the Ru-catalyzed silylation of indoles, followed by the Ir-catalyzed borylation of the formed silylindole. The mild hydrolysis of the silyl group then selectively afforded the C7-borylated indoles S22-1 (Scheme 22) [93]. The borylation selectivity most likely arises from the formation of the five-membered metallacycle S22-2 through the C−H bond cleavage at the 7-position rather than of the four-membered metallacycle at the 2-position. Sperry applied an analogous approach for the synthesis of indolequinone natural products where even 5-and 6-methoxy-substituted indoles reacted selectively at the 7-position, thereby broadening the applicability of the developed protocol [94]. Inspired by Hartwig's protocol, Movassaghi et al. developed a more streamlined C7-selective borylation of 3-alkylindoles. Their design was based on the diboronation/protodeboronation sequence. The authors managed to develop reaction conditions wherein the 3-substituted indoles S23-1 underwent iridium-catalyzed C2/C7 diboronation with an excess of HBpin so as to form S23-2 in situ, and subsequently, selective C2 protodeboronation either with a large excess of trifluoroacetic acid or a catalytic amount of Pd(OAc)2 in AcOH (Scheme 23) [95]. Smith and Maleczka later expanded upon this protocol. They developed a complementary method for selective C2 deborylation using the iridium-catalyzed deborylation of 2,7-diborylated indoles to prepare 7-borylated indoles [96]. They also determined that bismuth(III) acetate can be used for the C2 and C7 protodeboronation of indoles. They prepared a series of diborylated and triborylated indoles that underwent selective C2 and C7 deborylation with Bi(OAc)3 in methanol so as to prepare mono-and bisborylated indoles [97]. The requirement for an occupied 2-position can be avoided by means of the introduction of a silyl-directing group onto the nitrogen atom, as demonstrated by Hartwig in his one-pot protocol consisting of the Ru-catalyzed silylation of indoles, followed by the Ir-catalyzed borylation of the formed silylindole. The mild hydrolysis of the silyl group then selectively afforded the C7-borylated indoles S22-1 (Scheme 22) [93]. The borylation selectivity most likely arises from the formation of the five-membered metallacycle S22-2 through the C−H bond cleavage at the 7-position rather than of the four-membered metallacycle at the 2-position. Sperry applied an analogous approach for the synthesis of indolequinone natural products where even 5-and 6-methoxy-substituted indoles reacted selectively at the 7-position, thereby broadening the applicability of the developed protocol [94]. indole (S21-1) to functionalize the 2-position, followed by iridium-catalyzed borylation in the 7position in a one-pot manner so as to prepare S21-2 (Scheme 21).
The requirement for an occupied 2-position can be avoided by means of the introduction of a silyl-directing group onto the nitrogen atom, as demonstrated by Hartwig in his one-pot protocol consisting of the Ru-catalyzed silylation of indoles, followed by the Ir-catalyzed borylation of the formed silylindole. The mild hydrolysis of the silyl group then selectively afforded the C7-borylated indoles S22-1 (Scheme 22) [93]. The borylation selectivity most likely arises from the formation of the five-membered metallacycle S22-2 through the C−H bond cleavage at the 7-position rather than of the four-membered metallacycle at the 2-position. Sperry applied an analogous approach for the synthesis of indolequinone natural products where even 5-and 6-methoxy-substituted indoles reacted selectively at the 7-position, thereby broadening the applicability of the developed protocol [94]. Inspired by Hartwig's protocol, Movassaghi et al. developed a more streamlined C7-selective borylation of 3-alkylindoles. Their design was based on the diboronation/protodeboronation sequence. The authors managed to develop reaction conditions wherein the 3-substituted indoles S23-1 underwent iridium-catalyzed C2/C7 diboronation with an excess of HBpin so as to form S23-2 in situ, and subsequently, selective C2 protodeboronation either with a large excess of trifluoroacetic acid or a catalytic amount of Pd(OAc)2 in AcOH (Scheme 23) [95]. Smith and Maleczka later expanded upon this protocol. They developed a complementary method for selective C2 deborylation using the iridium-catalyzed deborylation of 2,7-diborylated indoles to prepare 7-borylated indoles [96]. They also determined that bismuth(III) acetate can be used for the C2 and C7 protodeboronation of indoles. They prepared a series of diborylated and triborylated indoles that underwent selective C2 and C7 deborylation with Bi(OAc)3 in methanol so as to prepare mono-and bisborylated indoles [97]. Inspired by Hartwig's protocol, Movassaghi et al. developed a more streamlined C7-selective borylation of 3-alkylindoles. Their design was based on the diboronation/protodeboronation sequence. The authors managed to develop reaction conditions wherein the 3-substituted indoles S23-1 underwent iridium-catalyzed C2/C7 diboronation with an excess of HBpin so as to form S23-2 in situ, and subsequently, selective C2 protodeboronation either with a large excess of trifluoroacetic acid or a catalytic amount of Pd(OAc) 2 in AcOH (Scheme 23) [95]. Smith and Maleczka later expanded upon this protocol. They developed a complementary method for selective C2 deborylation using the iridium-catalyzed deborylation of 2,7-diborylated indoles to prepare 7-borylated indoles [96]. They also determined that bismuth(III) acetate can be used for the C2 and C7 protodeboronation of indoles. They prepared a series of diborylated and triborylated indoles that underwent selective C2 and C7 deborylation with Bi(OAc) 3 in methanol so as to prepare mono-and bisborylated indoles [97]. Recently, the diboronation/protodeboronation method was used by Burns et al. to achieve the total synthesis of Ts-discorhabdin E from tryptamine [98].

Non-Selective Borylations
Several non-selective methods for the borylation of indoles have emerged over the last decade, which either produce multi-borylated indoles or else are highly substrate-specific and differently substituted indoles undergo borylation at different sites [99]. One such method concerns the esterdirected borylation of sulfur-, oxygen-, or nitrogen-containing five-membered heterocycles developed by Sawamura, whereby indoles S24-1 bear the ester functional group borylate at either the 2-or the 3-position depending on where the ester group resides. If the ester group is present at the nitrogen atom, then the borylation occurs at the 2-position, and it only occurs at the 7-position (S24-2) when the 2-and 3-positions are occupied (Scheme 24) [100].
As mentioned above, the borylations of indoles often proceed at multiple sites, most frequently at the C2 and C7 positions [101]. Protodeboronation at C2 can lead to selective C7 borylation, although that is not the only application of the inherent reactivity regarding indole borylations. Sperry applied a diborylation/oxidation protocol for the short total synthesis of an endogenous plant metabolite 7-hydroxyoxindole-3-acetic acid S25-4, which required only one chromatography separation (Scheme 25) [102]. Utilizing the Me4Phen ligand and an excess of B2pin2 was crucial for achieving the full conversion of the S25-1 into S25-2. Scheme 25. The short total synthesis of 7-hydroxyoxindole-3-acetic acid utilizing a selective diborylation/oxidation sequence.
Sperry also developed a reaction condition for the threefold borylation of 3-substituted indoles S26-1 by employing iridium catalysis with the Me4Phen ligand. During the course of the reaction, the Scheme 23. Selective C7 borylation using the diboronation/protodeboronation sequence developed by Movassaghi.

Non-Selective Borylations
Several non-selective methods for the borylation of indoles have emerged over the last decade, which either produce multi-borylated indoles or else are highly substrate-specific and differently substituted indoles undergo borylation at different sites [99]. One such method concerns the ester-directed borylation of sulfur-, oxygen-, or nitrogen-containing five-membered heterocycles developed by Sawamura, whereby indoles S24-1 bear the ester functional group borylate at either the 2-or the 3-position depending on where the ester group resides. If the ester group is present at the nitrogen atom, then the borylation occurs at the 2-position, and it only occurs at the 7-position (S24-2) when the 2-and 3-positions are occupied (Scheme 24) [100]. Recently, the diboronation/protodeboronation method was used by Burns et al. to achieve the total synthesis of Ts-discorhabdin E from tryptamine [98].

Non-Selective Borylations
Several non-selective methods for the borylation of indoles have emerged over the last decade, which either produce multi-borylated indoles or else are highly substrate-specific and differently substituted indoles undergo borylation at different sites [99]. One such method concerns the esterdirected borylation of sulfur-, oxygen-, or nitrogen-containing five-membered heterocycles developed by Sawamura, whereby indoles S24-1 bear the ester functional group borylate at either the 2-or the 3-position depending on where the ester group resides. If the ester group is present at the nitrogen atom, then the borylation occurs at the 2-position, and it only occurs at the 7-position (S24-2) when the 2-and 3-positions are occupied (Scheme 24) [100].
As mentioned above, the borylations of indoles often proceed at multiple sites, most frequently at the C2 and C7 positions [101]. Protodeboronation at C2 can lead to selective C7 borylation, although that is not the only application of the inherent reactivity regarding indole borylations. Sperry applied a diborylation/oxidation protocol for the short total synthesis of an endogenous plant metabolite 7-hydroxyoxindole-3-acetic acid S25-4, which required only one chromatography separation (Scheme 25) [102]. Utilizing the Me4Phen ligand and an excess of B2pin2 was crucial for achieving the full conversion of the S25-1 into S25-2. Scheme 25. The short total synthesis of 7-hydroxyoxindole-3-acetic acid utilizing a selective diborylation/oxidation sequence.
Sperry also developed a reaction condition for the threefold borylation of 3-substituted indoles S26-1 by employing iridium catalysis with the Me4Phen ligand. During the course of the reaction, the Scheme 24. Ester-directed iridium-catalyzed borylation of indoles.
As mentioned above, the borylations of indoles often proceed at multiple sites, most frequently at the C2 and C7 positions [101]. Protodeboronation at C2 can lead to selective C7 borylation, although that is not the only application of the inherent reactivity regarding indole borylations. Sperry applied a diborylation/oxidation protocol for the short total synthesis of an endogenous plant metabolite 7-hydroxyoxindole-3-acetic acid S25-4, which required only one chromatography separation (Scheme 25) [102]. Utilizing the Me 4 Phen ligand and an excess of B 2 pin 2 was crucial for achieving the full conversion of the S25-1 into S25-2.

Non-Selective Borylations
Several non-selective methods for the borylation of indoles have emerged over the last decade, which either produce multi-borylated indoles or else are highly substrate-specific and differently substituted indoles undergo borylation at different sites [99]. One such method concerns the esterdirected borylation of sulfur-, oxygen-, or nitrogen-containing five-membered heterocycles developed by Sawamura, whereby indoles S24-1 bear the ester functional group borylate at either the 2-or the 3-position depending on where the ester group resides. If the ester group is present at the nitrogen atom, then the borylation occurs at the 2-position, and it only occurs at the 7-position (S24-2) when the 2-and 3-positions are occupied (Scheme 24) [100].
As mentioned above, the borylations of indoles often proceed at multiple sites, most frequently at the C2 and C7 positions [101]. Protodeboronation at C2 can lead to selective C7 borylation, although that is not the only application of the inherent reactivity regarding indole borylations. Sperry applied a diborylation/oxidation protocol for the short total synthesis of an endogenous plant metabolite 7-hydroxyoxindole-3-acetic acid S25-4, which required only one chromatography separation (Scheme 25) [102]. Utilizing the Me4Phen ligand and an excess of B2pin2 was crucial for achieving the full conversion of the S25-1 into S25-2. Scheme 25. The short total synthesis of 7-hydroxyoxindole-3-acetic acid utilizing a selective diborylation/oxidation sequence.
Sperry also developed a reaction condition for the threefold borylation of 3-substituted indoles S26-1 by employing iridium catalysis with the Me4Phen ligand. During the course of the reaction, the Scheme 25. The short total synthesis of 7-hydroxyoxindole-3-acetic acid utilizing a selective diborylation/oxidation sequence. Sperry also developed a reaction condition for the threefold borylation of 3-substituted indoles S26-1 by employing iridium catalysis with the Me 4 Phen ligand. During the course of the reaction, the C−H borylation first proceeded quickly at the C2 and C7 positions, and then further, at the C5 position due to steric effects [103]. Several triborylated 3-substituted indoles S26-2 were prepared by following the described protocol (Scheme 26). C−H borylation first proceeded quickly at the C2 and C7 positions, and then further, at the C5 position due to steric effects [103]. Several triborylated 3-substituted indoles S26-2 were prepared by following the described protocol (Scheme 26).

Cyclization Protocols for the Synthesis of Indolylboronic Acid Derivatives
Thus far, the synthesis of indolylboronic acids or esters has been achieved via the manipulation of the indolyl moiety. The opposite approach, which consists of the cyclization of the substituted anilines, can also be used to synthesize 3-indolylboronic acids or boronates ( Table 3). The cyclization strategy can be performed under transition-metal-free conditions by means of a stoichiometric amount of BCl3 [105] or a catalytic amount of B(C6F5)3 [106] (Table 3, entries 1 and 2). Palladium [107] and gold [108] catalysts can also be used for the same cyclization, affording 3-indolylboronates in comparable isolated yields. The common feature of the above-mentioned protocols is the ability to Sperry then expanded the protocol to achieve the synthesis of 5,7-diborylated-3-methylindole S27-3 from 3-methylindole S27-1 utilizing the triborylation/C2-protodeboronation sequence in a one-pot manner (Scheme 27) [104]. The author showed that the two boryl groups in positions 5 and 7 of the S27-3 can be further functionalized in a selective or non-selective way so as to prepare valuable indoles bearing the aryl group, methoxy group, or halogen atoms in the aforementioned positions. Additionally, this method was applied to achieve the total synthesis of (+)-plakohypaphorine C (S27-5) from Boc-protected L-tryptophan methyl ester (S27-4) (Scheme 27). C−H borylation first proceeded quickly at the C2 and C7 positions, and then further, at the C5 position due to steric effects [103]. Several triborylated 3-substituted indoles S26-2 were prepared by following the described protocol (Scheme 26).

Cyclization Protocols for the Synthesis of Indolylboronic Acid Derivatives
Thus far, the synthesis of indolylboronic acids or esters has been achieved via the manipulation of the indolyl moiety. The opposite approach, which consists of the cyclization of the substituted anilines, can also be used to synthesize 3-indolylboronic acids or boronates ( Table 3). The cyclization strategy can be performed under transition-metal-free conditions by means of a stoichiometric amount of BCl3 [105] or a catalytic amount of B(C6F5)3 [106] (Table 3, entries 1 and 2). Palladium [107] and gold [108] catalysts can also be used for the same cyclization, affording 3-indolylboronates in comparable isolated yields. The common feature of the above-mentioned protocols is the ability to Scheme 27. Triborylation/protodeboronation sequence for the synthesis of 5,7-functionalized indoles and the total synthesis of (+)-plakohypaphorine C.

Cyclization Protocols for the Synthesis of Indolylboronic Acid Derivatives
Thus far, the synthesis of indolylboronic acids or esters has been achieved via the manipulation of the indolyl moiety. The opposite approach, which consists of the cyclization of the substituted anilines, can also be used to synthesize 3-indolylboronic acids or boronates ( Table 3). The cyclization strategy can be performed under transition-metal-free conditions by means of a stoichiometric amount of BCl 3 [105] or a catalytic amount of B(C 6 F 5 ) 3 [106] (Table 3, entries 1 and 2). Palladium [107] and gold [108] catalysts can also be used for the same cyclization, affording 3-indolylboronates in comparable isolated yields. The common feature of the above-mentioned protocols is the ability to provide rapid access to 2-subtituted-3-indolylboronates in good isolated yields and wide substrate scopes. Based on both experimental evidence and theoretical investigation [109], plausible mechanisms have been proposed to explain borylative cyclizations. Generally, simplified versions of the proposed mechanisms rely on the activation of the triple bond by means of Lewis acid complexation, and either transition metals or boron-based reagents can be used as acids (Table 3, entry 5). This complexation facilitates the addition of nitrogen to the triple bond. The synthesis of regioisomeric 2-indolylboronates is also feasible [110], although a procedure starting from 2-iodoanilines and MIDAB-acetylene under typical Miyaura borylation conditions would have to be used. provide rapid access to 2-subtituted-3-indolylboronates in good isolated yields and wide substrate scopes. Based on both experimental evidence and theoretical investigation [109], plausible mechanisms have been proposed to explain borylative cyclizations. Generally, simplified versions of the proposed mechanisms rely on the activation of the triple bond by means of Lewis acid complexation, and either transition metals or boron-based reagents can be used as acids (Table 3, entry 5). This complexation facilitates the addition of nitrogen to the triple bond. The synthesis of regioisomeric 2-indolylboronates is also feasible [110], although a procedure starting from 2iodoanilines and MIDAB-acetylene under typical Miyaura borylation conditions would have to be used. Save for the ortho-substituted aniline, the ortho-substituted phenylisocyanides undergo smooth cyclization so as to give substituted 2-indolylboronic acid pinacol esters S28-2 (Scheme 28) [111]. This methodology leads to excellent yields of the substituted indoles S28-2, although the presence of alkenyl species bearing an ester group is required. This requirement can be explained by a plausible mechanism. It is expected that the copper catalyst activates the pinB-Bpin, followed by a reaction with the isocyanide S28-1. The formed complex S28-3 then undergoes intramolecular addition so as to give copper enolate S28-4 while the ligand substitution releases the 2-indolylboronates S28-2. provide rapid access to 2-subtituted-3-indolylboronates in good isolated yields and wide substrate scopes. Based on both experimental evidence and theoretical investigation [109], plausible mechanisms have been proposed to explain borylative cyclizations. Generally, simplified versions of the proposed mechanisms rely on the activation of the triple bond by means of Lewis acid complexation, and either transition metals or boron-based reagents can be used as acids (Table 3, entry 5). This complexation facilitates the addition of nitrogen to the triple bond. The synthesis of regioisomeric 2-indolylboronates is also feasible [110], although a procedure starting from 2iodoanilines and MIDAB-acetylene under typical Miyaura borylation conditions would have to be used. Save for the ortho-substituted aniline, the ortho-substituted phenylisocyanides undergo smooth cyclization so as to give substituted 2-indolylboronic acid pinacol esters S28-2 (Scheme 28) [111]. This methodology leads to excellent yields of the substituted indoles S28-2, although the presence of alkenyl species bearing an ester group is required. This requirement can be explained by a plausible mechanism. It is expected that the copper catalyst activates the pinB-Bpin, followed by a reaction with the isocyanide S28-1. The formed complex S28-3 then undergoes intramolecular addition so as to give copper enolate S28-4 while the ligand substitution releases the 2-indolylboronates S28-2.
Save for the ortho-substituted aniline, the ortho-substituted phenylisocyanides undergo smooth cyclization so as to give substituted 2-indolylboronic acid pinacol esters S28-2 (Scheme 28) [111]. This methodology leads to excellent yields of the substituted indoles S28-2, although the presence of alkenyl species bearing an ester group is required. This requirement can be explained by a plausible mechanism. It is expected that the copper catalyst activates the pinB-Bpin, followed by a reaction with the isocyanide S28-1. The formed complex S28-3 then undergoes intramolecular addition so as to give copper enolate S28-4 while the ligand substitution releases the 2-indolylboronates S28-2.

