Mechanism of NHC-Catalyzed Conjugate Additions of Diboron and Borosilane Reagents to α,β-Unsaturated Carbonyl Compounds

Wu, Hao; Garcı́a, Jeannette M.; Hæffner, Fredrik; Radomkit, Suttipol; Zhugralin, Adil R.; Hoveyda, Amir H.

doi:10.1021/jacs.5b06745

Cited by 103 publications

(33 citation statements)

References 153 publications

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“…In this substrate screening (Table ), we turned to the acceptors having a Z configuration. The results pointed out the absolute configuration was the same as that products obtained from the E precursor, which is similar with Hoveyda's Cu‐NHC and NHC catalyzed sily addition to acyclic and cyclic α,β‐unsaturated carbonyls …”

Section: Methodssupporting

confidence: 81%

Cu‐NHC‐Catalyzed Enantioselective Conjugate Silyl addition to Indol‐1‐ylacrylate Derivatives

et al. 2019

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Cu‐catalyzed enantioseletive conjugate addition of a dimethylphenylsilyl group to indol‐1‐ylacrylate derivatives was established using N‐Heterocyclic Carbenes (NHCs) as the ligands. The reaction was efficient for a wide range of indole derivatives bearing eletron‐donating and electron‐withdrawing group, and proceeded under mild condition. Good levels of enantioselectivity were also observed for diverse carbonyl derivatives.

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Section: Methodssupporting

confidence: 81%

Cu‐NHC‐Catalyzed Enantioselective Conjugate Silyl addition to Indol‐1‐ylacrylate Derivatives

et al. 2019

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“…[74,75] In Gegenwart katalytischer Mengen eines N-heterocyclischen Carbens (NHC) reagierte B 2 pin 2 über eine 1,4-Addition an die ungesättigten Systeme in hervorragender Ausbeute und Regioselektivitätz uc yclischeno der acyclischen sekundärer und tertiären Alkylboronsäureestern. [74,75] In Gegenwart katalytischer Mengen eines N-heterocyclischen Carbens (NHC) reagierte B 2 pin 2 über eine 1,4-Addition an die ungesättigten Systeme in hervorragender Ausbeute und Regioselektivitätz uc yclischeno der acyclischen sekundärer und tertiären Alkylboronsäureestern.…”

Section: üBergangsmetallfreie Borylierung Von Elektronenarmen Alkenenunclassified

“…Eine wichtige Publikation von Hoveyda und Mitarbeitern aus dem Jahr 2009 behandelte ausführlich die b-Borylierung von a,b-ungesättigten Ketone in Abwesenheit eines Metallkatalysators. [74,75] [76] Während in der anfänglichen Studie racemische b-borylierte Produkte gebildet wurden, beschrieb Hoveyda später eine asymmetrische Variante mithilfe chiraler Imidazoliumsalze in Kombination mit einer organischen Base (Schema 20). [77] Hervorragende Ausbeuten und Enantioselektivitäten konnten fürd ie b-Borylierung einer großen Auswahl an Substraten erreicht werden, einschließlich a,b-ungesättigten Ketonen, Estern, Amiden und Aldehyden;ein späterer Bericht erweiterte die Methode auf b,b-disubstituierte Enone,w as einen Zugang zu optisch reinen tertiären Alkylboronsäureestern bot.…”

Section: üBergangsmetallfreie Borylierung Von Elektronenarmen Alkenenunclassified

Asymmetrische Synthese sekundärer und tertiärer Boronsäureester

Collins¹,

Wilson²,

Myers³

et al. 2017

Angewandte Chemie

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Nicht‐racemische chirale Boronsäureester sind äußerst wertvolle Bausteine in der modernen organischen Synthese. Ihre stereospezifische Umwandlung in diverse funktionelle Gruppen – von Aminen und Halogeniden bis hin zu Arenen und Alkinen – zusammen mit ihrer Luft‐ und Feuchtigkeitsstabilität haben sie als wichtige Zielverbindungen für die asymmetrische Synthese etabliert. Die Bemühungen im Hinblick auf eine stereoselektive Synthese sekundärer und tertiärer Alkylboronsäureester erstrecken sich mittlerweise auf mehr als fünf Dekaden und werden von einer Fülle an Reaktivitätsplattformen untermauert, die sich der einzigartigen und mannigfaltigen Reaktivität von Bor bedienen. Dieser Aufsatz fasst Strategien für die asymmetrische Synthese von Alkylboronsäureestern zusammen, beginnend mit den wegweisenden Hydroborierungsmethoden von H. C. Brown bis hin zu den modernsten Herangehensweisen.

