Deprotonative cadmation of functionalized aromatics

L’Helgoual’ch, Jean-Martial; Bentabed‐Ababsa, Ghenia; Chevallier, Floris; Yonehara, Mitsuhiro; Uchiyama, Masanobu; Derdour, Aïcha; Mongin, Florence

doi:10.1039/b809543d

Cited by 78 publications

(26 citation statements)

References 32 publications

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“…9 It has been a hot and fascinating topic that the alkali metal-mediated magnesiation, 20 zincation, 20,21 alumination, 22 cupration, 23 and cadmation 24 of aromatic compounds, including indoles and pyrroles, have been achieved by using ate bases [20][21][22][23][24] or a neutral base. 21b It should be noted that Me 2 AlCl metalated 1-methylindole (1a) at the 3-position (vide supra), while an ate base, i-Bu 3 Al(TM-P)Li, metalates 1-(Boc)indole at the 2-position.…”

Section: Contents Lists Available At Sciencedirectmentioning

confidence: 99%

Carboxylation of indoles and pyrroles with CO2 in the presence of dialkylaluminum halides

Nemoto

Onozawa

Egusa

et al. 2009

Tetrahedron Letters

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Section: Contents Lists Available At Sciencedirectmentioning

confidence: 99%

Carboxylation of indoles and pyrroles with CO2 in the presence of dialkylaluminum halides

Nemoto

Onozawa

Egusa

et al. 2009

Tetrahedron Letters

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“…[93] Substituierte Arene und Heteroarene mit empfindlichen Funktionen, beispielsweise Ester-, Cyan-und Ketogruppen, werden regioselektiv metalliert. [93,128] Die Cadmiumbase 102 wandelte substituierte Triazolpyridine wie 103 in das entsprechende Cadmiumreagens 104 um (25 8C, 2 h), [129] dessen Iodolyse anschließend das Iodtriazolpyridin 105 in 65 % Ausbeute lieferte (Schema 22). [93,128,130] Isonicotinsäureethylester wird von 102 (25 8C, 2 h) regioselektiv cadmiert und durch anschließende Iodolyse in die substituierte Isonicotinsäure 106 überführt (65 % Ausbeute).…”

Section: Tmp-aluminatbasenunclassified

“…[93,128] Die Cadmiumbase 102 wandelte substituierte Triazolpyridine wie 103 in das entsprechende Cadmiumreagens 104 um (25 8C, 2 h), [129] dessen Iodolyse anschließend das Iodtriazolpyridin 105 in 65 % Ausbeute lieferte (Schema 22). [93,128,130] Isonicotinsäureethylester wird von 102 (25 8C, 2 h) regioselektiv cadmiert und durch anschließende Iodolyse in die substituierte Isonicotinsäure 106 überführt (65 % Ausbeute). [130] Detaillierte NMR-spektroskopische Untersuchungen und DFT-Rechnungen bestätigen die Struktur von 102 als eigentliches Metallierungsreagens.…”

Section: Tmp-aluminatbasenunclassified

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Regio‐ und chemoselektive Metallierung von Arenen und Heteroarenen mit gehinderten Metallamidbasen

et al. 2011

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Die Synthese hoch funktionalisierter Organometallverbindungen gelingt durch C‐H‐Aktivierung zahlreicher ungesättigter Substrate mit Lithiumchlorid‐solubilisierten 2,2,6,6‐Tetramethylpiperidyl‐Basen (TMPnMXm⋅p LiCl). Diese Reagentien erweisen sich als exzellent zur Umwandlung vielfältiger aromatischer sowie heterocyclischer Substrate in nützliche metallorganische Reagentien mit weiter Anwendungsbreite in der organischen Synthese.

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“…Often superior in terms of functional-group tolerance, compatibility with more organic substrates, and milder experimental conditions than classical lithiation methods, these new metalations, which are zinc–hydrogen exchange reactions assisted by the presence of a charge-balancing alkali metal cation, can be interpreted as “alkali-metal-mediated zincations” (AMMZn) [2]. A range of other mildly electropositive, soft metals including aluminum,[3] cadmium,[4] iron,[5] magnesium,[6,1] and manganese[7] have similarly been transformed into powerful selective metalating agents through this special alkali-metal-mediated phenomenon. Two widely studied reagents in the context of AMMZn are TMP based, one being the lithium–zincate [Li(tmp)Zn( t Bu) 2 ] (TMP=2,2,6,6-tetramethylpiperidide) developed by Kondo and Uchiyama[8, 2c ] and the other is the sodium analogue [(tmeda)Na(μ- t Bu)(μ-tmp)Zn( t Bu)] (TMEDA= N , N , N′ , N′ -tetramethylethylenediamine) made by our own group, [2b] whereas Knochel has recently introduced an efficient zincating reagent by mixing the lithium–magnesiate Mg(tmp) 2 ⋅ 2LiCl with the halide ZnCl 2 [9]…”