Lewis-acid-catalyzed Borylation of Indoles
It is clear that the transition-metal-catalyzed borylations of indoles have become the methods of choice when designing the functionalization of indoles via indolylboronic acid intermediates. Yet, transition-metal-free borylations offer a relatively simple and cheap route to indolylboronates under mild reaction conditions. In 2013 [112] and 2014 [113], Wang et al. described a procedure that allowed for the conversion of arylamines into indolylboronic acid pinacol esters by means of the reaction with pinB-Bpin in the presence of t BuONO (Scheme 29). The developed methodology was found to be applicable in relation to diverse aromatic and heteroaromatic substrates substituted with both electron-donating and electron-withdrawing groups. Overall, the isolated yields were within the range of 14−80%, and a single example of indolylboronate S9-2 was isolated in a 22% yield. The authors proposed a single-electron transfer (SET) mechanism for their reaction [112]. A different approach comparable to the transition-metal-catalyzed borylation of indoles was reported by Zhang (Scheme 30) [114]. He observed that a catalytic amount of boron trifluoride diethyl etherate was able to catalyze the conversion of substituted indoles into indolylboronic acid pinacol esters. A wide range of indolylboronates were prepared by heating the starting compounds in n octane/THF to 140 °C. The author was able to synthesize indoles with sensitive bromine function S30-2b, unprotected indole S30-2c, as well as 2,3-disubstituted indole S30-2a. It is expected that the reaction proceeds through an initial attack of BF3 on the indole-affording intermediate S30-3. The Scheme 28. Borylative cyclization of ortho-substituted phenylisocyanides S28-1 catalyzed by copper(I) acetate.

Lewis-acid-catalyzed Borylation of Indoles
It is clear that the transition-metal-catalyzed borylations of indoles have become the methods of choice when designing the functionalization of indoles via indolylboronic acid intermediates. Yet, transition-metal-free borylations offer a relatively simple and cheap route to indolylboronates under mild reaction conditions. In 2013 [112] and 2014 [113], Wang et al. described a procedure that allowed for the conversion of arylamines into indolylboronic acid pinacol esters by means of the reaction with pinB-Bpin in the presence of t BuONO (Scheme 29). The developed methodology was found to be applicable in relation to diverse aromatic and heteroaromatic substrates substituted with both electron-donating and electron-withdrawing groups. Overall, the isolated yields were within the range of 14−80%, and a single example of indolylboronate S9-2 was isolated in a 22% yield. The authors proposed a single-electron transfer (SET) mechanism for their reaction [112].

Lewis-acid-catalyzed Borylation of Indoles
It is clear that the transition-metal-catalyzed borylations of indoles have become the methods of choice when designing the functionalization of indoles via indolylboronic acid intermediates. Yet, transition-metal-free borylations offer a relatively simple and cheap route to indolylboronates under mild reaction conditions. In 2013 [112] and 2014 [113], Wang et al. described a procedure that allowed for the conversion of arylamines into indolylboronic acid pinacol esters by means of the reaction with pinB-Bpin in the presence of t BuONO (Scheme 29). The developed methodology was found to be applicable in relation to diverse aromatic and heteroaromatic substrates substituted with both electron-donating and electron-withdrawing groups. Overall, the isolated yields were within the range of 14−80%, and a single example of indolylboronate S9-2 was isolated in a 22% yield. The authors proposed a single-electron transfer (SET) mechanism for their reaction [112]. A different approach comparable to the transition-metal-catalyzed borylation of indoles was reported by Zhang (Scheme 30) [114]. He observed that a catalytic amount of boron trifluoride diethyl etherate was able to catalyze the conversion of substituted indoles into indolylboronic acid pinacol esters. A wide range of indolylboronates were prepared by heating the starting compounds in n octane/THF to 140 °C. The author was able to synthesize indoles with sensitive bromine function S30-2b, unprotected indole S30-2c, as well as 2,3-disubstituted indole S30-2a. It is expected that the reaction proceeds through an initial attack of BF3 on the indole-affording intermediate S30-3. The A different approach comparable to the transition-metal-catalyzed borylation of indoles was reported by Zhang (Scheme 30) [114]. He observed that a catalytic amount of boron trifluoride diethyl etherate was able to catalyze the conversion of substituted indoles into indolylboronic acid pinacol esters. A wide range of indolylboronates were prepared by heating the starting compounds in n octane/THF to 140 • C. The author was able to synthesize indoles with sensitive bromine function S30-2b, unprotected indole S30-2c, as well as 2,3-disubstituted indole S30-2a. It is expected that the reaction proceeds through an initial attack of BF 3  The example presented in Scheme 30 illustrates an application of formal electrophilic aromatic substitution as a tool for the borylation of electron-rich arenes. This concept was further exploited by Zhang [115], Oestreich [116], and Erker [117] (Table 4). Zhang made use of catecholborane (catBH) along with pentafluoroborane as the Lewis acid in the catalytic setup. The reaction proceeds at room temperature as disproportionation affording a mixture of the indolylboronic acid catechol ester and the corresponding 2,3-dihydroindoles in good isolated yields (Table 4, entry 1). This approach allows for easy access to a variety of borylated The example presented in Scheme 30 illustrates an application of formal electrophilic aromatic substitution as a tool for the borylation of electron-rich arenes. This concept was further exploited by Zhang [115], Oestreich [116], and Erker [117] (Table 4). The example presented in Scheme 30 illustrates an application of formal electrophilic aromatic substitution as a tool for the borylation of electron-rich arenes. This concept was further exploited by Zhang [115], Oestreich [116], and Erker [117] (Table 4). Zhang made use of catecholborane (catBH) along with pentafluoroborane as the Lewis acid in the catalytic setup. The reaction proceeds at room temperature as disproportionation affording a mixture of the indolylboronic acid catechol ester and the corresponding 2,3-dihydroindoles in good isolated yields (Table 4, entry 1). This approach allows for easy access to a variety of borylated The example presented in Scheme 30 illustrates an application of formal electrophilic aromatic substitution as a tool for the borylation of electron-rich arenes. This concept was further exploited by Zhang [115], Oestreich [116], and Erker [117] (Table 4). Zhang made use of catecholborane (catBH) along with pentafluoroborane as the Lewis acid in the catalytic setup. The reaction proceeds at room temperature as disproportionation affording a mixture of the indolylboronic acid catechol ester and the corresponding 2,3-dihydroindoles in good isolated yields (Table 4, entry 1). This approach allows for easy access to a variety of borylated The example presented in Scheme 30 illustrates an application of formal electrophilic aromatic substitution as a tool for the borylation of electron-rich arenes. This concept was further exploited by Zhang [115], Oestreich [116], and Erker [117] (Table 4). Zhang made use of catecholborane (catBH) along with pentafluoroborane as the Lewis acid in the catalytic setup. The reaction proceeds at room temperature as disproportionation affording a mixture of the indolylboronic acid catechol ester and the corresponding 2,3-dihydroindoles in good isolated yields (Table 4, entry 1). This approach allows for easy access to a variety of borylated The example presented in Scheme 30 illustrates an application of formal electrophilic aromatic substitution as a tool for the borylation of electron-rich arenes. This concept was further exploited by Zhang [115], Oestreich [116], and Erker [117] (Table 4). Zhang made use of catecholborane (catBH) along with pentafluoroborane as the Lewis acid in the catalytic setup. The reaction proceeds at room temperature as disproportionation affording a mixture of the indolylboronic acid catechol ester and the corresponding 2,3-dihydroindoles in good isolated yields (Table 4, entry 1). This approach allows for easy access to a variety of borylated The example presented in Scheme 30 illustrates an application of formal electrophilic aromatic substitution as a tool for the borylation of electron-rich arenes. This concept was further exploited by Zhang [115], Oestreich [116], and Erker [117] (Table 4). Zhang made use of catecholborane (catBH) along with pentafluoroborane as the Lewis acid in the catalytic setup. The reaction proceeds at room temperature as disproportionation affording a mixture of the indolylboronic acid catechol ester and the corresponding 2,3-dihydroindoles in good isolated yields (Table 4, entry 1). This approach allows for easy access to a variety of borylated Zhang made use of catecholborane (catBH) along with pentafluoroborane as the Lewis acid in the catalytic setup. The reaction proceeds at room temperature as disproportionation affording a mixture of the indolylboronic acid catechol ester and the corresponding 2,3-dihydroindoles in good isolated yields (Table 4, entry 1). This approach allows for easy access to a variety of borylated indoles.
However, the convergent disproportionation reaction is able to increase the yield of borylated indoles up to a 98% yield. In this case, the borylation is performed at 120 • C. Under the above-mentioned conditions, the catalyst enables the conversion of indolines into indoles, thereby allowing for a shift in the equilibrium of disproportionation reactions. A similar approach was reported by Oestreich et al. (Table 4, entry 2) [116]. The same reaction conditions were applied, although the scope of the protocol was extended to electron-rich arenes. Interestingly, the reaction was accelerated when performed in the presence of norbornene or norbornadiene. Substantial progress was achieved by running the borylation reaction in the presence of bisborane T4-3, which allowed the borylation to proceed at room temperature with a good isolated yield of the corresponding boronates (Table 4, entry 3) [117].
In a series of papers, Fontaine showed that the frustrated Lewis pair S31-4 can catalyze transition-metal-free C−H borylation (Scheme 31) [118][119][120][121]. The developed conditions are mostly applicable to five-membered heterocycles, thiophene, pyrrole, or furan. However, the substituted indoles S31-2 and S31-3 were prepared in excellent isolated yields. indoles. However, the convergent disproportionation reaction is able to increase the yield of borylated indoles up to a 98% yield. In this case, the borylation is performed at 120 °C. Under the above-mentioned conditions, the catalyst enables the conversion of indolines into indoles, thereby allowing for a shift in the equilibrium of disproportionation reactions. A similar approach was reported by Oestreich et al. (Table 4, entry 2) [116]. The same reaction conditions were applied, although the scope of the protocol was extended to electron-rich arenes. Interestingly, the reaction was accelerated when performed in the presence of norbornene or norbornadiene. Substantial progress was achieved by running the borylation reaction in the presence of bisborane T4-3, which allowed the borylation to proceed at room temperature with a good isolated yield of the corresponding boronates (Table 4, entry 3) [117].
In a series of papers, Fontaine showed that the frustrated Lewis pair S31-4 can catalyze transition-metal-free C−H borylation (Scheme 31) [118][119][120][121]. The developed conditions are mostly applicable to five-membered heterocycles, thiophene, pyrrole, or furan. However, the substituted indoles S31-2 and S31-3 were prepared in excellent isolated yields. A different type of electrophilic borylation was reported by Ingleson [122][123][124][125]. This reaction is applicable for the borylation of a wide range of heteroarenes and arenes, including pyrene and anthracene. The reaction can be performed by means of BCl3 [122] or the less reactive ClBcat [123,124] derivative. It was proposed that during the first step, the borylation reagent S32-3 is activated by the presence of triethylamine and aluminum chloride, thereby affording the borenium cation S32-5 as the main reactive species (Scheme 32). Then, the formed borenium cation reacts with the arenes, and following esterification (e.g., with pinacol), provides the products of borylation. Thus, both pinacol esters [122−124] and MIDA-boronates [122] are available via this protocol. Recently, another different type of borylation reagent has been reported [126]. The protocol involves the treatment of electron-rich alkenes with four equivalents of boron tribromide in the presence of 2,6-lutidine at room temperature. The reaction is limited to electron-rich alkenes, and only one example of indole borylation is provided (Scheme 33). A different type of electrophilic borylation was reported by Ingleson [122][123][124][125]. This reaction is applicable for the borylation of a wide range of heteroarenes and arenes, including pyrene and anthracene. The reaction can be performed by means of BCl 3 [122] or the less reactive ClBcat [123,124] derivative. It was proposed that during the first step, the borylation reagent S32-3 is activated by the presence of triethylamine and aluminum chloride, thereby affording the borenium cation S32-5 as the main reactive species (Scheme 32). Then, the formed borenium cation reacts with the arenes, and following esterification (e.g., with pinacol), provides the products of borylation. Thus, both pinacol esters [122−124] and MIDA-boronates [122] are available via this protocol. indoles. However, the convergent disproportionation reaction is able to increase the yield of borylated indoles up to a 98% yield. In this case, the borylation is performed at 120 °C. Under the above-mentioned conditions, the catalyst enables the conversion of indolines into indoles, thereby allowing for a shift in the equilibrium of disproportionation reactions. A similar approach was reported by Oestreich et al. (Table 4, entry 2) [116]. The same reaction conditions were applied, although the scope of the protocol was extended to electron-rich arenes. Interestingly, the reaction was accelerated when performed in the presence of norbornene or norbornadiene. Substantial progress was achieved by running the borylation reaction in the presence of bisborane T4-3, which allowed the borylation to proceed at room temperature with a good isolated yield of the corresponding boronates (Table 4, entry 3) [117].
In a series of papers, Fontaine showed that the frustrated Lewis pair S31-4 can catalyze transition-metal-free C−H borylation (Scheme 31) [118][119][120][121]. The developed conditions are mostly applicable to five-membered heterocycles, thiophene, pyrrole, or furan. However, the substituted indoles S31-2 and S31-3 were prepared in excellent isolated yields. A different type of electrophilic borylation was reported by Ingleson [122][123][124][125]. This reaction is applicable for the borylation of a wide range of heteroarenes and arenes, including pyrene and anthracene. The reaction can be performed by means of BCl3 [122] or the less reactive ClBcat [123,124] derivative. It was proposed that during the first step, the borylation reagent S32-3 is activated by the presence of triethylamine and aluminum chloride, thereby affording the borenium cation S32-5 as the main reactive species (Scheme 32). Then, the formed borenium cation reacts with the arenes, and following esterification (e.g., with pinacol), provides the products of borylation. Thus, both pinacol esters [122−124] and MIDA-boronates [122] are available via this protocol. Recently, another different type of borylation reagent has been reported [126]. The protocol involves the treatment of electron-rich alkenes with four equivalents of boron tribromide in the presence of 2,6-lutidine at room temperature. The reaction is limited to electron-rich alkenes, and only one example of indole borylation is provided (Scheme 33). Recently, another different type of borylation reagent has been reported [126]. The protocol involves the treatment of electron-rich alkenes with four equivalents of boron tribromide in the presence of 2,6-lutidine at room temperature. The reaction is limited to electron-rich alkenes, and only one example of indole borylation is provided (Scheme 33). The final option for the preparation of indolylboronic acids or boronates is based on the chemical manipulation of indoles bearing the −B(OH)2 or −B(OR)2 function. In this regard, regioselective Friedel−Crafts alkylation [127], boronate ligand interconversion [128], palladium or rhodium C−H activation [129,130], metal-free arylation [131,132], and other approaches [133] have emerged in the literature. Although these procedures allow for access to a novel type of indolylboronic acid or ester, they are not discussed in detail in the present paper because indolylboronic acid esters are already used as starting compounds.

Formal Substitution of Boron Moieties by Transition-Metal-Catalyzed or Transition-Metal-Free Reactions
Indolylboronic acids and their derivatives are all examples of simple and stable heteroaromatic compounds, which have found many applications in the field of organic synthesis, along with other aromatic and heteroaromatic boronates and boronic acids. Presumably, the simplest modification is represented by the protodeboronation that was reported by Macgregor and Lee (Table 5, entry 1) [134]. They found that 5 mol % of a gold catalyst facilitates the protodeboronation of boronic acids in the presence of dimethyl carbonate and water when using a microwave setup. As the reaction is carried out under non-acidic conditions, acid-sensitive functional groups (e.g., the THP group) are tolerated. The use of THF along with D2O allows for a simple deuterodeboronation. Based on density functional theory calculations, a mechanism explaining the observed reactivity has been proposed. A copper catalyst was used for the direct conversion of boronates, boronic acids, and organotrifluoroborates into the azides (Table 5, entry 2) [135]. The final option for the preparation of indolylboronic acids or boronates is based on the chemical manipulation of indoles bearing the −B(OH) 2 or −B(OR) 2 function. In this regard, regioselective Friedel−Crafts alkylation [127], boronate ligand interconversion [128], palladium or rhodium C−H activation [129,130], metal-free arylation [131,132], and other approaches [133] have emerged in the literature. Although these procedures allow for access to a novel type of indolylboronic acid or ester, they are not discussed in detail in the present paper because indolylboronic acid esters are already used as starting compounds.

Formal Substitution of Boron Moieties by Transition-Metal-Catalyzed or Transition-Metal-Free Reactions
Indolylboronic acids and their derivatives are all examples of simple and stable heteroaromatic compounds, which have found many applications in the field of organic synthesis, along with other aromatic and heteroaromatic boronates and boronic acids. Presumably, the simplest modification is represented by the protodeboronation that was reported by Macgregor and Lee (Table 5, entry 1) [134]. They found that 5 mol % of a gold catalyst facilitates the protodeboronation of boronic acids in the presence of dimethyl carbonate and water when using a microwave setup. As the reaction is carried out under non-acidic conditions, acid-sensitive functional groups (e.g., the THP group) are tolerated. The use of THF along with D 2 O allows for a simple deuterodeboronation. Based on density functional theory calculations, a mechanism explaining the observed reactivity has been proposed. A copper catalyst was used for the direct conversion of boronates, boronic acids, and organotrifluoroborates into the azides (Table 5, entry 2) [135]. The final option for the preparation of indolylboronic acids or boronates is based on the chemical manipulation of indoles bearing the −B(OH)2 or −B(OR)2 function. In this regard, regioselective Friedel−Crafts alkylation [127], boronate ligand interconversion [128], palladium or rhodium C−H activation [129,130], metal-free arylation [131,132], and other approaches [133] have emerged in the literature. Although these procedures allow for access to a novel type of indolylboronic acid or ester, they are not discussed in detail in the present paper because indolylboronic acid esters are already used as starting compounds.

Formal Substitution of Boron Moieties by Transition-Metal-Catalyzed or Transition-Metal-Free Reactions
Indolylboronic acids and their derivatives are all examples of simple and stable heteroaromatic compounds, which have found many applications in the field of organic synthesis, along with other aromatic and heteroaromatic boronates and boronic acids. Presumably, the simplest modification is represented by the protodeboronation that was reported by Macgregor and Lee (Table 5, entry 1) [134]. They found that 5 mol % of a gold catalyst facilitates the protodeboronation of boronic acids in the presence of dimethyl carbonate and water when using a microwave setup. As the reaction is carried out under non-acidic conditions, acid-sensitive functional groups (e.g., the THP group) are tolerated. The use of THF along with D2O allows for a simple deuterodeboronation. Based on density functional theory calculations, a mechanism explaining the observed reactivity has been proposed. A copper catalyst was used for the direct conversion of boronates, boronic acids, and organotrifluoroborates into the azides (Table 5, entry 2) [135]. The final option for the preparation of indolylboronic acids or boronates is based on the chemical manipulation of indoles bearing the −B(OH)2 or −B(OR)2 function. In this regard, regioselective Friedel−Crafts alkylation [127], boronate ligand interconversion [128], palladium or rhodium C−H activation [129,130], metal-free arylation [131,132], and other approaches [133] have emerged in the literature. Although these procedures allow for access to a novel type of indolylboronic acid or ester, they are not discussed in detail in the present paper because indolylboronic acid esters are already used as starting compounds.

