Rhodium(III)‐Catalyzed Regioselective Direct C‐2 Alkenylation of Indoles Assisted by the Removable N‐(2‐Pyrimidyl) Group

Gong, Binwei; Shi, Jingjing; Wang, Xiaowei; Yan, Yijun; Qiu, Li; Yang, Meng; Xu, H. Eric; Yi, Wei

doi:10.1002/adsc.201300700

Cited by 68 publications

(14 citation statements)

References 68 publications

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“…In our theoretical calculations, N , N ‐diisopropylbenzamide was selected as the model reaction to study the mechanism of bromination. Cleavage of the C−H bond is generally considered to be the rate‐determining step in the majority of Rh‐catalyzed C−H bond functionalization reactions reported to date ,,–. With this in mind, we considered that this step would occur after the oxidative addition of NBS and initially calculated the free energy profiles for pathway A.…”

Section: Resultsmentioning

confidence: 99%

Computational Investigation of the Role Played by Rhodium(V) in the Rhodium(III)‐Catalyzed ortho‐Bromination of Arenes

Zhang

Liu

et al. 2017

Chemistry A European J

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In this study, M11-L was used to evaluate the feasibility of the formation of rhodium(V) species using the rhodium(III)-catalyzed ortho-bromination of arenes as a model reaction. In most cases for these types of reactions, DFT calculations reveal that the bromination step involves a Br transfer from N-bromosuccinimide to the reacting arylrhodium to form a bromonium intermediate, followed by a Br shift to generate a new C-Br bond, which is more favorable than the previously proposed Rh /Rh catalytic cycle. The rhodium catalyst remains in its +3 oxidation state throughout. The substituent effects of the reacting arene were studied, and computational results showed that the introduction of electron-donating groups on the reacting arene was favorable for this pathway. In contrast, the inclusion of a strong electron-withdrawing group on the aromatic ring would hinder the formation of a bromonium intermediate. Therefore, the Rh /Rh catalytic cycle is favorable in cases that involve a Rh intermediate, which is generated by oxidative addition with NBS. In this pathway, the C-Br bond is formed by reductive elimination from the Rh intermediate. Additionally, a distortion-interaction analysis model along the reaction pathway was used to explain the directing-group effects. The results showed that the interaction energy controlled the reactivity because of the difference in electronic nature of various directing groups.

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Section: Resultsmentioning

confidence: 99%

Computational Investigation of the Role Played by Rhodium(V) in the Rhodium(III)‐Catalyzed ortho‐Bromination of Arenes

Zhang

Liu

et al. 2017

Chemistry A European J

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“…The utilization of the N‐ (2‐pyrimidyl) group for the selective C‐2 alkenylation of indoles is effective using Rh III complexes coupled with Cu(OAc) 2 , or molecular oxygen as terminal oxidants (Scheme ) . The yields of the prepared adducts are comparable with those previously obtained using the same metal and the N , N ‐dimethylcarbamoyl directing group.…”

Section: Transition Metal C−h Activation Of Indoles and Alkenesmentioning

confidence: 94%

“…Ac atalytic system composed by [Cp*RhCl 2 ] 2 and AgSbF 6 leads to at andem alkenylation-deprotection of the corresponding indole, although the alkenylated products are obtained with lower chemical yields compared to the twosteps method (46-85 %). [48] The utilization of the N-(2-pyrimidyl) group for the selective C-2 alkenylation of indoles is effective using Rh III complexes coupled with Cu(OAc) 2 , [49] or molecular oxygen as terminal oxidants (Scheme 14). [50] The yields of the prepared adducts are comparable with those previouslyo btained using the same metal andt he N,N-dimethylcarbamoyl directing group.…”

Section: C-2 Alkenylationsmentioning

confidence: 99%

Regioselective Direct C‐Alkenylation of Indoles

Petrini

2017

Chemistry A European J

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The direct introduction of alkenyl groups into the indole framework avoiding its preliminary functionalization can be carried out using different synthetic strategies. Transition-metal complexes facilitate the C-H activation of indoles or alkenes allowing an efficient Csp - Csp bond formation. The hydroindolation of alkynes catalyzed by the same metal complexes or various acidic promoters can also be pursued for the alkenylation process. Conjugate addition of electron-poor alkenes and direct condensation of carbonyl derivatives with indoles are also of interest for this purpose. The regiochemical control can be exploited using the intrinsic C-3 reactivity of the indole ring. The introduction of a suitable directing group at the nitrogen atom allows the preparation of C-2 alkenylated derivatives by transition metal catalyzed reactions. This review collects the fundamental contributions in this field reported in literature during the last fifteen years.

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“…In these reports, Cp*(pentamethylcyclopentadienyl) ligated rhodium complexes proved to be effective catalysts for this kind of transformation, and a variety of directing groups containing oxygen, nitrogen and sulfur atoms have exhibited their remarkable ability to promote the reactivity and selectivity. In particular, the 2‐pyrimidyl and 2‐pyridyl groups performed well as readily installable and removable directing groups in direct olefination of N‐heterocycles such as indoles,,,,, pyrroles,,, and indolines. Inspired by these elegant studies, we envisioned that the installation of a pyrimidyl or pyridyl directing groups on the N atom of the imidazole ring may facilitate direct C−H olefination of imidazoles in the presence of a Rh(III) catalyst.…”

Section: Introductionmentioning

confidence: 99%

Rhodium(III)‐Catalyzed Selective Direct Olefination of Imidazoles

Zhao

Chen

et al. 2018

Adv Synth Catal

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Rhodium(III)-catalyzed chelation-assisted highly regio-and stereoselective direct olefination of imidazoles with olefins has been developed. A broad range of C2-substituted N-(2-pyrimidyl)imidazoles underwent smooth C5-olefination with both activated and unactivated olefins to furnish the corresponding products in good to excellent yields with high tolerance of functional groups on both coupling partners in the presence of a cationic rhodium(III) catalyst. The combination of a catalytic amount of Cu(OAc) 2 (copper(II) acetate) and O 2 (oxygen) serves as the terminal oxidant. This protocol strongly relies on the use of 2substituted imidazoles as the substrates, and the presence of readily installable and removable pyrimidyl directing group was found to be critical for catalysis. Mechanistic studies suggest the involvement of a fivemembered rhodacycle as the key intermediate in the catalytic cycle. The method can also be extended to the coupling reaction of benzimidazoles with olefins.

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Rhodium(III)‐Catalyzed Regioselective Direct C‐2 Alkenylation of Indoles Assisted by the Removable N‐(2‐Pyrimidyl) Group

Cited by 68 publications

References 68 publications

Computational Investigation of the Role Played by Rhodium(V) in the Rhodium(III)‐Catalyzed ortho‐Bromination of Arenes

Computational Investigation of the Role Played by Rhodium(V) in the Rhodium(III)‐Catalyzed ortho‐Bromination of Arenes

Regioselective Direct C‐Alkenylation of Indoles

Rhodium(III)‐Catalyzed Selective Direct Olefination of Imidazoles

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