Section: Introductionmentioning

confidence: 99%

Structurally Defined Potassium‐Mediated Zincation of Pyridine and 4‐R‐Substituted Pyridines (R=Et, iPr, tBu, Ph, and Me₂N) by Using Dialkyl–TMP–Zincate Bases

Clegg

Conway

Graham

et al. 2009

Chemistry A European J

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Two potassium–dialkyl–TMP–zincate bases [(pmdeta)K(μ-Et)(μ-tmp)Zn(Et)] (1) (PMDETA=N,N,N′,N′′,N′′-pentamethyldiethylenetriamine, TMP=2,2,6,6-tetramethylpiperidide), and [(pmdeta)K(μ-nBu)(μ-tmp)Zn(nBu)] (2), have been synthesized by a simple co-complexation procedure. Treatment of 1 with a series of substituted 4-R-pyridines (R=Me2N, H, Et, iPr, tBu, and Ph) gave 2-zincated products of the general formula [{2-Zn(Et)2-μ-4-R-C5H3N}2⋅2{K(pmdeta)}] (3–8, respectively) in isolated crystalline yields of 53, 16, 7, 23, 67, and 51%, respectively; the treatment of 2 with 4-tBu-pyridine gave [{2-Zn(nBu)2-μ-4-tBu-C5H3N}2⋅2{K(pmdeta)}] (9) in an isolated crystalline yield of 58%. Single-crystal X-ray crystallographic and NMR spectroscopic characterization of 3–9 revealed a novel structural motif consisting of a dianionic dihydroanthracene-like tricyclic ring system with a central diazadicarbadizinca (ZnCN)2 ring, face-capped on either side by PMDETA-wrapped K+ cations. All the new metalated pyridine complexes share this dimeric arrangement. As determined by NMR spectroscopic investigations of the reaction filtrates, those solutions producing 3, 7, 8, and 9 appear to be essentially clean reactions, in contrast to those producing 4, 5, and 6, which also contain laterally zincated coproducts. In all of these metalation reactions, the potassium–zincate base acts as an amido transfer agent with a subsequent ligand-exchange mechanism (amido replacing alkyl) inhibited by the coordinative saturation, and thus, low Lewis acidity of the 4-coordinate Zn centers in these dimeric molecules. Studies on analogous trialkyl–zincate reagents in the absence and presence of stoichiometric or substoichiometric amounts of TMP(H) established the importance of Zn–N bonds for efficient zincation.

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Deprotonative cadmation of functionalized aromatics

Abstract: This communication describes the deproto-metalation of a large range of aromatics including heterocycles using a newly developed lithium-cadmium base; the reaction proceeds at room temperature with an excellent chemoselectivity and efficiency, and proved to be regioselective in most cases.

Cited by 78 publications

References 32 publications

Carboxylation of indoles and pyrroles with CO2 in the presence of dialkylaluminum halides

Carboxylation of indoles and pyrroles with CO2 in the presence of dialkylaluminum halides

Regio‐ und chemoselektive Metallierung von Arenen und Heteroarenen mit gehinderten Metallamidbasen

Structurally Defined Potassium‐Mediated Zincation of Pyridine and 4‐R‐Substituted Pyridines (R=Et, iPr, tBu, Ph, and Me₂N) by Using Dialkyl–TMP–Zincate Bases

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Deprotonative cadmation of functionalized aromatics

Cited by 78 publications

References 32 publications

Carboxylation of indoles and pyrroles with CO2 in the presence of dialkylaluminum halides

Carboxylation of indoles and pyrroles with CO2 in the presence of dialkylaluminum halides

Regio‐ und chemoselektive Metallierung von Arenen und Heteroarenen mit gehinderten Metallamidbasen

Structurally Defined Potassium‐Mediated Zincation of Pyridine and 4‐R‐Substituted Pyridines (R=Et, iPr, tBu, Ph, and Me2N) by Using Dialkyl–TMP–Zincate Bases

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Structurally Defined Potassium‐Mediated Zincation of Pyridine and 4‐R‐Substituted Pyridines (R=Et, iPr, tBu, Ph, and Me₂N) by Using Dialkyl–TMP–Zincate Bases