Formal Substitution of Boron Moieties by Transition-Metal-Catalyzed or Transition-Metal-Free Reactions
Indolylboronic acids and their derivatives are all examples of simple and stable heteroaromatic compounds, which have found many applications in the field of organic synthesis, along with other aromatic and heteroaromatic boronates and boronic acids. Presumably, the simplest modification is represented by the protodeboronation that was reported by Macgregor and Lee (Table 5, entry 1) [134]. They found that 5 mol % of a gold catalyst facilitates the protodeboronation of boronic acids in the presence of dimethyl carbonate and water when using a microwave setup. As the reaction is carried out under non-acidic conditions, acid-sensitive functional groups (e.g., the THP group) are tolerated. The use of THF along with D2O allows for a simple deuterodeboronation. Based on density functional theory calculations, a mechanism explaining the observed reactivity has been proposed. A copper catalyst was used for the direct conversion of boronates, boronic acids, and organotrifluoroborates into the azides (Table 5, entry 2) [135]. The final option for the preparation of indolylboronic acids or boronates is based on the chemical manipulation of indoles bearing the −B(OH)2 or −B(OR)2 function. In this regard, regioselective Friedel−Crafts alkylation [127], boronate ligand interconversion [128], palladium or rhodium C−H activation [129,130], metal-free arylation [131,132], and other approaches [133] have emerged in the literature. Although these procedures allow for access to a novel type of indolylboronic acid or ester, they are not discussed in detail in the present paper because indolylboronic acid esters are already used as starting compounds.

Formal Substitution of Boron Moieties by Transition-Metal-Catalyzed or Transition-Metal-Free Reactions
Indolylboronic acids and their derivatives are all examples of simple and stable heteroaromatic compounds, which have found many applications in the field of organic synthesis, along with other aromatic and heteroaromatic boronates and boronic acids. Presumably, the simplest modification is represented by the protodeboronation that was reported by Macgregor and Lee (Table 5, entry 1) [134]. They found that 5 mol % of a gold catalyst facilitates the protodeboronation of boronic acids in the presence of dimethyl carbonate and water when using a microwave setup. As the reaction is carried out under non-acidic conditions, acid-sensitive functional groups (e.g., the THP group) are tolerated. The use of THF along with D2O allows for a simple deuterodeboronation. Based on density functional theory calculations, a mechanism explaining the observed reactivity has been proposed. A copper catalyst was used for the direct conversion of boronates, boronic acids, and organotrifluoroborates into the azides (Table 5, entry 2) [135].  The final option for the preparation of indolylboronic acids or boronates is based on the chemical manipulation of indoles bearing the −B(OH)2 or −B(OR)2 function. In this regard, regioselective Friedel−Crafts alkylation [127], boronate ligand interconversion [128], palladium or rhodium C−H activation [129,130], metal-free arylation [131,132], and other approaches [133] have emerged in the literature. Although these procedures allow for access to a novel type of indolylboronic acid or ester, they are not discussed in detail in the present paper because indolylboronic acid esters are already used as starting compounds.

Formal Substitution of Boron Moieties by Transition-Metal-Catalyzed or Transition-Metal-Free Reactions
Indolylboronic acids and their derivatives are all examples of simple and stable heteroaromatic compounds, which have found many applications in the field of organic synthesis, along with other aromatic and heteroaromatic boronates and boronic acids. Presumably, the simplest modification is represented by the protodeboronation that was reported by Macgregor and Lee (Table 5, entry 1) [134]. They found that 5 mol % of a gold catalyst facilitates the protodeboronation of boronic acids in the presence of dimethyl carbonate and water when using a microwave setup. As the reaction is carried out under non-acidic conditions, acid-sensitive functional groups (e.g., the THP group) are tolerated. The use of THF along with D2O allows for a simple deuterodeboronation. Based on density functional theory calculations, a mechanism explaining the observed reactivity has been proposed. A copper catalyst was used for the direct conversion of boronates, boronic acids, and organotrifluoroborates into the azides (Table 5, entry 2) [135]. The developed conditions saw the azidation performed in excellent isolated yields, while the coupling efficiency did not correlate with the electron-donating ability of the substituents. However, the isolated yield of azidoindole was only 51%. The reaction course could be followed colorimetrically as the dark brown solution turned light green upon completion. Recently, the rapid palladium-catalyzed [ 11 C] C-cyanation of aryl-or heteroarylboronates was reported [136]. The reaction conditions allowed for the rapid conversion of the starting boronates by means of treatment with a [ 11 C] NH 4 CN/NH 3 system in the presence of a PdCl 2 (PPh 3 ) 2 catalyst. The high efficiency of the developed protocol was demonstrated via the cyanation of indolylboronate in a 90% radiochemical yield (rcy) and the synthesis of [ 11 C] C-labeled cetrozole.
The ipso-substitution of B-moiety via a halogen atom represents an alternative approach for the synthesis of halogenated arenes. This transformation can be performed under transition-metal-free conditions by means of iodine and KF in dioxane at 80 • C ( Table 6, entry 1) [137]. The isolated yield of iodoindole is high. However, this reaction is less important from a practical point of view, as indoles can be regioselectively lithiated at the 3-position by means of t BuLi [138]. The developed conditions saw the azidation performed in excellent isolated yields, while the coupling efficiency did not correlate with the electron-donating ability of the substituents. However, the isolated yield of azidoindole was only 51%. The reaction course could be followed colorimetrically as the dark brown solution turned light green upon completion. Recently, the rapid palladiumcatalyzed [ 11 C] C-cyanation of aryl-or heteroarylboronates was reported [136]. The reaction conditions allowed for the rapid conversion of the starting boronates by means of treatment with a [ 11 C] NH4CN/NH3 system in the presence of a PdCl2(PPh3)2 catalyst. The high efficiency of the developed protocol was demonstrated via the cyanation of indolylboronate in a 90% radiochemical yield (rcy) and the synthesis of [ 11 C] C-labeled cetrozole.
The ipso-substitution of B-moiety via a halogen atom represents an alternative approach for the synthesis of halogenated arenes. This transformation can be performed under transition-metal-free conditions by means of iodine and KF in dioxane at 80 °C (Table 6, entry 1) [137]. The isolated yield of iodoindole is high. However, this reaction is less important from a practical point of view, as indoles can be regioselectively lithiated at the 3-position by means of t BuLi [138]. The fluorination of indoles is more import, as fluorinated indoles are of interest due to their potential use in the field of medicine. Thus, Hartwig developed the copper(I)-catalyzed fluorination of pinacol boronic ester via an electrophilic fluorine source in THF at 50 °C (Table 6, entry 2) [139]. Overall, the isolated yields of the fluorinated arenes ranged from 29% to 77%, with a 44% isolated yield of 5-fluoroindole being achieved. Radiofluorination is a more attractive concept in relation to the fluorination of indoles. Two different procedures have thus far been reported ( Table 6, entries 3 and 4). Both published procedures rely on Cu-mediated radiofluorination with different fluoride sources. Krasikova [140] achieved a radiochemical conversion (rcc) of 84% within 20 min in DMA at 110 °C under phase-transfer catalysis conditions. The same catalytic system was used by Neumaier, although in that case [ 18 F]Fwas eluted with Et4NHCO3 in n butanol [141]. As demonstrated by the reported examples, the achieved rcc rates were found to be almost quantitative ( The developed conditions saw the azidation performed in excellent isolated yields, while the coupling efficiency did not correlate with the electron-donating ability of the substituents. However, the isolated yield of azidoindole was only 51%. The reaction course could be followed colorimetrically as the dark brown solution turned light green upon completion. Recently, the rapid palladiumcatalyzed [ 11 C] C-cyanation of aryl-or heteroarylboronates was reported [136]. The reaction conditions allowed for the rapid conversion of the starting boronates by means of treatment with a [ 11 C] NH4CN/NH3 system in the presence of a PdCl2(PPh3)2 catalyst. The high efficiency of the developed protocol was demonstrated via the cyanation of indolylboronate in a 90% radiochemical yield (rcy) and the synthesis of [ 11 C] C-labeled cetrozole.
The ipso-substitution of B-moiety via a halogen atom represents an alternative approach for the synthesis of halogenated arenes. This transformation can be performed under transition-metal-free conditions by means of iodine and KF in dioxane at 80 °C (Table 6, entry 1) [137]. The isolated yield of iodoindole is high. However, this reaction is less important from a practical point of view, as indoles can be regioselectively lithiated at the 3-position by means of t BuLi [138]. The fluorination of indoles is more import, as fluorinated indoles are of interest due to their potential use in the field of medicine. Thus, Hartwig developed the copper(I)-catalyzed fluorination of pinacol boronic ester via an electrophilic fluorine source in THF at 50 °C (Table 6, entry 2) [139]. Overall, the isolated yields of the fluorinated arenes ranged from 29% to 77%, with a 44% isolated yield of 5-fluoroindole being achieved. Radiofluorination is a more attractive concept in relation to the fluorination of indoles. Two different procedures have thus far been reported ( Table 6, entries 3 and 4). Both published procedures rely on Cu-mediated radiofluorination with different fluoride sources. Krasikova [140] achieved a radiochemical conversion (rcc) of 84% within 20 min in DMA at 110 °C under phase-transfer catalysis conditions. The same catalytic system was used by Neumaier, although in that case [ 18 F]Fwas eluted with Et4NHCO3 in n butanol [141]. As demonstrated by the reported examples, the achieved rcc rates were found to be almost quantitative ( Table 6, entry 4). The The developed conditions saw the azidation performed in excellent isolated yields, while the coupling efficiency did not correlate with the electron-donating ability of the substituents. However, the isolated yield of azidoindole was only 51%. The reaction course could be followed colorimetrically as the dark brown solution turned light green upon completion. Recently, the rapid palladiumcatalyzed [ 11 C] C-cyanation of aryl-or heteroarylboronates was reported [136]. The reaction conditions allowed for the rapid conversion of the starting boronates by means of treatment with a [ 11 C] NH4CN/NH3 system in the presence of a PdCl2(PPh3)2 catalyst. The high efficiency of the developed protocol was demonstrated via the cyanation of indolylboronate in a 90% radiochemical yield (rcy) and the synthesis of [ 11 C] C-labeled cetrozole.
The ipso-substitution of B-moiety via a halogen atom represents an alternative approach for the synthesis of halogenated arenes. This transformation can be performed under transition-metal-free conditions by means of iodine and KF in dioxane at 80 °C (Table 6, entry 1) [137]. The isolated yield of iodoindole is high. However, this reaction is less important from a practical point of view, as indoles can be regioselectively lithiated at the 3-position by means of t BuLi [138]. The fluorination of indoles is more import, as fluorinated indoles are of interest due to their potential use in the field of medicine. Thus, Hartwig developed the copper(I)-catalyzed fluorination of pinacol boronic ester via an electrophilic fluorine source in THF at 50 °C (Table 6, entry 2) [139]. Overall, the isolated yields of the fluorinated arenes ranged from 29% to 77%, with a 44% isolated yield of 5-fluoroindole being achieved. Radiofluorination is a more attractive concept in relation to the fluorination of indoles. Two different procedures have thus far been reported ( Table 6, entries 3 and 4). Both published procedures rely on Cu-mediated radiofluorination with different fluoride sources. Krasikova [140] achieved a radiochemical conversion (rcc) of 84% within 20 min in DMA at 110 °C under phase-transfer catalysis conditions. The same catalytic system was used by Neumaier, although in that case [ 18 F]Fwas eluted with Et4NHCO3 in n butanol [141]. As demonstrated by the reported examples, the achieved rcc rates were found to be almost quantitative ( Table 6, entry 4). The The developed conditions saw the azidation performed in excellent isolated yields, while the coupling efficiency did not correlate with the electron-donating ability of the substituents. However, the isolated yield of azidoindole was only 51%. The reaction course could be followed colorimetrically as the dark brown solution turned light green upon completion. Recently, the rapid palladiumcatalyzed [ 11 C] C-cyanation of aryl-or heteroarylboronates was reported [136]. The reaction conditions allowed for the rapid conversion of the starting boronates by means of treatment with a [ 11 C] NH4CN/NH3 system in the presence of a PdCl2(PPh3)2 catalyst. The high efficiency of the developed protocol was demonstrated via the cyanation of indolylboronate in a 90% radiochemical yield (rcy) and the synthesis of [ 11 C] C-labeled cetrozole.
The ipso-substitution of B-moiety via a halogen atom represents an alternative approach for the synthesis of halogenated arenes. This transformation can be performed under transition-metal-free conditions by means of iodine and KF in dioxane at 80 °C (Table 6, entry 1) [137]. The isolated yield of iodoindole is high. However, this reaction is less important from a practical point of view, as indoles can be regioselectively lithiated at the 3-position by means of t BuLi [138]. The fluorination of indoles is more import, as fluorinated indoles are of interest due to their potential use in the field of medicine. Thus, Hartwig developed the copper(I)-catalyzed fluorination of pinacol boronic ester via an electrophilic fluorine source in THF at 50 °C (Table 6, entry 2) [139]. Overall, the isolated yields of the fluorinated arenes ranged from 29% to 77%, with a 44% isolated yield of 5-fluoroindole being achieved. Radiofluorination is a more attractive concept in relation to the fluorination of indoles. Two different procedures have thus far been reported ( Table 6, entries 3 and 4). Both published procedures rely on Cu-mediated radiofluorination with different fluoride sources. Krasikova [140] achieved a radiochemical conversion (rcc) of 84% within 20 min in DMA at 110 °C under phase-transfer catalysis conditions. The same catalytic system was used by Neumaier, although in that case [ 18 F]Fwas eluted with Et4NHCO3 in n butanol [141]. As demonstrated by the The developed conditions saw the azidation performed in excellent isolated yields, while the coupling efficiency did not correlate with the electron-donating ability of the substituents. However, the isolated yield of azidoindole was only 51%. The reaction course could be followed colorimetrically as the dark brown solution turned light green upon completion. Recently, the rapid palladiumcatalyzed [ 11 C] C-cyanation of aryl-or heteroarylboronates was reported [136]. The reaction conditions allowed for the rapid conversion of the starting boronates by means of treatment with a [ 11 C] NH4CN/NH3 system in the presence of a PdCl2(PPh3)2 catalyst. The high efficiency of the developed protocol was demonstrated via the cyanation of indolylboronate in a 90% radiochemical yield (rcy) and the synthesis of [ 11 C] C-labeled cetrozole.
The ipso-substitution of B-moiety via a halogen atom represents an alternative approach for the synthesis of halogenated arenes. This transformation can be performed under transition-metal-free conditions by means of iodine and KF in dioxane at 80 °C (Table 6, entry 1) [137]. The isolated yield of iodoindole is high. However, this reaction is less important from a practical point of view, as indoles can be regioselectively lithiated at the 3-position by means of t BuLi [138]. The fluorination of indoles is more import, as fluorinated indoles are of interest due to their potential use in the field of medicine. Thus, Hartwig developed the copper(I)-catalyzed fluorination of pinacol boronic ester via an electrophilic fluorine source in THF at 50 °C (Table 6, entry 2) [139]. Overall, the isolated yields of the fluorinated arenes ranged from 29% to 77%, with a 44% isolated yield of 5-fluoroindole being achieved. Radiofluorination is a more attractive concept in relation to the fluorination of indoles. Two different procedures have thus far been reported ( Table 6, entries 3 and 4). Both published procedures rely on Cu-mediated radiofluorination with different fluoride sources. Krasikova [140] achieved a radiochemical conversion (rcc) of 84% within 20 min in DMA at 110 °C under phase-transfer catalysis conditions. The same catalytic system was used by Neumaier, although in that case [ 18 F]Fwas eluted with Et4NHCO3 in n butanol [141]. As demonstrated by the reported examples, the achieved rcc rates were found to be almost quantitative ( Table 6, entry 4). The The developed conditions saw the azidation performed in excellent isolated yields, while the coupling efficiency did not correlate with the electron-donating ability of the substituents. However, the isolated yield of azidoindole was only 51%. The reaction course could be followed colorimetrically as the dark brown solution turned light green upon completion. Recently, the rapid palladiumcatalyzed [ 11 C] C-cyanation of aryl-or heteroarylboronates was reported [136]. The reaction conditions allowed for the rapid conversion of the starting boronates by means of treatment with a [ 11 C] NH4CN/NH3 system in the presence of a PdCl2(PPh3)2 catalyst. The high efficiency of the developed protocol was demonstrated via the cyanation of indolylboronate in a 90% radiochemical yield (rcy) and the synthesis of [ 11 C] C-labeled cetrozole.
The ipso-substitution of B-moiety via a halogen atom represents an alternative approach for the synthesis of halogenated arenes. This transformation can be performed under transition-metal-free conditions by means of iodine and KF in dioxane at 80 °C (Table 6, entry 1) [137]. The isolated yield of iodoindole is high. However, this reaction is less important from a practical point of view, as indoles can be regioselectively lithiated at the 3-position by means of t BuLi [138]. The fluorination of indoles is more import, as fluorinated indoles are of interest due to their potential use in the field of medicine. Thus, Hartwig developed the copper(I)-catalyzed fluorination of pinacol boronic ester via an electrophilic fluorine source in THF at 50 °C (Table 6, entry 2) [139]. Overall, the isolated yields of the fluorinated arenes ranged from 29% to 77%, with a 44% isolated yield of 5-fluoroindole being achieved. Radiofluorination is a more attractive concept in relation to the fluorination of indoles. Two different procedures have thus far been reported ( Table 6, entries 3 and 4). Both published procedures rely on Cu-mediated radiofluorination with different fluoride sources. Krasikova [140] achieved a radiochemical conversion (rcc) of 84% within 20 min in DMA at 110 °C under phase-transfer catalysis conditions. The same catalytic system was used by Neumaier, although in that case [ 18 F]Fwas eluted with Et4NHCO3 in n butanol [141]. As demonstrated by the reported examples, the achieved rcc rates were found to be almost quantitative ( The developed conditions saw the azidation performed in excellent isolated yields, while the coupling efficiency did not correlate with the electron-donating ability of the substituents. However, the isolated yield of azidoindole was only 51%. The reaction course could be followed colorimetrically as the dark brown solution turned light green upon completion. Recently, the rapid palladiumcatalyzed [ 11 C] C-cyanation of aryl-or heteroarylboronates was reported [136]. The reaction conditions allowed for the rapid conversion of the starting boronates by means of treatment with a [ 11 C] NH4CN/NH3 system in the presence of a PdCl2(PPh3)2 catalyst. The high efficiency of the developed protocol was demonstrated via the cyanation of indolylboronate in a 90% radiochemical yield (rcy) and the synthesis of [ 11 C] C-labeled cetrozole.
The ipso-substitution of B-moiety via a halogen atom represents an alternative approach for the synthesis of halogenated arenes. This transformation can be performed under transition-metal-free conditions by means of iodine and KF in dioxane at 80 °C (Table 6, entry 1) [137]. The isolated yield of iodoindole is high. However, this reaction is less important from a practical point of view, as indoles can be regioselectively lithiated at the 3-position by means of t BuLi [138]. The fluorination of indoles is more import, as fluorinated indoles are of interest due to their potential use in the field of medicine. Thus, Hartwig developed the copper(I)-catalyzed fluorination of pinacol boronic ester via an electrophilic fluorine source in THF at 50 °C (Table 6, entry 2) [139]. Overall, the isolated yields of the fluorinated arenes ranged from 29% to 77%, with a 44% isolated yield of 5-fluoroindole being achieved. Radiofluorination is a more attractive concept in relation to the fluorination of indoles. Two different procedures have thus far been reported ( Table 6, entries 3 and 4). Both published procedures rely on Cu-mediated radiofluorination with different fluoride sources. Krasikova [140] achieved a radiochemical conversion (rcc) of 84% within 20 min in DMA at 110 °C under phase-transfer catalysis conditions. The same catalytic system was used by Neumaier, although in that case [ 18 F]Fwas eluted with Et4NHCO3 in n butanol [141]. As demonstrated by the reported examples, the achieved rcc rates were found to be almost quantitative ( The developed conditions saw the azidation performed in excellent isolated yields, while the coupling efficiency did not correlate with the electron-donating ability of the substituents. However, the isolated yield of azidoindole was only 51%. The reaction course could be followed colorimetrically as the dark brown solution turned light green upon completion. Recently, the rapid palladiumcatalyzed [ 11 C] C-cyanation of aryl-or heteroarylboronates was reported [136]. The reaction conditions allowed for the rapid conversion of the starting boronates by means of treatment with a [ 11 C] NH4CN/NH3 system in the presence of a PdCl2(PPh3)2 catalyst. The high efficiency of the developed protocol was demonstrated via the cyanation of indolylboronate in a 90% radiochemical yield (rcy) and the synthesis of [ 11 C] C-labeled cetrozole.
The ipso-substitution of B-moiety via a halogen atom represents an alternative approach for the synthesis of halogenated arenes. This transformation can be performed under transition-metal-free conditions by means of iodine and KF in dioxane at 80 °C (Table 6, entry 1) [137]. The isolated yield of iodoindole is high. However, this reaction is less important from a practical point of view, as indoles can be regioselectively lithiated at the 3-position by means of t BuLi [138]. The fluorination of indoles is more import, as fluorinated indoles are of interest due to their potential use in the field of medicine. Thus, Hartwig developed the copper(I)-catalyzed fluorination of pinacol boronic ester via an electrophilic fluorine source in THF at 50 °C (Table 6, entry 2) [139]. Overall, the isolated yields of the fluorinated arenes ranged from 29% to 77%, with a 44% isolated yield of 5-fluoroindole being achieved. Radiofluorination is a more attractive concept in relation to the fluorination of indoles. Two different procedures have thus far been reported ( Table 6, entries 3 and 4). Both published procedures rely on Cu-mediated radiofluorination with different fluoride sources. Krasikova [140] achieved a radiochemical conversion (rcc) of 84% within 20 min in DMA at 110 °C under phase-transfer catalysis conditions. The same catalytic system was used by Neumaier, although in that case [ 18 F]Fwas eluted with Et4NHCO3 in n butanol [141]. As demonstrated by the reported examples, the achieved rcc rates were found to be almost quantitative ( The developed conditions saw the azidation performed in excellent isolated yields, while the coupling efficiency did not correlate with the electron-donating ability of the substituents. However, the isolated yield of azidoindole was only 51%. The reaction course could be followed colorimetrically as the dark brown solution turned light green upon completion. Recently, the rapid palladiumcatalyzed [ 11 C] C-cyanation of aryl-or heteroarylboronates was reported [136]. The reaction conditions allowed for the rapid conversion of the starting boronates by means of treatment with a [ 11 C] NH4CN/NH3 system in the presence of a PdCl2(PPh3)2 catalyst. The high efficiency of the developed protocol was demonstrated via the cyanation of indolylboronate in a 90% radiochemical yield (rcy) and the synthesis of [ 11 C] C-labeled cetrozole.
The ipso-substitution of B-moiety via a halogen atom represents an alternative approach for the synthesis of halogenated arenes. This transformation can be performed under transition-metal-free conditions by means of iodine and KF in dioxane at 80 °C (Table 6, entry 1) [137]. The isolated yield of iodoindole is high. However, this reaction is less important from a practical point of view, as indoles can be regioselectively lithiated at the 3-position by means of t BuLi [138]. The fluorination of indoles is more import, as fluorinated indoles are of interest due to their potential use in the field of medicine. Thus, Hartwig developed the copper(I)-catalyzed fluorination of pinacol boronic ester via an electrophilic fluorine source in THF at 50 °C (Table 6, entry 2) [139]. Overall, the isolated yields of the fluorinated arenes ranged from 29% to 77%, with a 44% isolated yield of 5-fluoroindole being achieved. Radiofluorination is a more attractive concept in relation to the fluorination of indoles. Two different procedures have thus far been reported ( Table 6, entries 3 and 4). Both published procedures rely on Cu-mediated radiofluorination with different fluoride sources. Krasikova [140] achieved a radiochemical conversion (rcc) of 84% within 20 min in DMA at 110 °C under phase-transfer catalysis conditions. The same catalytic system was used by Neumaier, although in that case [ 18 F]Fwas eluted with Et4NHCO3 in n butanol [141]. As demonstrated by the reported examples, the achieved rcc rates were found to be almost quantitative ( Table 6, entry 4). The The fluorination of indoles is more import, as fluorinated indoles are of interest due to their potential use in the field of medicine. Thus, Hartwig developed the copper(I)-catalyzed fluorination of pinacol boronic ester via an electrophilic fluorine source in THF at 50 • C ( Table 6, entry 2) [139]. Overall, the isolated yields of the fluorinated arenes ranged from 29% to 77%, with a 44% isolated yield of 5-fluoroindole being achieved. Radiofluorination is a more attractive concept in relation to the fluorination of indoles. Two different procedures have thus far been reported ( Table 6, entries 3 and 4). Both published procedures rely on Cu-mediated radiofluorination with different fluoride sources. Krasikova [140] achieved a radiochemical conversion (rcc) of 84% within 20 min in DMA at 110 • C under phase-transfer catalysis conditions. The same catalytic system was used by Neumaier, although in that case [ 18 F]Fwas eluted with Et 4 NHCO 3 in n butanol [141]. As demonstrated by the reported examples, the achieved rcc rates were found to be almost quantitative ( Table 6, entry 4). The developed reaction conditions were used for the synthesis of a PET probe by means of the radiofluorination of the SnMe 3 substrate.
Ermert [142] developed a protocol for the copper(II)-catalyzed fluorination of indolylboronic acid pinacol esters by means of Et 4 N[ 18 F]F. This protocol was applied for the synthesis of 6-6-[ 18 F]fluoro-L-tryptophan (Scheme 34). The starting bromoindole S34-1 was prepared according to the procedure described in the literature [143]. Then, Miyaura borylation was used for the bromine substitution with the Bpin moiety and the resultant radiolabeled fluorination, along with hydrolysis, afforded the tryptophan derivative S34-3 in an overall isolated yield of 37% and moderate rcc. developed reaction conditions were used for the synthesis of a PET probe by means of the radiofluorination of the SnMe3 substrate. Ermert [142] developed a protocol for the copper(II)-catalyzed fluorination of indolylboronic acid pinacol esters by means of Et4N[ 18 F]F. This protocol was applied for the synthesis of 6-6-[ 18 F]fluoro-L-tryptophan (Scheme 34). The starting bromoindole S34-1 was prepared according to the procedure described in the literature [143]. Then, Miyaura borylation was used for the bromine substitution with the Bpin moiety and the resultant radiolabeled fluorination, along with hydrolysis, afforded the tryptophan derivative S34-3 in an overall isolated yield of 37% and moderate rcc.