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“…The mechanism of these NHC-catalysed boryl conjugate addition reaction in the absence of transition-metal complexes [115] will not be discussed here, as it is outside of the scope of this chapter.…”

Section: Formation Of Boron-containing Quaternary Centres By Copper Cmentioning

confidence: 99%

Formation of Quaternary Stereocentres by Copper-Catalysed Enantioselective Conjugate Addition Reaction

Maciá

2015

Progress in Enantioselective Cu(I)-Catalyzed Formation of Stereogenic Centers

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Remarkable progress in copper catalysed enantioselective conjugate addition (ECA) reactions has been made over the past decade. This enantioselective transformation now allows the challenging formation of chiral quaternary centres by addition of different nucleophiles to trisubstituted ,unsaturated systems. This chapter summarizes the developments in the area.to overcome this barrier and allow the synthesis of quaternary stereogenic centres with very good selectivities [32,33], as it will be presented in the following pages of this chapter. Alternative strategies to facilitate the copper catalysed formation of quaternary chiral centres include the activation of the ,-disubstituted ,-unsaturated systems (by making the β-position more electrophilic) by using Lewis-acidic nucleophiles or by the implementation of additional electronwithdrawing functionalities in the substrate.This chapter is an overview of the copper-based catalytic systems that enable the formation of chiral quaternary centres through conjugate addition reactions. The existing methodologies have been classified in three main sections, according to the nature of the nucleophile that participates in the ECA reaction. Thus, Section 2 covers carbon nucleophiles, including organoaluminium (section 2.1), Grignard (section 2.2), organozinc (section 2.3) and organozirconium reagents (section 2.4). Next, Section 3 reviews the use of organoboron reagents, to form boron containing quaternary centres. And last, Section 4 presents the use of organosilicon reagents, to form silicon containing quaternary centres.After the ECA reaction step, the generated enolate requires protonation to generate the corresponding enol, which rapidly tautomerises to the ketone product. Protonation is typically carried out by addition of water, aqueous NH4Cl or aqueous HCl. For simplicity, this step has been omitted in all schemes, and only the conditions for the ECA have been presented. * Strangely, the use of two equivalents of MeLi gave poor processes -despite the known efficacy of Me2AlCH≡CHR species in related processes. Scheme 14. Copper catalysed ECA of organoaluminium reagents to -aryl cyclohexenones by Alexakis [47,48].Regarding the challenging -substituted cyclopenten-2-one substrates, phosphinamine ligands give moderate, comparable enantioselectivities to phosphoramidites, as shown in Scheme 15.Scheme 15. Copper-phosphinamine catalysed ECA of organoaluminium reagents to -substituted cyclopentenones by Alexakis [47,48].The tandem hydroalumination-ECA process to β-substituted cyclic enones with phosphinamine ligands also works very efficiently (Scheme 16) [49,50]. The best copper source for this catalytic system is copper (II) naphthenate, which is cheaper than the CuTC used in previous methodologies and can be used as a stock solution. A wide range of alkenylaluminium reagents can be added with

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Mechanism of NHC-Catalyzed Conjugate Additions of Diboron and Borosilane Reagents to α,β-Unsaturated Carbonyl Compounds

Cited by 103 publications

References 153 publications

Cu‐NHC‐Catalyzed Enantioselective Conjugate Silyl addition to Indol‐1‐ylacrylate Derivatives

Cu‐NHC‐Catalyzed Enantioselective Conjugate Silyl addition to Indol‐1‐ylacrylate Derivatives

Asymmetrische Synthese sekundärer und tertiärer Boronsäureester

Formation of Quaternary Stereocentres by Copper-Catalysed Enantioselective Conjugate Addition Reaction

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