Scheme 34. Radiolabeled synthesis of fluorinated L-tryptophan.
A logical extension of the halogenation reactions of indolylboronic acids can be seen in the case of trifluoromethylation, since a trifluoromethyl group is a prominent structural motif present in biologically active compounds used in the fields of pharmaceuticals and agrochemicals. An early report concerning such a procedure was published by Buchwald [144] (Table 7, entry 1). This coppermediated oxidative cross-coupling uses TMSCF3 (Ruppert's reagent) as a source of nucleophilic CF3 and oxygen as a stoichiometric reoxidant. The isolated yields of trifluoromethylated indoles were 44% and 61%, which demonstrates good agreement with the overall isolated yields. A similar procedure was published by Gooßen (Table 7, entry 2) [145]. This protocol substitutes the inconveniently volatile and moisture-sensitive Ruppert's reagent for crystalline potassium (trifluoromethyl)trimethoxyborate. Among the other substrates, the isolated yield of 5-(trifluoromethyl)-1-methylindole was only 49%. To overcome the need for stoichiometric amounts of copper, Liu [146] (Table 7, entry 3) suggested the use of (trifluoromethyl)dibenzothiophenium triflate as an electrophilic CF3 source. The greatest advantage offered by this method is the tolerance of an unprotected NH group, which meant that an unprotected trifluoromethylated indole was obtained in a 61% yield. Alternatively, Shen [147] exploited the use of Togni's reagent [148] using a similar method and achieved the highest isolated yield of trifluoromethylated indole of all the discussed procedures (Table 7, entry 4). A slightly different approach to trifluoromethylation was described by Molander et al. (Table 7, entry 5) [149]. They performed the radical trifluoromethylation of organotrifluoroborates by using sodium triflinate (Langlois reagent) as the source of the CF3 radicals and five equivalents of tert-butyl hydroperoxide (TBHP) in a mixture of solvents. Additionally, the introduction of the trifluoromethoxy group into an indole moiety via the coupling of the corresponding boronic acids was described by Ritter [150]. His two-step, one-pot procedure includes the reaction of indolylboronic acids with NaOH (1 equiv.) and AgPF6 (2 equiv.) in methanol, followed by treatment with TAS•OCF3 and the Selectfluor-type reagent (F-TEDA-PF6). A logical extension of the halogenation reactions of indolylboronic acids can be seen in the case of trifluoromethylation, since a trifluoromethyl group is a prominent structural motif present in biologically active compounds used in the fields of pharmaceuticals and agrochemicals. An early report concerning such a procedure was published by Buchwald [144] (Table 7, entry 1). This copper-mediated oxidative cross-coupling uses TMSCF 3 (Ruppert's reagent) as a source of nucleophilic CF 3 and oxygen as a stoichiometric reoxidant. The isolated yields of trifluoromethylated indoles were 44% and 61%, which demonstrates good agreement with the overall isolated yields. A similar procedure was published by Gooßen (Table 7, entry 2) [145]. This protocol substitutes the inconveniently volatile and moisture-sensitive Ruppert's reagent for crystalline potassium (trifluoromethyl)trimethoxyborate. Among the other substrates, the isolated yield of 5-(trifluoromethyl)-1-methylindole was only 49%. To overcome the need for stoichiometric amounts of copper, Liu [146] (Table 7, entry 3) suggested the use of (trifluoromethyl)dibenzothiophenium triflate as an electrophilic CF 3 source. The greatest advantage offered by this method is the tolerance of an unprotected NH group, which meant that an unprotected trifluoromethylated indole was obtained in a 61% yield. Alternatively, Shen [147] exploited the use of Togni's reagent [148] using a similar method and achieved the highest isolated yield of trifluoromethylated indole of all the discussed procedures (Table 7, entry 4). A slightly different approach to trifluoromethylation was described by Molander et al. (Table 7, entry 5) [149]. They performed the radical trifluoromethylation of organotrifluoroborates by using sodium triflinate (Langlois reagent) as the source of the CF 3 radicals and five equivalents of tert-butyl hydroperoxide (TBHP) in a mixture of solvents. Additionally, the introduction of the trifluoromethoxy group into an indole moiety via the coupling of the corresponding boronic acids was described by Ritter [150]. His two-step, one-pot procedure includes the reaction of indolylboronic acids with NaOH (1 equiv.) and AgPF 6 (2 equiv.) in methanol, followed by treatment with TAS·OCF 3 and the Selectfluor-type reagent (F-TEDA-PF 6 ).  The methylation of indole boronic esters can be achieved by a simple cross-coupling reaction with methyl iodide when compared to trifluoromethylation. The iron-catalyzed methylation approach described by Nakamura [151] (Scheme 35, condition A) presumably involves a radical mechanism whereby the methylation of the starting compound proceeds in the solvent cage, thereby affording 1,5-dimethylindole in a 74% isolated yield. The presence of a bulky bidentate ligand (SciPROP-TB) is required in this case. More traditional procedures make use of the cross-coupling between indolylboronic acid pinacol esters and methyl iodide catalyzed by palladium catalyst A, as reported by Hartwig et al. (Scheme 35, condition B) [152].  The methylation of indole boronic esters can be achieved by a simple cross-coupling reaction with methyl iodide when compared to trifluoromethylation. The iron-catalyzed methylation approach described by Nakamura [151] (Scheme 35, condition A) presumably involves a radical mechanism whereby the methylation of the starting compound proceeds in the solvent cage, thereby affording 1,5-dimethylindole in a 74% isolated yield. The presence of a bulky bidentate ligand (SciPROP-TB) is required in this case. More traditional procedures make use of the cross-coupling between indolylboronic acid pinacol esters and methyl iodide catalyzed by palladium catalyst A, as reported by Hartwig et al. (Scheme 35, condition B) [152].  The methylation of indole boronic esters can be achieved by a simple cross-coupling reaction with methyl iodide when compared to trifluoromethylation. The iron-catalyzed methylation approach described by Nakamura [151] (Scheme 35, condition A) presumably involves a radical mechanism whereby the methylation of the starting compound proceeds in the solvent cage, thereby affording 1,5-dimethylindole in a 74% isolated yield. The presence of a bulky bidentate ligand (SciPROP-TB) is required in this case. More traditional procedures make use of the cross-coupling between indolylboronic acid pinacol esters and methyl iodide catalyzed by palladium catalyst A, as reported by Hartwig et al. (Scheme 35, condition B) [152].  The methylation of indole boronic esters can be achieved by a simple cross-coupling reaction with methyl iodide when compared to trifluoromethylation. The iron-catalyzed methylation approach described by Nakamura [151] (Scheme 35, condition A) presumably involves a radical mechanism whereby the methylation of the starting compound proceeds in the solvent cage, thereby affording 1,5-dimethylindole in a 74% isolated yield. The presence of a bulky bidentate ligand (SciPROP-TB) is required in this case. More traditional procedures make use of the cross-coupling between indolylboronic acid pinacol esters and methyl iodide catalyzed by palladium catalyst A, as reported by Hartwig et al. (Scheme 35, condition B) [152].  The methylation of indole boronic esters can be achieved by a simple cross-coupling reaction with methyl iodide when compared to trifluoromethylation. The iron-catalyzed methylation approach described by Nakamura [151] (Scheme 35, condition A) presumably involves a radical mechanism whereby the methylation of the starting compound proceeds in the solvent cage, thereby affording 1,5-dimethylindole in a 74% isolated yield. The presence of a bulky bidentate ligand (SciPROP-TB) is required in this case. More traditional procedures make use of the cross-coupling between indolylboronic acid pinacol esters and methyl iodide catalyzed by palladium catalyst A, as reported by Hartwig et al. (Scheme 35, condition B) [152].  The methylation of indole boronic esters can be achieved by a simple cross-coupling reaction with methyl iodide when compared to trifluoromethylation. The iron-catalyzed methylation approach described by Nakamura [151] (Scheme 35, condition A) presumably involves a radical mechanism whereby the methylation of the starting compound proceeds in the solvent cage, thereby affording 1,5-dimethylindole in a 74% isolated yield. The presence of a bulky bidentate ligand (SciPROP-TB) is required in this case. More traditional procedures make use of the cross-coupling between indolylboronic acid pinacol esters and methyl iodide catalyzed by palladium catalyst A, as reported by Hartwig et al. (Scheme 35, condition B) [152]. The authors provided a simple methylation of indomethacin as an example of the late-stage methylation of a bioactive compound. Alternatively, trimethyl phosphate can be used in combination The methylation of indole boronic esters can be achieved by a simple cross-coupling reaction with methyl iodide when compared to trifluoromethylation. The iron-catalyzed methylation approach described by Nakamura [151] (Scheme 35, condition A) presumably involves a radical mechanism whereby the methylation of the starting compound proceeds in the solvent cage, thereby affording 1,5-dimethylindole in a 74% isolated yield. The presence of a bulky bidentate ligand (SciPROP-TB) is required in this case. More traditional procedures make use of the cross-coupling between indolylboronic acid pinacol esters and methyl iodide catalyzed by palladium catalyst A, as reported by Hartwig et al. (Scheme 35, condition B) [152].  The methylation of indole boronic esters can be achieved by a simple cross-coupling reaction with methyl iodide when compared to trifluoromethylation. The iron-catalyzed methylation approach described by Nakamura [151] (Scheme 35, condition A) presumably involves a radical mechanism whereby the methylation of the starting compound proceeds in the solvent cage, thereby affording 1,5-dimethylindole in a 74% isolated yield. The presence of a bulky bidentate ligand (SciPROP-TB) is required in this case. More traditional procedures make use of the cross-coupling between indolylboronic acid pinacol esters and methyl iodide catalyzed by palladium catalyst A, as reported by Hartwig et al. (Scheme 35, condition B) [152]. The authors provided a simple methylation of indomethacin as an example of the late-stage methylation of a bioactive compound. Alternatively, trimethyl phosphate can be used in combination with iodine salt as a milder source of slow-releasing methyl iodide, as described by Hartwig [153] (Scheme 35, condition C). The isolated yields of methylated indoles were 62-70%. It was proposed that the lithium iodide reacts with the trimethyl phosphate (S35-3) to slowly release methyl iodide (S35-4). This reaction represents a rate-determining step. Subsequently, the methyl iodide reacts with the arylcopper intermediate so as to give the product of the methylation. Any side reactions are suppressed by the slow release of methyl iodide as well as the acid base reaction between ArBpin S35-5 and t BuOLi.
Gomez [154] focused on the direct benzylation of 2-indolylboronic acids by means of benzyl bromides in the presence of a trans-PdBr(N-Succ)(PPh 3 ) 2 catalyst. This catalyst turned out to be the most efficient in terms of suppressing any undesired protodeboronation. The optimized conditions were applied on substituted indoles and benzyl bromides, thereby affording trisubstituted indoles in good isolated yields (Scheme 36). with iodine salt as a milder source of slow-releasing methyl iodide, as described by Hartwig [153] (Scheme 35, condition C). The isolated yields of methylated indoles were 62-70%. It was proposed that the lithium iodide reacts with the trimethyl phosphate (S35-3) to slowly release methyl iodide (S35-4). This reaction represents a rate-determining step. Subsequently, the methyl iodide reacts with the arylcopper intermediate so as to give the product of the methylation. Any side reactions are suppressed by the slow release of methyl iodide as well as the acid base reaction between ArBpin S35-5 and t BuOLi.
Gomez [154] focused on the direct benzylation of 2-indolylboronic acids by means of benzyl bromides in the presence of a trans-PdBr(N-Succ)(PPh3)2 catalyst. This catalyst turned out to be the most efficient in terms of suppressing any undesired protodeboronation. The optimized conditions were applied on substituted indoles and benzyl bromides, thereby affording trisubstituted indoles in good isolated yields (Scheme 36).

Scheme 36. Palladium-catalyzed benzylation of 2-indolylboronic acids S36-1.
A different approach for the synthesis of diarylmethanes was designed by Watson and Garnsey (Table 8, entry 1) [155]. Their methodology started with benzylamines, which were converted into pyridinium salts by refluxing with 2,4,6-triphenylpyrrilium tetrafluoroborate. Then, the benzylation of the indolylboronic acids was achieved by means of an Ni-catalyzed reaction in 1,4-dioxane at 60 °C. The authors hypothesized that the radical mechanism operated along the lines of the developed protocol. This idea was confirmed by the isolation of the benzylated TEMPO radical. The similar nickel-catalyzed benzylation of indolylboronic acid neopentylglycol ester was reported by Tobisu and Chatani (Table 8, entry 2) [156]. The reaction was conducted in toluene at 120 °C in the presence of the NHC ligand. The synthesis of the alkylated indole was performed on a multigram scale in a 90% isolated yield. Analogously to the benzylation protocols, a representative example of the asymmetric allylation of allyl phosphates with boronic acids was described by Hayashi [157]. The allylation of 5-(nepB)-1-methylindole was achieved by means of a CuCl-catalyzed reaction in the presence of sodium methoxide and the N-heterocyclic carbene. The formed allylated indole was isolated in an 89% yield and exhibited acceptable enantiomeric access of 88%. A different approach for the synthesis of diarylmethanes was designed by Watson and Garnsey (Table 8, entry 1) [155]. Their methodology started with benzylamines, which were converted into pyridinium salts by refluxing with 2,4,6-triphenylpyrrilium tetrafluoroborate. Then, the benzylation of the indolylboronic acids was achieved by means of an Ni-catalyzed reaction in 1,4-dioxane at 60 • C. The authors hypothesized that the radical mechanism operated along the lines of the developed protocol. This idea was confirmed by the isolation of the benzylated TEMPO radical. The similar nickel-catalyzed benzylation of indolylboronic acid neopentylglycol ester was reported by Tobisu and Chatani (Table 8, entry 2) [156]. The reaction was conducted in toluene at 120 • C in the presence of the NHC ligand. The synthesis of the alkylated indole was performed on a multigram scale in a 90% isolated yield. Analogously to the benzylation protocols, a representative example of the asymmetric allylation of allyl phosphates with boronic acids was described by Hayashi [157]. The allylation of 5-(nepB)-1-methylindole was achieved by means of a CuCl-catalyzed reaction in the presence of sodium methoxide and the N-heterocyclic carbene. The formed allylated indole was isolated in an 89% yield and exhibited acceptable enantiomeric access of 88%. with iodine salt as a milder source of slow-releasing methyl iodide, as described by Hartwig [153] (Scheme 35, condition C). The isolated yields of methylated indoles were 62-70%. It was proposed that the lithium iodide reacts with the trimethyl phosphate (S35-3) to slowly release methyl iodide (S35-4). This reaction represents a rate-determining step. Subsequently, the methyl iodide reacts with the arylcopper intermediate so as to give the product of the methylation. Any side reactions are suppressed by the slow release of methyl iodide as well as the acid base reaction between ArBpin S35-5 and t BuOLi.
Gomez [154] focused on the direct benzylation of 2-indolylboronic acids by means of benzyl bromides in the presence of a trans-PdBr(N-Succ)(PPh3)2 catalyst. This catalyst turned out to be the most efficient in terms of suppressing any undesired protodeboronation. The optimized conditions were applied on substituted indoles and benzyl bromides, thereby affording trisubstituted indoles in good isolated yields (Scheme 36).

Scheme 36. Palladium-catalyzed benzylation of 2-indolylboronic acids S36-1.
A different approach for the synthesis of diarylmethanes was designed by Watson and Garnsey (Table 8, entry 1) [155]. Their methodology started with benzylamines, which were converted into pyridinium salts by refluxing with 2,4,6-triphenylpyrrilium tetrafluoroborate. Then, the benzylation of the indolylboronic acids was achieved by means of an Ni-catalyzed reaction in 1,4-dioxane at 60 °C. The authors hypothesized that the radical mechanism operated along the lines of the developed protocol. This idea was confirmed by the isolation of the benzylated TEMPO radical. The similar nickel-catalyzed benzylation of indolylboronic acid neopentylglycol ester was reported by Tobisu and Chatani (Table 8, entry 2) [156]. The reaction was conducted in toluene at 120 °C in the presence of the NHC ligand. The synthesis of the alkylated indole was performed on a multigram scale in a 90% isolated yield. Analogously to the benzylation protocols, a representative example of the asymmetric allylation of allyl phosphates with boronic acids was described by Hayashi [157]. The allylation of 5-(nepB)-1-methylindole was achieved by means of a CuCl-catalyzed reaction in the presence of sodium methoxide and the N-heterocyclic carbene. The formed allylated indole was isolated in an 89% yield and exhibited acceptable enantiomeric access of 88%. with iodine salt as a milder source of slow-releasing methyl iodide, as described by Hartwig [153] (Scheme 35, condition C). The isolated yields of methylated indoles were 62-70%. It was proposed that the lithium iodide reacts with the trimethyl phosphate (S35-3) to slowly release methyl iodide (S35-4). This reaction represents a rate-determining step. Subsequently, the methyl iodide reacts with the arylcopper intermediate so as to give the product of the methylation. Any side reactions are suppressed by the slow release of methyl iodide as well as the acid base reaction between ArBpin S35-5 and t BuOLi.
Gomez [154] focused on the direct benzylation of 2-indolylboronic acids by means of benzyl bromides in the presence of a trans-PdBr(N-Succ)(PPh3)2 catalyst. This catalyst turned out to be the most efficient in terms of suppressing any undesired protodeboronation. The optimized conditions were applied on substituted indoles and benzyl bromides, thereby affording trisubstituted indoles in good isolated yields (Scheme 36).

Scheme 36. Palladium-catalyzed benzylation of 2-indolylboronic acids S36-1.
A different approach for the synthesis of diarylmethanes was designed by Watson and Garnsey (Table 8, entry 1) [155]. Their methodology started with benzylamines, which were converted into pyridinium salts by refluxing with 2,4,6-triphenylpyrrilium tetrafluoroborate. Then, the benzylation of the indolylboronic acids was achieved by means of an Ni-catalyzed reaction in 1,4-dioxane at 60 °C. The authors hypothesized that the radical mechanism operated along the lines of the developed protocol. This idea was confirmed by the isolation of the benzylated TEMPO radical. The similar nickel-catalyzed benzylation of indolylboronic acid neopentylglycol ester was reported by Tobisu and Chatani (Table 8, entry 2) [156]. The reaction was conducted in toluene at 120 °C in the presence of the NHC ligand. The synthesis of the alkylated indole was performed on a multigram scale in a 90% isolated yield. Analogously to the benzylation protocols, a representative example of the asymmetric allylation of allyl phosphates with boronic acids was described by Hayashi [157]. The allylation of 5-(nepB)-1-methylindole was achieved by means of a CuCl-catalyzed reaction in the presence of sodium methoxide and the N-heterocyclic carbene. The formed allylated indole was isolated in an 89% yield and exhibited acceptable enantiomeric access of 88%. Table 8. The benzylation of indolylboronic acids.

Entry
LG with iodine salt as a milder source of slow-releasing methyl iodide, as described by Hartwig [153] (Scheme 35, condition C). The isolated yields of methylated indoles were 62-70%. It was proposed that the lithium iodide reacts with the trimethyl phosphate (S35-3) to slowly release methyl iodide (S35-4). This reaction represents a rate-determining step. Subsequently, the methyl iodide reacts with the arylcopper intermediate so as to give the product of the methylation. Any side reactions are suppressed by the slow release of methyl iodide as well as the acid base reaction between ArBpin S35-5 and t BuOLi.
Gomez [154] focused on the direct benzylation of 2-indolylboronic acids by means of benzyl bromides in the presence of a trans-PdBr(N-Succ)(PPh3)2 catalyst. This catalyst turned out to be the most efficient in terms of suppressing any undesired protodeboronation. The optimized conditions were applied on substituted indoles and benzyl bromides, thereby affording trisubstituted indoles in good isolated yields (Scheme 36).

Scheme 36. Palladium-catalyzed benzylation of 2-indolylboronic acids S36-1.
A different approach for the synthesis of diarylmethanes was designed by Watson and Garnsey (Table 8, entry 1) [155]. Their methodology started with benzylamines, which were converted into pyridinium salts by refluxing with 2,4,6-triphenylpyrrilium tetrafluoroborate. Then, the benzylation of the indolylboronic acids was achieved by means of an Ni-catalyzed reaction in 1,4-dioxane at 60 °C. The authors hypothesized that the radical mechanism operated along the lines of the developed protocol. This idea was confirmed by the isolation of the benzylated TEMPO radical. The similar nickel-catalyzed benzylation of indolylboronic acid neopentylglycol ester was reported by Tobisu and Chatani (Table 8, entry 2) [156]. The reaction was conducted in toluene at 120 °C in the presence of the NHC ligand. The synthesis of the alkylated indole was performed on a multigram scale in a 90% isolated yield. Analogously to the benzylation protocols, a representative example of the asymmetric allylation of allyl phosphates with boronic acids was described by Hayashi [157]. The allylation of 5-(nepB)-1-methylindole was achieved by means of a CuCl-catalyzed reaction in the presence of sodium methoxide and the N-heterocyclic carbene. The formed allylated indole was isolated in an 89% yield and exhibited acceptable enantiomeric access of 88%. with iodine salt as a milder source of slow-releasing methyl iodide, as described by Hartwig [153] (Scheme 35, condition C). The isolated yields of methylated indoles were 62-70%. It was proposed that the lithium iodide reacts with the trimethyl phosphate (S35-3) to slowly release methyl iodide (S35-4). This reaction represents a rate-determining step. Subsequently, the methyl iodide reacts with the arylcopper intermediate so as to give the product of the methylation. Any side reactions are suppressed by the slow release of methyl iodide as well as the acid base reaction between ArBpin S35-5 and t BuOLi.
Gomez [154] focused on the direct benzylation of 2-indolylboronic acids by means of benzyl bromides in the presence of a trans-PdBr(N-Succ)(PPh3)2 catalyst. This catalyst turned out to be the most efficient in terms of suppressing any undesired protodeboronation. The optimized conditions were applied on substituted indoles and benzyl bromides, thereby affording trisubstituted indoles in good isolated yields (Scheme 36).

Scheme 36. Palladium-catalyzed benzylation of 2-indolylboronic acids S36-1.
A different approach for the synthesis of diarylmethanes was designed by Watson and Garnsey (Table 8, entry 1) [155]. Their methodology started with benzylamines, which were converted into pyridinium salts by refluxing with 2,4,6-triphenylpyrrilium tetrafluoroborate. Then, the benzylation of the indolylboronic acids was achieved by means of an Ni-catalyzed reaction in 1,4-dioxane at 60 °C. The authors hypothesized that the radical mechanism operated along the lines of the developed protocol. This idea was confirmed by the isolation of the benzylated TEMPO radical. The similar nickel-catalyzed benzylation of indolylboronic acid neopentylglycol ester was reported by Tobisu and Chatani (Table 8, entry 2) [156]. The reaction was conducted in toluene at 120 °C in the presence of the NHC ligand. The synthesis of the alkylated indole was performed on a multigram scale in a 90% isolated yield. Analogously to the benzylation protocols, a representative example of the asymmetric allylation of allyl phosphates with boronic acids was described by Hayashi [157]. The allylation of 5-(nepB)-1-methylindole was achieved by means of a CuCl-catalyzed reaction in the presence of sodium methoxide and the N-heterocyclic carbene. The formed allylated indole was isolated in an 89% yield and exhibited acceptable enantiomeric access of 88%. with iodine salt as a milder source of slow-releasing methyl iodide, as described by Hartwig [153] (Scheme 35, condition C). The isolated yields of methylated indoles were 62-70%. It was proposed that the lithium iodide reacts with the trimethyl phosphate (S35-3) to slowly release methyl iodide (S35-4). This reaction represents a rate-determining step. Subsequently, the methyl iodide reacts with the arylcopper intermediate so as to give the product of the methylation. Any side reactions are suppressed by the slow release of methyl iodide as well as the acid base reaction between ArBpin S35-5 and t BuOLi.
Gomez [154] focused on the direct benzylation of 2-indolylboronic acids by means of benzyl bromides in the presence of a trans-PdBr(N-Succ)(PPh3)2 catalyst. This catalyst turned out to be the most efficient in terms of suppressing any undesired protodeboronation. The optimized conditions were applied on substituted indoles and benzyl bromides, thereby affording trisubstituted indoles in good isolated yields (Scheme 36).

Scheme 36. Palladium-catalyzed benzylation of 2-indolylboronic acids S36-1.
A different approach for the synthesis of diarylmethanes was designed by Watson and Garnsey (Table 8, entry 1) [155]. Their methodology started with benzylamines, which were converted into pyridinium salts by refluxing with 2,4,6-triphenylpyrrilium tetrafluoroborate. Then, the benzylation of the indolylboronic acids was achieved by means of an Ni-catalyzed reaction in 1,4-dioxane at 60 °C. The authors hypothesized that the radical mechanism operated along the lines of the developed protocol. This idea was confirmed by the isolation of the benzylated TEMPO radical. The similar nickel-catalyzed benzylation of indolylboronic acid neopentylglycol ester was reported by Tobisu and Chatani (Table 8, entry 2) [156]. The reaction was conducted in toluene at 120 °C in the presence of the NHC ligand. The synthesis of the alkylated indole was performed on a multigram scale in a 90% isolated yield. Analogously to the benzylation protocols, a representative example of the asymmetric allylation of allyl phosphates with boronic acids was described by Hayashi [157]. The allylation of 5-(nepB)-1-methylindole was achieved by means of a CuCl-catalyzed reaction in the presence of sodium methoxide and the N-heterocyclic carbene. The formed allylated indole was isolated in an 89% yield and exhibited acceptable enantiomeric access of 88%. Table 8. The benzylation of indolylboronic acids.

Entry
LG The hydroxylation of aromatic or heteroaromatic boronic acids represents an alternative reaction pathway for synthesizing the corresponding phenols. In the case of indolylboronic acids or boronates, two protocols have been described in the literature. The first report relies on a C 70 fullerene-catalyzed reaction under photocatalytic conditions (Scheme 37, method A) [158]. However, the isolated yield of 6-hydroxyindoles S37-2 is significantly lower when compared to the tested aromatic boronic acids. A quantitative yield of 5-hydroxyindole was achieved by means of oxone oxidation under phase-transfer conditions (Scheme 37, method B) [159]. In addition to the quantitative yield of S37-3, the described protocol allows for the chemoselective oxidation of boronic acids over pinacol boronates. The chemoselectivity is achieved via the faster trihydroxyboronate transfer from the organic layer to the water layer. The hydroxylation of aromatic or heteroaromatic boronic acids represents an alternative reaction pathway for synthesizing the corresponding phenols. In the case of indolylboronic acids or boronates, two protocols have been described in the literature. The first report relies on a C70 fullerene-catalyzed reaction under photocatalytic conditions (Scheme 37, method A) [158]. However, the isolated yield of 6-hydroxyindoles S37-2 is significantly lower when compared to the tested aromatic boronic acids. A quantitative yield of 5-hydroxyindole was achieved by means of oxone oxidation under phasetransfer conditions (Scheme 37, method B) [159]. In addition to the quantitative yield of S37-3, the described protocol allows for the chemoselective oxidation of boronic acids over pinacol boronates. The chemoselectivity is achieved via the faster trihydroxyboronate transfer from the organic layer to the water layer. In an effort to expand the diversity-oriented synthesis of substituted indoles, two different carbonylation procedures have been reported (Table 9, entries 1 and 2). In the first report, Skrydstrup [160] made use of a traditional palladium catalyst with a Xantphos ligand and the carbonylation of boronic acids with CO and N,N-diethyl-α-bromo-α,α-difluoroacetamide. It was determined that the reaction is suitable for the carbonylation of unprotected indoles, thereby affording the product in a good isolated yield. In an effort to expand the diversity-oriented synthesis of substituted indoles, two different carbonylation procedures have been reported (Table 9, entries 1 and 2). In the first report, Skrydstrup [160] made use of a traditional palladium catalyst with a Xantphos ligand and the carbonylation of boronic acids with CO and N,N-diethyl-α-bromo-α,α-difluoroacetamide. It was determined that the reaction is suitable for the carbonylation of unprotected indoles, thereby affording the product in a good isolated yield. The hydroxylation of aromatic or heteroaromatic boronic acids represents an alternative reaction pathway for synthesizing the corresponding phenols. In the case of indolylboronic acids or boronates, two protocols have been described in the literature. The first report relies on a C70 fullerene-catalyzed reaction under photocatalytic conditions (Scheme 37, method A) [158]. However, the isolated yield of 6-hydroxyindoles S37-2 is significantly lower when compared to the tested aromatic boronic acids. A quantitative yield of 5-hydroxyindole was achieved by means of oxone oxidation under phasetransfer conditions (Scheme 37, method B) [159]. In addition to the quantitative yield of S37-3, the described protocol allows for the chemoselective oxidation of boronic acids over pinacol boronates. The chemoselectivity is achieved via the faster trihydroxyboronate transfer from the organic layer to the water layer. In an effort to expand the diversity-oriented synthesis of substituted indoles, two different carbonylation procedures have been reported (Table 9, entries 1 and 2). In the first report, Skrydstrup [160] made use of a traditional palladium catalyst with a Xantphos ligand and the carbonylation of boronic acids with CO and N,N-diethyl-α-bromo-α,α-difluoroacetamide. It was determined that the reaction is suitable for the carbonylation of unprotected indoles, thereby affording the product in a good isolated yield. The hydroxylation of aromatic or heteroaromatic boronic acids represents an alternative reaction pathway for synthesizing the corresponding phenols. In the case of indolylboronic acids or boronates, two protocols have been described in the literature. The first report relies on a C70 fullerene-catalyzed reaction under photocatalytic conditions (Scheme 37, method A) [158]. However, the isolated yield of 6-hydroxyindoles S37-2 is significantly lower when compared to the tested aromatic boronic acids. A quantitative yield of 5-hydroxyindole was achieved by means of oxone oxidation under phasetransfer conditions (Scheme 37, method B) [159]. In addition to the quantitative yield of S37-3, the described protocol allows for the chemoselective oxidation of boronic acids over pinacol boronates. The chemoselectivity is achieved via the faster trihydroxyboronate transfer from the organic layer to the water layer. In an effort to expand the diversity-oriented synthesis of substituted indoles, two different carbonylation procedures have been reported (Table 9, entries 1 and 2). In the first report, Skrydstrup [160] made use of a traditional palladium catalyst with a Xantphos ligand and the carbonylation of boronic acids with CO and N,N-diethyl-α-bromo-α,α-difluoroacetamide. It was determined that the reaction is suitable for the carbonylation of unprotected indoles, thereby affording the product in a good isolated yield. The hydroxylation of aromatic or heteroaromatic boronic acids represents an alternative reaction pathway for synthesizing the corresponding phenols. In the case of indolylboronic acids or boronates, two protocols have been described in the literature. The first report relies on a C70 fullerene-catalyzed reaction under photocatalytic conditions (Scheme 37, method A) [158]. However, the isolated yield of 6-hydroxyindoles S37-2 is significantly lower when compared to the tested aromatic boronic acids. A quantitative yield of 5-hydroxyindole was achieved by means of oxone oxidation under phasetransfer conditions (Scheme 37, method B) [159]. In addition to the quantitative yield of S37-3, the described protocol allows for the chemoselective oxidation of boronic acids over pinacol boronates. The chemoselectivity is achieved via the faster trihydroxyboronate transfer from the organic layer to the water layer. In an effort to expand the diversity-oriented synthesis of substituted indoles, two different carbonylation procedures have been reported (Table 9, entries 1 and 2). In the first report, Skrydstrup [160] made use of a traditional palladium catalyst with a Xantphos ligand and the carbonylation of boronic acids with CO and N,N-diethyl-α-bromo-α,α-difluoroacetamide. It was determined that the reaction is suitable for the carbonylation of unprotected indoles, thereby affording the product in a good isolated yield. The hydroxylation of aromatic or heteroaromatic boronic acids represents an alternative reaction pathway for synthesizing the corresponding phenols. In the case of indolylboronic acids or boronates, two protocols have been described in the literature. The first report relies on a C70 fullerene-catalyzed reaction under photocatalytic conditions (Scheme 37, method A) [158]. However, the isolated yield of 6-hydroxyindoles S37-2 is significantly lower when compared to the tested aromatic boronic acids. A quantitative yield of 5-hydroxyindole was achieved by means of oxone oxidation under phasetransfer conditions (Scheme 37, method B) [159]. In addition to the quantitative yield of S37-3, the described protocol allows for the chemoselective oxidation of boronic acids over pinacol boronates. The chemoselectivity is achieved via the faster trihydroxyboronate transfer from the organic layer to the water layer. In an effort to expand the diversity-oriented synthesis of substituted indoles, two different carbonylation procedures have been reported (Table 9, entries 1 and 2). In the first report, Skrydstrup [160] made use of a traditional palladium catalyst with a Xantphos ligand and the carbonylation of boronic acids with CO and N,N-diethyl-α-bromo-α,α-difluoroacetamide. It was determined that the reaction is suitable for the carbonylation of unprotected indoles, thereby affording the product in a good isolated yield. The hydroxylation of aromatic or heteroaromatic boronic acids represents an alternative reaction pathway for synthesizing the corresponding phenols. In the case of indolylboronic acids or boronates, two protocols have been described in the literature. The first report relies on a C70 fullerene-catalyzed reaction under photocatalytic conditions (Scheme 37, method A) [158]. However, the isolated yield of 6-hydroxyindoles S37-2 is significantly lower when compared to the tested aromatic boronic acids. A quantitative yield of 5-hydroxyindole was achieved by means of oxone oxidation under phasetransfer conditions (Scheme 37, method B) [159]. In addition to the quantitative yield of S37-3, the described protocol allows for the chemoselective oxidation of boronic acids over pinacol boronates. The chemoselectivity is achieved via the faster trihydroxyboronate transfer from the organic layer to the water layer. In an effort to expand the diversity-oriented synthesis of substituted indoles, two different carbonylation procedures have been reported (Table 9, entries 1 and 2). In the first report, Skrydstrup [160] made use of a traditional palladium catalyst with a Xantphos ligand and the carbonylation of boronic acids with CO and N,N-diethyl-α-bromo-α,α-difluoroacetamide. It was determined that the reaction is suitable for the carbonylation of unprotected indoles, thereby affording the product in a good isolated yield. The hydroxylation of aromatic or heteroaromatic boronic acids represents an alternative reaction pathway for synthesizing the corresponding phenols. In the case of indolylboronic acids or boronates, two protocols have been described in the literature. The first report relies on a C70 fullerene-catalyzed reaction under photocatalytic conditions (Scheme 37, method A) [158]. However, the isolated yield of 6-hydroxyindoles S37-2 is significantly lower when compared to the tested aromatic boronic acids. A quantitative yield of 5-hydroxyindole was achieved by means of oxone oxidation under phasetransfer conditions (Scheme 37, method B) [159]. In addition to the quantitative yield of S37-3, the described protocol allows for the chemoselective oxidation of boronic acids over pinacol boronates. The chemoselectivity is achieved via the faster trihydroxyboronate transfer from the organic layer to the water layer. In an effort to expand the diversity-oriented synthesis of substituted indoles, two different carbonylation procedures have been reported (Table 9, entries 1 and 2). In the first report, Skrydstrup [160] made use of a traditional palladium catalyst with a Xantphos ligand and the carbonylation of boronic acids with CO and N,N-diethyl-α-bromo-α,α-difluoroacetamide. It was determined that the reaction is suitable for the carbonylation of unprotected indoles, thereby affording the product in a good isolated yield. The reaction was also extended to include α-bromo-α,α-difluoroacetates. The presence of two equivalents of 1,4-dinitrobenzene suppressed the reaction, while the two equivalents of TEMPO resulted in the isolation of the corresponding adducts. These experiments indicated a SET mechanism for the carbonylation. Different from Skrydstrup's protocol, Szostak [161] applied an alternative method for the carbonylation of boronic acids. His protocol is based on the cross-coupling reaction of the activated C−N amide bond. Thus, the cyclic amide T9-3 was found to be the best substrate, affording various ketones along with the indole in good isolated yields (Table 9, entry 2). The methodology of the CO carbonylation of indolylboronic acid pinacol boronic esters was extended to cover methoxycarbonylation (Table 9, entry 3) [162]. Weinreb amides are useful synthons for Weinreb ketone synthesis [163]. Therefore, it is unsurprising that the simple and high-yielding synthesis of Weinreb amides has been pursued ( Table 9, entry 4) [164]. Different boronic acids and organotrifluoroborates were mixed with N-methoxy-N-methylcarbamoyl chloride in the presence of PdCl 2 (PPh 3 ) 2 and potassium phosphate in ethanol, thereby affording, for instance, 1H protected and unprotected indole-based amides in good isolated yields.
Among the other aromatic and heteroaromatic boronates, 1-methyl-5-nepBindole smoothly reacted with arylcarbamate in the rhodium-catalyzed reaction so as to yield 5-substituted indole in a 93% isolated yield (Table 10, entry 1). Interestingly, the cross-coupling reaction was achieved by means of a catalytic amount of the Rh catalyst [165]. The Liebeskind−Srogl cross-coupling reaction was used for the synthesis of substituted BODIPY involving Biellmann BODIPY (Table 10, entry 2) [166]. The reaction was catalyzed by Pd 2 (dba) 3 in the presence of a catalytic amount of trifurylphosphine and a stoichiometric amount of CuTC, thereby leading to variously substituted BODIPYs. The reaction can also be performed under microwave heating, and the fluorescent efficiency was tested on prepared substances. The reaction was also extended to include α-bromo-α,α-difluoroacetates. The presence of two equivalents of 1,4-dinitrobenzene suppressed the reaction, while the two equivalents of TEMPO resulted in the isolation of the corresponding adducts. These experiments indicated a SET mechanism for the carbonylation. Different from Skrydstrup's protocol, Szostak [161] applied an alternative method for the carbonylation of boronic acids. His protocol is based on the cross-coupling reaction of the activated C−N amide bond. Thus, the cyclic amide T9-3 was found to be the best substrate, affording various ketones along with the indole in good isolated yields (Table 9, entry 2). The methodology of the CO carbonylation of indolylboronic acid pinacol boronic esters was extended to cover methoxycarbonylation (Table 9, entry 3) [162]. Weinreb amides are useful synthons for Weinreb ketone synthesis [163]. Therefore, it is unsurprising that the simple and high-yielding synthesis of Weinreb amides has been pursued ( Table 9, entry 4) [164]. Different boronic acids and organotrifluoroborates were mixed with N-methoxy-N-methylcarbamoyl chloride in the presence of PdCl2(PPh3)2 and potassium phosphate in ethanol, thereby affording, for instance, 1H protected and unprotected indole-based amides in good isolated yields.
Among the other aromatic and heteroaromatic boronates, 1-methyl-5-nepBindole smoothly reacted with arylcarbamate in the rhodium-catalyzed reaction so as to yield 5-substituted indole in a 93% isolated yield (Table 10, entry 1). Interestingly, the cross-coupling reaction was achieved by means of a catalytic amount of the Rh catalyst [165]. The Liebeskind−Srogl cross-coupling reaction was used for the synthesis of substituted BODIPY involving Biellmann BODIPY (Table 10, entry 2) [166]. The reaction was catalyzed by Pd2(dba)3 in the presence of a catalytic amount of trifurylphosphine and a stoichiometric amount of CuTC, thereby leading to variously substituted BODIPYs. The reaction can also be performed under microwave heating, and the fluorescent efficiency was tested on prepared substances. Table 10. Palladium-and rhodium-catalyzed arylation of indolylboronic acids.

Entry
LG A similar type of cross-coupling reaction was described by Pentelute and Buchwald (Scheme 38) [167]. In their report, they applied an umpolung strategy for the bioconjugation of the selenocysteine in unprotected peptides. The reaction was conducted by mixing boronic acids in the presence of copper (II) sulfate and the phenanthroline ligand. The incorporation of diverse indolylboronic acids S38-2 and S38-3 was achieved in good yields.

Entry
LG BX 2 Conditions T10-3 The reaction was also extended to include α-bromo-α,α-difluoroacetates. The presence of two equivalents of 1,4-dinitrobenzene suppressed the reaction, while the two equivalents of TEMPO resulted in the isolation of the corresponding adducts. These experiments indicated a SET mechanism for the carbonylation. Different from Skrydstrup's protocol, Szostak [161] applied an alternative method for the carbonylation of boronic acids. His protocol is based on the cross-coupling reaction of the activated C−N amide bond. Thus, the cyclic amide T9-3 was found to be the best substrate, affording various ketones along with the indole in good isolated yields (Table 9, entry 2). The methodology of the CO carbonylation of indolylboronic acid pinacol boronic esters was extended to cover methoxycarbonylation (Table 9, entry 3) [162]. Weinreb amides are useful synthons for Weinreb ketone synthesis [163]. Therefore, it is unsurprising that the simple and high-yielding synthesis of Weinreb amides has been pursued ( Table 9, entry 4) [164]. Different boronic acids and organotrifluoroborates were mixed with N-methoxy-N-methylcarbamoyl chloride in the presence of PdCl2(PPh3)2 and potassium phosphate in ethanol, thereby affording, for instance, 1H protected and unprotected indole-based amides in good isolated yields.
Among the other aromatic and heteroaromatic boronates, 1-methyl-5-nepBindole smoothly reacted with arylcarbamate in the rhodium-catalyzed reaction so as to yield 5-substituted indole in a 93% isolated yield (Table 10, entry 1). Interestingly, the cross-coupling reaction was achieved by means of a catalytic amount of the Rh catalyst [165]. The Liebeskind−Srogl cross-coupling reaction was used for the synthesis of substituted BODIPY involving Biellmann BODIPY (Table 10, entry 2) [166]. The reaction was catalyzed by Pd2(dba)3 in the presence of a catalytic amount of trifurylphosphine and a stoichiometric amount of CuTC, thereby leading to variously substituted BODIPYs. The reaction can also be performed under microwave heating, and the fluorescent efficiency was tested on prepared substances. Table 10. Palladium-and rhodium-catalyzed arylation of indolylboronic acids.

Entry
LG A similar type of cross-coupling reaction was described by Pentelute and Buchwald (Scheme 38) [167]. In their report, they applied an umpolung strategy for the bioconjugation of the selenocysteine in unprotected peptides. The reaction was conducted by mixing boronic acids in the presence of copper (II) sulfate and the phenanthroline ligand. The incorporation of diverse indolylboronic acids S38-2 and S38-3 was achieved in good yields. The reaction was also extended to include α-bromo-α,α-difluoroacetates. The presence of two equivalents of 1,4-dinitrobenzene suppressed the reaction, while the two equivalents of TEMPO resulted in the isolation of the corresponding adducts. These experiments indicated a SET mechanism for the carbonylation. Different from Skrydstrup's protocol, Szostak [161] applied an alternative method for the carbonylation of boronic acids. His protocol is based on the cross-coupling reaction of the activated C−N amide bond. Thus, the cyclic amide T9-3 was found to be the best substrate, affording various ketones along with the indole in good isolated yields (Table 9, entry 2). The methodology of the CO carbonylation of indolylboronic acid pinacol boronic esters was extended to cover methoxycarbonylation (Table 9, entry 3) [162]. Weinreb amides are useful synthons for Weinreb ketone synthesis [163]. Therefore, it is unsurprising that the simple and high-yielding synthesis of Weinreb amides has been pursued ( Table 9, entry 4) [164]. Different boronic acids and organotrifluoroborates were mixed with N-methoxy-N-methylcarbamoyl chloride in the presence of PdCl2(PPh3)2 and potassium phosphate in ethanol, thereby affording, for instance, 1H protected and unprotected indole-based amides in good isolated yields.
Among the other aromatic and heteroaromatic boronates, 1-methyl-5-nepBindole smoothly reacted with arylcarbamate in the rhodium-catalyzed reaction so as to yield 5-substituted indole in a 93% isolated yield (Table 10, entry 1). Interestingly, the cross-coupling reaction was achieved by means of a catalytic amount of the Rh catalyst [165]. The Liebeskind−Srogl cross-coupling reaction was used for the synthesis of substituted BODIPY involving Biellmann BODIPY (Table 10, entry 2) [166]. The reaction was catalyzed by Pd2(dba)3 in the presence of a catalytic amount of trifurylphosphine and a stoichiometric amount of CuTC, thereby leading to variously substituted BODIPYs. The reaction can also be performed under microwave heating, and the fluorescent efficiency was tested on prepared substances. Table 10. Palladium-and rhodium-catalyzed arylation of indolylboronic acids.

Entry
LG A similar type of cross-coupling reaction was described by Pentelute and Buchwald (Scheme 38) [167]. In their report, they applied an umpolung strategy for the bioconjugation of the selenocysteine in unprotected peptides. The reaction was conducted by mixing boronic acids in the presence of copper (II) sulfate and the phenanthroline ligand. The incorporation of diverse indolylboronic acids S38-2 and S38-3 was achieved in good yields. The reaction was also extended to include α-bromo-α,α-difluoroacetates. The presence of two equivalents of 1,4-dinitrobenzene suppressed the reaction, while the two equivalents of TEMPO resulted in the isolation of the corresponding adducts. These experiments indicated a SET mechanism for the carbonylation. Different from Skrydstrup's protocol, Szostak [161] applied an alternative method for the carbonylation of boronic acids. His protocol is based on the cross-coupling reaction of the activated C−N amide bond. Thus, the cyclic amide T9-3 was found to be the best substrate, affording various ketones along with the indole in good isolated yields (Table 9, entry 2). The methodology of the CO carbonylation of indolylboronic acid pinacol boronic esters was extended to cover methoxycarbonylation (Table 9, entry 3) [162]. Weinreb amides are useful synthons for Weinreb ketone synthesis [163]. Therefore, it is unsurprising that the simple and high-yielding synthesis of Weinreb amides has been pursued ( Table 9, entry 4) [164]. Different boronic acids and organotrifluoroborates were mixed with N-methoxy-N-methylcarbamoyl chloride in the presence of PdCl2(PPh3)2 and potassium phosphate in ethanol, thereby affording, for instance, 1H protected and unprotected indole-based amides in good isolated yields.
Among the other aromatic and heteroaromatic boronates, 1-methyl-5-nepBindole smoothly reacted with arylcarbamate in the rhodium-catalyzed reaction so as to yield 5-substituted indole in a 93% isolated yield (Table 10, entry 1). Interestingly, the cross-coupling reaction was achieved by means of a catalytic amount of the Rh catalyst [165]. The Liebeskind−Srogl cross-coupling reaction was used for the synthesis of substituted BODIPY involving Biellmann BODIPY (Table 10, entry 2) [166]. The reaction was catalyzed by Pd2(dba)3 in the presence of a catalytic amount of trifurylphosphine and a stoichiometric amount of CuTC, thereby leading to variously substituted BODIPYs. The reaction can also be performed under microwave heating, and the fluorescent efficiency was tested on prepared substances. Table 10. Palladium-and rhodium-catalyzed arylation of indolylboronic acids.

Entry
LG A similar type of cross-coupling reaction was described by Pentelute and Buchwald (Scheme 38) [167]. In their report, they applied an umpolung strategy for the bioconjugation of the selenocysteine in unprotected peptides. The reaction was conducted by mixing boronic acids in the presence of copper (II) sulfate and the phenanthroline ligand. The incorporation of diverse indolylboronic acids S38-2 and S38-3 was achieved in good yields.
A similar type of cross-coupling reaction was described by Pentelute and Buchwald (Scheme 38) [167]. In their report, they applied an umpolung strategy for the bioconjugation of the selenocysteine in unprotected peptides. The reaction was conducted by mixing boronic acids in the presence of copper (II) sulfate and the phenanthroline ligand. The incorporation of diverse indolylboronic acids S38-2 and S38-3 was achieved in good yields. Arvidsson et al. [168]. developed a general methodology for the synthesis of substituted β-aryl ethenesulfonyl fluorides by means of oxidative Heck coupling. The optimized ligandless reaction conditions involved copper(II) acetate as the oxidant and THF as the solvent. The reaction was applied to the synthesis of 5-substituted indole and the following reaction with methylamine resulted in β-sultam S39-3 in an 85% isolated yield (Scheme 39). Arvidsson et al. [168]. developed a general methodology for the synthesis of substituted β-aryl ethenesulfonyl fluorides by means of oxidative Heck coupling. The optimized ligandless reaction conditions involved copper(II) acetate as the oxidant and THF as the solvent. The reaction was applied to the synthesis of 5-substituted indole and the following reaction with methylamine resulted in β-sultam S39-3 in an 85% isolated yield (Scheme 39). Arvidsson et al. [168]. developed a general methodology for the synthesis of substituted β-aryl ethenesulfonyl fluorides by means of oxidative Heck coupling. The optimized ligandless reaction conditions involved copper(II) acetate as the oxidant and THF as the solvent. The reaction was applied to the synthesis of 5-substituted indole and the following reaction with methylamine resulted in β-sultam S39-3 in an 85% isolated yield (Scheme 39). The conditions necessary for a transition-metal-free reaction between electron-rich aryl/hetarylboronic acids or trifluoroborates and unprotected vicinal diols have also been published (Scheme 40) [169]. Two different reaction conditions were developed in order to gain opposite stereochemical outcomes. Trifluoroacetic anhydride preferentially formed the substituted indole S40-2 in a 76% isolated yield as a single diastereomer upon reaction with boronic acid. Arvidsson et al. [168]. developed a general methodology for the synthesis of substituted β-aryl ethenesulfonyl fluorides by means of oxidative Heck coupling. The optimized ligandless reaction conditions involved copper(II) acetate as the oxidant and THF as the solvent. The reaction was applied to the synthesis of 5-substituted indole and the following reaction with methylamine resulted in β-sultam S39-3 in an 85% isolated yield (Scheme 39). Alternatively, Bu 4 NHSO 4 along with organotrifluoroborate gave the pure diastereomer S40-3 in an 80% yield. Based on the experimental evidence, it is expected that the reaction proceeds according to two different types of alcohol S40-1 activations. In the case of the boronic acids, the formation of a cyclic ester is preferred, leading to the product S40-4, which in turn forms the product S40-2. Meanwhile, Bu 4 NHSO 4 facilitates the formation of carbocation S40-5, resulting in the formation of the opposite diastereomer.
A simple approach to the synthesis of substituted indoles was developed by Aggarwal (Scheme 41) [170]. The protocol starts with easily available pinacol boronic esters, which are combined with vinylmagnesium chlorides or vinyllithiums. The formed ate complexes are transformed into the final product via the use of iodine and sodium methoxide. The synthesis of the substituted indoles S41-1 and S41-3 in acceptable yields is achieved. The conditions necessary for a transition-metal-free reaction between electron-rich aryl/hetarylboronic acids or trifluoroborates and unprotected vicinal diols have also been published (Scheme 40) [169]. Two different reaction conditions were developed in order to gain opposite stereochemical outcomes. Trifluoroacetic anhydride preferentially formed the substituted indole S40-2 in a 76% isolated yield as a single diastereomer upon reaction with boronic acid.
Alternatively, Bu4NHSO4 along with organotrifluoroborate gave the pure diastereomer S40-3 in an 80% yield. Based on the experimental evidence, it is expected that the reaction proceeds according to two different types of alcohol S40-1 activations. In the case of the boronic acids, the formation of a cyclic ester is preferred, leading to the product S40-4, which in turn forms the product S40-2. Meanwhile, Bu4NHSO4 facilitates the formation of carbocation S40-5, resulting in the formation of the opposite diastereomer.
A simple approach to the synthesis of substituted indoles was developed by Aggarwal (Scheme 41) [170]. The protocol starts with easily available pinacol boronic esters, which are combined with vinylmagnesium chlorides or vinyllithiums. The formed ate complexes are transformed into the final product via the use of iodine and sodium methoxide. The synthesis of the substituted indoles S41-1 and S41-3 in acceptable yields is achieved. In 2018, Niu et al. [171] developed a simple protocol for the transition-metal-free amination of boronic acids. The authors proposed that the initially formed ate complex S42-3 requires hydroxyl group activation so as to accomplish the amination (Scheme 42). Indeed, the activation was achieved with trichloroacetonitrile in t butanol. Thus, the synthesis of 5-(N-benzylamino)-1H-indole was completed in a 90% isolated yield. Aside from the other aromatic and heteroaromatic substrates, the same methodology was used for the amination of a tripeptide, a steroidal moiety and a protected carbohydrate showing excellent functional group tolerance. In addition to the aforementioned transition-metal-free amination of boronic acids, the copper(II)-acetate-catalyzed oxidative coupling of 1H-pyrazolo [3-b]pyridine-amine and 2-aminobenzimidazoles has been described in the literature [172].

Cyclization Reactions of Indolylboronic Acid Derivatives
Several cyclizations of diverse substrates have been developed covering both indolylboronic acids and transition-metal catalysis. In 2019, the Darses research group developed a methodology for the asymmetric cyclization of (allyl)propargylether catalyzed by a rhodium catalyst (Scheme 43) [173]. The reaction is performed in methanol at 60 °C, and the reaction outcome depends on the structure of the ligand. When conducted in the presence of 1-Np-MSBod (S43-3), the exclusive Scheme 41. The Zweifel coupling of 5-indolylboronic pinacol boronic acid esters.
In 2018, Niu et al. [171] developed a simple protocol for the transition-metal-free amination of boronic acids. The authors proposed that the initially formed ate complex S42-3 requires hydroxyl group activation so as to accomplish the amination (Scheme 42). Indeed, the activation was achieved with trichloroacetonitrile in t butanol. Thus, the synthesis of 5-(N-benzylamino)-1H-indole was completed in a 90% isolated yield. Aside from the other aromatic and heteroaromatic substrates, the same methodology was used for the amination of a tripeptide, a steroidal moiety and a protected carbohydrate showing excellent functional group tolerance. In addition to the aforementioned transition-metal-free amination of boronic acids, the copper(II)-acetate-catalyzed oxidative coupling of 1H-pyrazolo [3-b]pyridine-amine and 2-aminobenzimidazoles has been described in the literature [172]. The conditions necessary for a transition-metal-free reaction between electron-rich aryl/hetarylboronic acids or trifluoroborates and unprotected vicinal diols have also been published (Scheme 40) [169]. Two different reaction conditions were developed in order to gain opposite stereochemical outcomes. Trifluoroacetic anhydride preferentially formed the substituted indole S40-2 in a 76% isolated yield as a single diastereomer upon reaction with boronic acid.
Alternatively, Bu4NHSO4 along with organotrifluoroborate gave the pure diastereomer S40-3 in an 80% yield. Based on the experimental evidence, it is expected that the reaction proceeds according to two different types of alcohol S40-1 activations. In the case of the boronic acids, the formation of a cyclic ester is preferred, leading to the product S40-4, which in turn forms the product S40-2. Meanwhile, Bu4NHSO4 facilitates the formation of carbocation S40-5, resulting in the formation of the opposite diastereomer.
A simple approach to the synthesis of substituted indoles was developed by Aggarwal (Scheme 41) [170]. The protocol starts with easily available pinacol boronic esters, which are combined with vinylmagnesium chlorides or vinyllithiums. The formed ate complexes are transformed into the final product via the use of iodine and sodium methoxide. The synthesis of the substituted indoles S41-1 and S41-3 in acceptable yields is achieved. In 2018, Niu et al. [171] developed a simple protocol for the transition-metal-free amination of boronic acids. The authors proposed that the initially formed ate complex S42-3 requires hydroxyl group activation so as to accomplish the amination (Scheme 42). Indeed, the activation was achieved with trichloroacetonitrile in t butanol. Thus, the synthesis of 5-(N-benzylamino)-1H-indole was completed in a 90% isolated yield. Aside from the other aromatic and heteroaromatic substrates, the same methodology was used for the amination of a tripeptide, a steroidal moiety and a protected carbohydrate showing excellent functional group tolerance. In addition to the aforementioned transition-metal-free amination of boronic acids, the copper(II)-acetate-catalyzed oxidative coupling of 1H-pyrazolo [3-b]pyridine-amine and 2-aminobenzimidazoles has been described in the literature [172].

Cyclization Reactions of Indolylboronic Acid Derivatives
Several cyclizations of diverse substrates have been developed covering both indolylboronic acids and transition-metal catalysis. In 2019, the Darses research group developed a methodology for the asymmetric cyclization of (allyl)propargylether catalyzed by a rhodium catalyst (Scheme 43) [173]. The reaction is performed in methanol at 60 °C, and the reaction outcome depends on the structure of the ligand. When conducted in the presence of 1-Np-MSBod (S43-3), the exclusive Scheme 42. Transition-metal-free amination of indolylboronic acids.

Cyclization Reactions of Indolylboronic Acid Derivatives
Several cyclizations of diverse substrates have been developed covering both indolylboronic acids and transition-metal catalysis. In 2019, the Darses research group developed a methodology for the asymmetric cyclization of (allyl)propargylether catalyzed by a rhodium catalyst (Scheme 43) [173]. The reaction is performed in methanol at 60 • C, and the reaction outcome depends on the structure of the ligand. When conducted in the presence of 1-Np-MSBod (S43-3), the exclusive formation of 3,4-disubstitutedtetrahydrofurans was observed in 47−60% isolated yields. The indolyl derivative S43-2 was isolated in a 54% yield and 95% ee. As demonstrated by Bower, palladium-catalyzed cyclizations of oxime esters or N-(pentafluorobenzoyloxy)carbamates have been successfully used to synthesize trisubstituted 1pyrrolines [174] (Scheme 44a) and pyrrolidine [175] (Scheme 44b). Both strategies take advantage of the N-pentafluorobenzoyloxy group, which activates the N−O bond for the oxidative addition of palladium, although it requires two different ligands. The catalyzed alkene 1,2-carboamination reaction requires the tris[3,5-bis(trifluoromethyl)phenyl]phosphine ligand (Scheme 44a), while the aza-Heck cyclization relies on an adamantyl-type ligand (Scheme 44b) to give good isolated yields of the products S44-1−S44-3. Analogously to Bower's work, Selander et al. developed the 1,2-aminoarylation of oxime estertethered alkenes catalyzed by a nickel catalyst along with the phenanthroline ligand, thereby affording 2,5-disubstituted-1-pyrrolines (Scheme 45) [176]. The cyclization reaction showed a good substrate scope with isolated yields ranging from 38−82%. The indolylboronic acid gave the product S45-2 in a 62% isolated yield. The authors proposed the cleavage of the N−O bond by means of SET, with the subsequent cyclization proceeding via a radical addition to the double bond. This assumption was confirmed by trapping the radical intermediate with TEMPO. The developed conditions were applied to the synthesis of ABI-274, a potent tubulin inhibitor effective in relation to multidrug-resistant cancer cells. As demonstrated by Bower, palladium-catalyzed cyclizations of oxime esters or N-(pentafluorobenzoyloxy)carbamates have been successfully used to synthesize trisubstituted 1-pyrrolines [174] (Scheme 44a) and pyrrolidine [175] (Scheme 44b). Both strategies take advantage of the N-pentafluorobenzoyloxy group, which activates the N−O bond for the oxidative addition of palladium, although it requires two different ligands. The catalyzed alkene 1,2-carboamination reaction requires the tris[3,5-bis(trifluoromethyl)phenyl]phosphine ligand (Scheme 44a), while the aza-Heck cyclization relies on an adamantyl-type ligand (Scheme 44b) to give good isolated yields of the products S44-1−S44-3. As demonstrated by Bower, palladium-catalyzed cyclizations of oxime esters or N-(pentafluorobenzoyloxy)carbamates have been successfully used to synthesize trisubstituted 1pyrrolines [174] (Scheme 44a) and pyrrolidine [175] (Scheme 44b). Both strategies take advantage of the N-pentafluorobenzoyloxy group, which activates the N−O bond for the oxidative addition of palladium, although it requires two different ligands. The catalyzed alkene 1,2-carboamination reaction requires the tris[3,5-bis(trifluoromethyl)phenyl]phosphine ligand (Scheme 44a), while the aza-Heck cyclization relies on an adamantyl-type ligand (Scheme 44b) to give good isolated yields of the products S44-1−S44-3. Analogously to Bower's work, Selander et al. developed the 1,2-aminoarylation of oxime ester-tethered alkenes catalyzed by a nickel catalyst along with the phenanthroline ligand, thereby affording 2,5-disubstituted-1-pyrrolines (Scheme 45) [176]. The cyclization reaction showed a good substrate scope with isolated yields ranging from 38−82%. The indolylboronic acid gave the product S45-2 in a 62% isolated yield. The authors proposed the cleavage of the N−O bond by means of SET, with the subsequent cyclization proceeding via a radical addition to the double bond. This assumption was confirmed by trapping the radical intermediate with TEMPO. The developed conditions were applied to the synthesis of ABI-274, a potent tubulin inhibitor effective in relation to multidrug-resistant cancer cells. There exists an inverse approach to substituted indoles based on a cyclobutanone ring expansion (Scheme 46) [177]. In this case, the substituted cyclobutanone S46-1 was treated with 5-indolylboronic acid in the presence of a palladium precatalyst and the tricyclohexylphosphine ligand. The corresponding 5-substituted indole was formed in a high isolated yield and an excellent Z:E ratio. There exists an inverse approach to substituted indoles based on a cyclobutanone ring expansion (Scheme 46) [177]. In this case, the substituted cyclobutanone S46-1 was treated with 5-indolylboronic acid in the presence of a palladium precatalyst and the tricyclohexylphosphine ligand. The corresponding 5-substituted indole was formed in a high isolated yield and an excellent Z:E ratio. The methodology also tolerates other substituted phenyl, styrenyl, and heteroarylboronic acids. Based on the deuterium experiments, the formation of the palladium complex S46-3 by means of 1,2-addition is expected as a key reaction intermediate. The subsequent β-carbon elimination via C sp3 −C sp2 bond cleavage and protolysis is responsible for the formation of the final product. There exists an inverse approach to substituted indoles based on a cyclobutanone ring expansion (Scheme 46) [177]. In this case, the substituted cyclobutanone S46-1 was treated with 5-indolylboronic acid in the presence of a palladium precatalyst and the tricyclohexylphosphine ligand. The corresponding 5-substituted indole was formed in a high isolated yield and an excellent Z:E ratio. The methodology also tolerates other substituted phenyl, styrenyl, and heteroarylboronic acids. Based on the deuterium experiments, the formation of the palladium complex S46-3 by means of 1,2addition is expected as a key reaction intermediate. The subsequent β-carbon elimination via Csp3−Csp2 bond cleavage and protolysis is responsible for the formation of the final product. Scheme 46. Palladium-catalyzed ring expansion of cyclobutanone en route to Z-disubstituted alkenes.

Multicomponent Reactions of Indolylboronic Acid Derivatives
Multicomponent reactions can significantly facilitate the preparation of complex structures of organic molecules due to lowering the required number of reaction steps. The use of boronic acids is widespread in such reactions, as the creation of the quaternary borate salt known as the "ate" complex enables the transfer of the boron substituent onto, for example, an imine -as is the case in the Petasis-Borono-Mannich multicomponent reaction. The classical metal-free Petasis reaction is the topic of the work published by Manolikakes [178] (Scheme 47). He used sulfonamides as the amine component in a three-component reaction with a glyoxylic and a boronic acid. This way, the medicinally important sulfonamide group was introduced into various α-substituted glycines, although the yield of the indole-based substrate S47-2 was only 48%. The sulfonamide group in the prepared compounds could serve as a protecting group and a possible site of alteration for modulating the biological properties and increasing the metabolic stability of the compound.

Multicomponent Reactions of Indolylboronic Acid Derivatives
Multicomponent reactions can significantly facilitate the preparation of complex structures of organic molecules due to lowering the required number of reaction steps. The use of boronic acids is widespread in such reactions, as the creation of the quaternary borate salt known as the "ate" complex enables the transfer of the boron substituent onto, for example, an imine -as is the case in the Petasis-Borono-Mannich multicomponent reaction. The classical metal-free Petasis reaction is the topic of the work published by Manolikakes [178] (Scheme 47). He used sulfonamides as the amine component in a three-component reaction with a glyoxylic and a boronic acid. This way, the medicinally important sulfonamide group was introduced into various α-substituted glycines, although the yield of the indole-based substrate S47-2 was only 48%. The sulfonamide group in the prepared compounds could serve as a protecting group and a possible site of alteration for modulating the biological properties and increasing the metabolic stability of the compound. There exists an inverse approach to substituted indoles based on a cyclobutanone ring expansion (Scheme 46) [177]. In this case, the substituted cyclobutanone S46-1 was treated with 5-indolylboronic acid in the presence of a palladium precatalyst and the tricyclohexylphosphine ligand. The corresponding 5-substituted indole was formed in a high isolated yield and an excellent Z:E ratio. The methodology also tolerates other substituted phenyl, styrenyl, and heteroarylboronic acids. Based on the deuterium experiments, the formation of the palladium complex S46-3 by means of 1,2addition is expected as a key reaction intermediate. The subsequent β-carbon elimination via Csp3−Csp2 bond cleavage and protolysis is responsible for the formation of the final product. Scheme 46. Palladium-catalyzed ring expansion of cyclobutanone en route to Z-disubstituted alkenes.

Multicomponent Reactions of Indolylboronic Acid Derivatives
Multicomponent reactions can significantly facilitate the preparation of complex structures of organic molecules due to lowering the required number of reaction steps. The use of boronic acids is widespread in such reactions, as the creation of the quaternary borate salt known as the "ate" complex enables the transfer of the boron substituent onto, for example, an imine -as is the case in the Petasis-Borono-Mannich multicomponent reaction. The classical metal-free Petasis reaction is the topic of the work published by Manolikakes [178] (Scheme 47). He used sulfonamides as the amine component in a three-component reaction with a glyoxylic and a boronic acid. This way, the medicinally important sulfonamide group was introduced into various α-substituted glycines, although the yield of the indole-based substrate S47-2 was only 48%. The sulfonamide group in the prepared compounds could serve as a protecting group and a possible site of alteration for modulating the biological properties and increasing the metabolic stability of the compound. A more general methodology for the synthesis of sulfones, sulfonamides [179], and sulfonate esters [180] was developed by Willis et al. (Scheme 48). In their reports, the synthesis of the target compounds is realized via the conversion of aryl/hetarylboronic acid, for example, indolylboronic acid S48-1, into the sulfonates S48-2. The reaction is carried out in the presence of the sulfur dioxide surrogate 1,4-diazabicyclo[2.2.2]octane bis(sulfur dioxide) (DABSO) and a Pd-catalyst. The direct conversion of the sulfinate S48-2 into the sulfones S48-4 is performed under transition-metal-free conditions by means of tert-butyl α-bromoacetate, while the conversion into the sulfonate esters S48-3 is mediated by copper(II) bromide. A similar direct copper-catalyzed sulfonamides synthesis was reported by the same authors [181]. Primary amines and sterically demanding secondary amines are not tolerated in this reaction. The authors also incorporated several pharmaceutically important amines into the structures of the indole-5-sulfonamides so as to display the potential value of this method in relation to drug design and discovery.
compounds is realized via the conversion of aryl/hetarylboronic acid, for example, indolylboronic acid S48-1, into the sulfonates S48-2. The reaction is carried out in the presence of the sulfur dioxide surrogate 1,4-diazabicyclo[2.2.2]octane bis(sulfur dioxide) (DABSO) and a Pd-catalyst. The direct conversion of the sulfinate S48-2 into the sulfones S48-4 is performed under transition-metal-free conditions by means of tert-butyl α-bromoacetate, while the conversion into the sulfonate esters S48-3 is mediated by copper(II) bromide. A similar direct copper-catalyzed sulfonamides synthesis was reported by the same authors [181]. Primary amines and sterically demanding secondary amines are not tolerated in this reaction. The authors also incorporated several pharmaceutically important amines into the structures of the indole-5-sulfonamides so as to display the potential value of this method in relation to drug design and discovery. Scheme 48. The synthesis of sulfones and sulfonate esters by means of DABSO.
In 2012, Nielsen [182] described a three-component coupling reaction involving α-hydroxy aldehydes and boronic acids (Scheme 49) in a mixture of solvents, namely MeOH:hexafluoroisopropanol (HFIP). The products formed in the Petasis reaction varied from 26-95% in terms of the yield. The hydrazido alcohols S49-4 obtained using this protocol were subjected to a cyclization reaction in relation to the corresponding oxadiazolones and oxazolidinones, that is the target compounds of the work due to their possible antibacterial activity. Later on, the same authors [183] reported a four-component Petasis-type reaction that was used for the synthesis of dioxadiazaborocines.

Scheme 49. The Petasis reaction of indolylboronic acids.
A Petasis-type reaction was utilized by Onomura [184] when designing a versatile procedure for the diasterocontrolled synthesis of cis-2,3-disubstitutedpiperidine S50-3 (Scheme 50). The Lewis-acidcatalyzed reaction of indolyl boronic acid S50-1 with cyclic N,O-acetal S50-2 provided the cyclic carbamate S50-3. In 2012, Nielsen [182] described a three-component coupling reaction involving α-hydroxy aldehydes and boronic acids (Scheme 49) in a mixture of solvents, namely MeOH:hexafluoroisopropanol (HFIP). The products formed in the Petasis reaction varied from 26-95% in terms of the yield. The hydrazido alcohols S49-4 obtained using this protocol were subjected to a cyclization reaction in relation to the corresponding oxadiazolones and oxazolidinones, that is the target compounds of the work due to their possible antibacterial activity. Later on, the same authors [183] reported a four-component Petasis-type reaction that was used for the synthesis of dioxadiazaborocines. esters [180] was developed by Willis et al. (Scheme 48). In their reports, the synthesis of the target compounds is realized via the conversion of aryl/hetarylboronic acid, for example, indolylboronic acid S48-1, into the sulfonates S48-2. The reaction is carried out in the presence of the sulfur dioxide surrogate 1,4-diazabicyclo[2.2.2]octane bis(sulfur dioxide) (DABSO) and a Pd-catalyst. The direct conversion of the sulfinate S48-2 into the sulfones S48-4 is performed under transition-metal-free conditions by means of tert-butyl α-bromoacetate, while the conversion into the sulfonate esters S48-3 is mediated by copper(II) bromide. A similar direct copper-catalyzed sulfonamides synthesis was reported by the same authors [181]. Primary amines and sterically demanding secondary amines are not tolerated in this reaction. The authors also incorporated several pharmaceutically important amines into the structures of the indole-5-sulfonamides so as to display the potential value of this method in relation to drug design and discovery. Scheme 48. The synthesis of sulfones and sulfonate esters by means of DABSO.
In 2012, Nielsen [182] described a three-component coupling reaction involving α-hydroxy aldehydes and boronic acids (Scheme 49) in a mixture of solvents, namely MeOH:hexafluoroisopropanol (HFIP). The products formed in the Petasis reaction varied from 26-95% in terms of the yield. The hydrazido alcohols S49-4 obtained using this protocol were subjected to a cyclization reaction in relation to the corresponding oxadiazolones and oxazolidinones, that is the target compounds of the work due to their possible antibacterial activity. Later on, the same authors [183] reported a four-component Petasis-type reaction that was used for the synthesis of dioxadiazaborocines.
In 2017, Ready [185] reported on the three-component palladium-catalyzed coupling of indoles with boronic esters and allylic acetates. The multicomponent reaction generates ate complexes S51-2 via the reaction of indolylboronic acid pinacol esters S51-1 (Scheme 51). Then, the formed ate complexes S51-2 are rearranged into 2,3-dihydroindoles S51-3. Overall, the isolated yields of the disubstituted indoles S51-4a−S51-4d are high, thereby demonstrating high diastereomeric and enantiomeric ratios. The other multicomponent reactions include indolylboronic acids are summarized in Figure 2. The palladium-catalyzed multicomponent reaction [186] of indole boronic acids includes the 1,1diarylation of terminal alkenes by means of boronic acids and aryldiazonium salts. This method is highly enantioselective due to the utilization of a chiral anion phase-transfer catalyst, and the indolebased product F3-1 was obtained in a 29% isolated yield and an excellent enantiomeric ratio. Another possibility with regard to 1,2-diarylation, as published by Xiao [187], employs nitrogencentered radicals created from cyclobutanone oxime derivatives. The reaction is carried out in the presence of a copper(I) catalyst and with 4,4′-di-tert-butyl-2,2′-dipyridyl (dtbbpy) serving as the ligand. This multicomponent reaction is able to accommodate the 3-indolyl moiety, affording the product F3-2 in an excellent isolated yield. A related procedure concerning the 1,2-addition of boronic esters and aryl triflate to vinyl magnesium chloride was published by Morken [188]. The stereoselective preparation of trisubstituted alkenes with perfluoroalkyl chains was also described Scheme 51. The procedure for the preparation of C2-and C3-substituted indoles.
The other multicomponent reactions include indolylboronic acids are summarized in Figure 2. The palladium-catalyzed multicomponent reaction [186] of indole boronic acids includes the 1,1-diarylation of terminal alkenes by means of boronic acids and aryldiazonium salts. This method is highly enantioselective due to the utilization of a chiral anion phase-transfer catalyst, and the indole-based product F3-1 was obtained in a 29% isolated yield and an excellent enantiomeric ratio.
In 2017, Ready [185] reported on the three-component palladium-catalyzed coupling of indoles with boronic esters and allylic acetates. The multicomponent reaction generates ate complexes S51-2 via the reaction of indolylboronic acid pinacol esters S51-1 (Scheme 51). Then, the formed ate complexes S51-2 are rearranged into 2,3-dihydroindoles S51-3. Overall, the isolated yields of the disubstituted indoles S51-4a−S51-4d are high, thereby demonstrating high diastereomeric and enantiomeric ratios. The other multicomponent reactions include indolylboronic acids are summarized in Figure 2. The palladium-catalyzed multicomponent reaction [186] of indole boronic acids includes the 1,1diarylation of terminal alkenes by means of boronic acids and aryldiazonium salts. This method is highly enantioselective due to the utilization of a chiral anion phase-transfer catalyst, and the indolebased product F3-1 was obtained in a 29% isolated yield and an excellent enantiomeric ratio. Another possibility with regard to 1,2-diarylation, as published by Xiao [187], employs nitrogencentered radicals created from cyclobutanone oxime derivatives. The reaction is carried out in the presence of a copper(I) catalyst and with 4,4′-di-tert-butyl-2,2′-dipyridyl (dtbbpy) serving as the ligand. This multicomponent reaction is able to accommodate the 3-indolyl moiety, affording the product F3-2 in an excellent isolated yield. A related procedure concerning the 1,2-addition of boronic esters and aryl triflate to vinyl magnesium chloride was published by Morken [188]. The stereoselective preparation of trisubstituted alkenes with perfluoroalkyl chains was also described Another possibility with regard to 1,2-diarylation, as published by Xiao [187], employs nitrogen-centered radicals created from cyclobutanone oxime derivatives. The reaction is carried out in the presence of a copper(I) catalyst and with 4,4 -di-tert-butyl-2,2 -dipyridyl (dtbbpy) serving as the ligand. This multicomponent reaction is able to accommodate the 3-indolyl moiety, affording the product F3-2 in an excellent isolated yield. A related procedure concerning the 1,2-addition of boronic esters and aryl triflate to vinyl magnesium chloride was published by Morken [188]. The stereoselective preparation of trisubstituted alkenes with perfluoroalkyl chains was also described [189]. This four-component protocol makes use of carbon monoxide, terminal alkynes, perfluoralkyliodide, and arylboronic acids. A trisubstituted alkene F3-3 was prepared in a moderate yield, while the overall isolated yields ranged from 43−90%. The double-bond configuration was determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael   Entry  T11-1  Conditions  T11-3 1 determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael 2 determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael 3 yield, while the overall isolated yields ranged from 43−90%. The double-bond configuration was determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael ArB(OH) 2 (2 equiv.), Pd(OAc) 2 (10 mol %), NaF (2 equiv.), TFT, 100 • C, 12 h yield, while the overall isolated yields ranged from 43−90%. The double-bond configuration was determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael 4 yield, while the overall isolated yields ranged from 43−90%. The double-bond configuration was determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael ArB(OH) 2 (1.5 equiv.), Cu(OTf) 2 (10 mol %), toluene, 70 • C, 18 h yield, while the overall isolated yields ranged from 43−90%. The double-bond configuration was determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael 5 yield, while the overall isolated yields ranged from 43−90%. The double-bond configuration was determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael ArB(OH) 2 (2.5 equiv.), Ni(cod) 2 (10 mol %), TrixiePhos (10 mol %), THF (0.05 M), rt, 24 h yield, while the overall isolated yields ranged from 43−90%. The double-bond configuration was determined by the through space 13 C− 19 F coupling.

Addition of Indolylboronic Acids or Boronates to Multiple Bonds
The 1,4-addition of aryl-or hetarylboronic acids can be catalyzed by transition metals. Both published procedures (Table 11, entries 1 and 2) are catalyzed by a rhodium catalyst under identical reaction conditions. Table 11. Transition-metal-catalyzed reactions of indolylboronic acids with alkenes. Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael Viaud-Massuard [190] developed the asymmetric addition on 7-azaindoles as an example of an exocyclic benzylidene lactamyl Michael acceptor. The reaction was performed in the presence of the (R,R)-Phbod ligand, which ensured the 94% ee of the indole-based product (Table 11, entry 1). A ligandless condition was described by Howell et al. (Table 11, entry 2) [191]. They studied the Michael addition of boronic acids onto α-methylene-β-lactones under similar reaction conditions [190]. Generally speaking, the reaction provided a mixture of diastereomers, including β-propiolactone substituted by a 1-methyl-5-indolyl substituent. The synthesis of nocardiolactone was also described in this paper. The palladium-catalyzed γ-selective hydroarylation of a β,γ-unsaturated secondary amide was reported by Engle (Table 11, entry 3) [192]. In his report, palladium acetate was used to catalyze a regioselective hydroarylation with arylboronic acids, although the substrate scope was limited to amides bearing the N-8-aminoquinoline (AQ) substituent. Based on mechanistic studies, it was proposed that palladium coordinates to the AQ moiety, and further, that transmetalation represents the rate-controlling step. In a different paper, Scarso et al. studied the course of the conjugated addition of boronic acids to vinylidenebisphosphonate (VBP) [193]. This reaction represents a valuable contribution to the synthesis of gem-bisphosphonates. The reaction takes advantage of a simple copper(II) catalyst and tolerates diverse boronic acids, including 4-indolylboronic acids, which afforded the expected product in an 83% isolated yield (Table 11, entry 4). The same catalytic system is able to facilitate the Friedel-Crafts reaction between VBP and indoles, thereby expanding the scope for the preparation of gem-bisphosphonates. The regio-and stereoselective hydroarylation of propargylic carbamates by means of aryl-heteroarylboronic acids catalyzed by a Ni(cod) 2 catalyst was reported by Jarvo (Table 11, entry 5) [194]. The rac-2-(di-tert-butylphosphino)-1,1 -binaphthyl (TrixiePhos) was determined to be the ligand of choice in terms of maintaining the quantitative conversion of the starting alkynes, along with excellent regio-and stereoselectivity. The isolated yields of the trisubstituted alkenes were good, which is illustrated by the provided example (Table 11, entry 5). The methodology was later extended to include the formal synthesis of tamoxifen.

Entry
Recently, Hyland described a different kind of (Z)-selective palladium-catalyzed addition of aryl boronic acids to vinylaziridines (Scheme 52) [195]. This reaction makes use of palladium acetate as a catalyst in combination with the phenanthroline ligand and AgSbF 6 . Although the reaction is said to be (Z)-selective, however the reported Z:E ratio varies between 1.6:1 and 4.5:1. This reactivity is demonstrated by the reaction of indolylboronic acid S52-1, which gave a 38% yield of the substituted indole S52-2 as a mixture of Z:E isomers in a ratio of 1.8:1.
amide was reported by Engle (Table 11, entry 3) [192]. In his report, palladium acetate was used to catalyze a regioselective hydroarylation with arylboronic acids, although the substrate scope was limited to amides bearing the N-8-aminoquinoline (AQ) substituent. Based on mechanistic studies, it was proposed that palladium coordinates to the AQ moiety, and further, that transmetalation represents the rate-controlling step. In a different paper, Scarso et al. studied the course of the conjugated addition of boronic acids to vinylidenebisphosphonate (VBP) [193]. This reaction represents a valuable contribution to the synthesis of gem-bisphosphonates. The reaction takes advantage of a simple copper(II) catalyst and tolerates diverse boronic acids, including 4indolylboronic acids, which afforded the expected product in an 83% isolated yield (Table 11, entry 4). The same catalytic system is able to facilitate the Friedel-Crafts reaction between VBP and indoles, thereby expanding the scope for the preparation of gem-bisphosphonates. The regio-and stereoselective hydroarylation of propargylic carbamates by means of aryl-heteroarylboronic acids catalyzed by a Ni(cod)2 catalyst was reported by Jarvo (Table 11, entry 5) [194]. The rac-2-(di-tertbutylphosphino)-1,1′-binaphthyl (TrixiePhos) was determined to be the ligand of choice in terms of maintaining the quantitative conversion of the starting alkynes, along with excellent regio-and stereoselectivity. The isolated yields of the trisubstituted alkenes were good, which is illustrated by the provided example (Table 11, entry 5). The methodology was later extended to include the formal synthesis of tamoxifen.
Recently, Hyland described a different kind of (Z)-selective palladium-catalyzed addition of aryl boronic acids to vinylaziridines (Scheme 52) [195]. This reaction makes use of palladium acetate as a catalyst in combination with the phenanthroline ligand and AgSbF6. Although the reaction is said to be (Z)-selective, however the reported Z:E ratio varies between 1.6:1 and 4.5:1. This reactivity is demonstrated by the reaction of indolylboronic acid S52-1, which gave a 38% yield of the substituted indole S52-2 as a mixture of Z:E isomers in a ratio of 1.8:1. Organocatalytic additions are considered to be more environmentally acceptable than transitionmetal-catalyzed reactions. However, practical examples concerning a series of indolylboronic acids can only be found in three reports. In 2012, Schaus described the enantioselective addition of diethyl boronates to o-quinone methides S53-1 (Scheme 53) [196]. The reaction is catalyzed by 10 mol % of the BINOL ligand in toluene at room temperature. Aromatic and heteroaromatic boronates provide a high yield (46−85%) with regard to aromatic phenols, in addition to an excellent enantiomeric ratio of ≥90:10. In the case of indolylboronate S53-2, the isolated yield of the product S53-3 was only 46% and the enantiomeric ratio was 96:4. Moreover, the published protocol was applied to the short synthesis of (S)-4-methoxydalbergione. Organocatalytic additions are considered to be more environmentally acceptable than transition-metal-catalyzed reactions. However, practical examples concerning a series of indolylboronic acids can only be found in three reports. In 2012, Schaus described the enantioselective addition of diethyl boronates to o-quinone methides S53-1 (Scheme 53) [196]. The reaction is catalyzed by 10 mol % of the BINOL ligand in toluene at room temperature. Aromatic and heteroaromatic boronates provide a high yield (46−85%) with regard to aromatic phenols, in addition to an excellent enantiomeric ratio of ≥90:10. In the case of indolylboronate S53-2, the isolated yield of the product S53-3 was only 46% and the enantiomeric ratio was 96:4. Moreover, the published protocol was applied to the short synthesis of (S)-4-methoxydalbergione. A combination of the organocatalytic Michael addition of boronic acids and the diastereoselective intramolecular Passerini reaction was used for the synthesis of chiral γ-lactones S54-4 (Scheme 54) [197,198]. This one-pot sequential synthesis starts with the reaction between the Boc-protected 2-indolylboronic acids S54-1 and 5-hydroxyfuran-2(5H)-one (S54-2) in the presence of a diphenylprolinol catalyst. The organocatalyst activates the starting 5-hydroxyfuran-2(5H)-one, while the subsequent addition of indolylboronic acid S54-1 provides the acyclic intermediate S54-3, which undergoes a diastereoselective Passerini reaction with isonitriles. A series of chiral lactones S54-4a−S54-4c substituted with the indole moiety were prepared using this methodology. A combination of the organocatalytic Michael addition of boronic acids and the diastereoselective intramolecular Passerini reaction was used for the synthesis of chiral γ-lactones S54-4 (Scheme 54) [197,198]. This one-pot sequential synthesis starts with the reaction between the Boc-protected 2-indolylboronic acids S54-1 and 5-hydroxyfuran-2(5H)-one (S54-2) in the presence of a diphenylprolinol catalyst. The organocatalyst activates the starting 5-hydroxyfuran-2(5H)-one, while the subsequent addition of indolylboronic acid S54-1 provides the acyclic intermediate S54-3, which undergoes a diastereoselective Passerini reaction with isonitriles. A series of chiral lactones S54-4a−S54-4c substituted with the indole moiety were prepared using this methodology. Scheme 53. Enantioselective addition of indolylboronic acid diethyl esters to o-quinone methide catalyzed by chiral biphenol.