Palladium‐Catalyzed Asymmetric Decarboxylative Cycloaddition of Vinylethylene Carbonates with Michael Acceptors: Construction of Vicinal Quaternary Stereocenters

Khan, Ajmal; Yang, Lei; Xu, Jing; Jin, Long; Zhang, Yong Jian

doi:10.1002/anie.201407013

Cited by 242 publications

(88 citation statements)

References 54 publications

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“…[20] They are increasingly regarded as key chemicali ntermediates for the preparation of acyclic carbonates and polycarbonates [21] and as ar oute towards cis-diols, [22] methanol, [23] allylic alcohols, [24] ionic liquids, [25] and oxygen-containing heterocyclic compounds. [26] The preparation of cyclic carbonates has long been the domain of organometallic complexes of metals such as Cr,C o, Al, and Sn, [27] which are generally used in combination with co-catalytic amounts of organic nucleophiles. The role of the metal centeri nt his reactioni s the activation of the epoxide for nucleophilic attack of the cocatalystt hrough coordination of the oxygen atom (Scheme 3).…”

Section: Cycloadditions Of Co 2 To Epoxidesmentioning

confidence: 99%

Cycloadditions to Epoxides Catalyzed by Group III–V Transition‐Metal Complexes

2015

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Complexes of group III–V transition metals are gaining increasing importance as Lewis acid catalysts for the cycloaddition of dipolarophiles to epoxides. This review examines the latest reports, including homogeneous and heterogeneous applications. The pivotal step for the cycloaddition reactions is the ring opening of the epoxide following activation by the Lewis acid. Two modes of cleavage (CC versus CO) have been identified depending primarily on the substitution pattern of the epoxide, with lesser influence observed from the Lewis acid employed. The widely studied cycloaddition of CO2 to epoxides to afford cyclic carbonates (CO bond cleavage) has been scrutinized in terms of catalytic efficiency and reaction mechanism, showing that unsophisticated complexes of group III–V transition metals are excellent molecular catalysts. These metals have been incorporated, as well, in highly performing, recyclable heterogeneous catalysts. Cycloadditions to epoxides with other dipolarophiles (alkynes, imines, indoles) have been conducted with scandium triflate with remarkable performances (CC bond cleavage).

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Section: Cycloadditions Of Co 2 To Epoxidesmentioning

confidence: 99%

Cycloadditions to Epoxides Catalyzed by Group III–V Transition‐Metal Complexes

2015

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“…[20][21][22] These COCs have been frequently associated with numerous applications involving them as non-protic solvents, precursors for poly(carbonate) synthesis, electrolyte solvents and more recently as useful intermediates in organic synthesis. [23][24][25] It is for these reasons, among others, that the interest in COC synthesis has slowly but surely shifted attention towards the preparation of more sophisticated synthetic intermediates, providing new catalytic processes that show increased reactivity behavior, improved enantio-and chemo-selectivity and amplified substrate scope with excellent functional group tolerance. These endeavors can ultimate lead to the creation of secondary products derived from COC intermediates with applications in (bio)polymer synthesis 26 and pharmaceuticals.…”

Section: Introductionmentioning

confidence: 99%

Recent Advances in the Catalytic Preparation of Cyclic Organic Carbonates

2015

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ABSTRACT:The catalytic formation of cyclic organic carbonates (COCs) using carbon dioxide (CO 2 ) as a renewable carbon feed stock is a highly vibrant area of research with an increasing amount of researchers focusing on this thematic investigation. These organic carbonates are highly useful building blocks and nontoxic reagents, and are most commonly derived from CO 2 coupling reactions with oxirane and di-alcohol precursors using homogeneous catalysis methodologies. The activation of suitable reaction partners using catalysis as a key technology is a requisite for efficient CO 2 conversion as its high kinetic stability poses a barrier to access functional organic molecules with added value in both academic and industrial laboratories. Though this area of science has been flourishing for at least a decade, in the last 2−3 years significant advancements have been made to address the general reactivity and selectivity issues that are associated with the formation of COCs. Here we present a concise overview of these activities with a primary focus to highlight the most important progress made and the opportunities that catalysis can bring about when the synthesis of these intermediates is optimized to a higher level of sophistication. The attention will be limited to those cases where homogeneous metal-containing systems have been employed as they possess the highest potential for directed organic synthesis using CO 2 as molecular building block. This review discusses examples of exceptional reactivity and selectivity taking into account the challenging nature of the substrates that were involved, and mechanistic understanding guiding the optimization of these protocols is also highlighted.

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“…While the combined use of common chiral phosphine ligands, such as MOP 38 (13) or BINAP 39 (14) with TBAB was ineffective in promoting the cycloaddition (Entry 4) or inducing stereoselectivity (Entry 5), BINOLderived phosphoramidite 40,41 15 could impart sufficient cata- lytic activity to the corresponding Pd complex (Entry 6). 12 However, the observed poor stereoselectivity could not be improved by a further screening of structurally different chiral phosphoramidites. These results emphasize the critical importance of the molecular architecture of 2¢X that features the triarylphosphine incorporating chiral ammonium ion component paired with an appropriate halide ion for achieving an otherwise difficult multiple stereocontrol in the Pd-catalyzed [3+2] cycloaddition.…”

Section: Resultsmentioning

confidence: 99%

“…From this standpoint, we assessed the viability of the asymmetric construction of three contiguous stereocenters including vicinal all-carbon quaternary stereocenters 8,12,3135 through the [3+2] annulation of racemic 5-vinyloxazolidinone 8a and 2-cyano-3-phenylacrylate 6a (Table 2). Thus, the reaction of 8a with 6a catalyzed by [Pd 2 (dba) 3 ]¢CHCl 3 and 2d¢I in toluene at 0°C furnished the desired densely substituted pyrrolidine 11a in an almost stereochemically pure form (Entry 1).…”

Section: Resultsmentioning

confidence: 99%

Multiple Absolute Stereocontrol in Pd-Catalyzed [3+2] Cycloaddition of Oxazolidinones and Trisubstituted Alkenes Using Chiral Ammonium–Phosphine Hybrid Ligands

Imagawa

Nagato

Ohmatsu

et al. 2016

Bulletin of the Chemical Society of Japan

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The development of a Pd-catalyzed highly enantio-and diastereoselective [3+2] cycloaddition of 5-vinyloxazolidinones and activated trisubstituted alkenes is described in detail. This protocol for the single-step construction of densely functionalized pyrrolidines with three contiguous stereocenters including vicinal quaternary stereocenters depends on the remarkable ability of phosphine ligands possessing a chiral ammonium ion to promote intermolecular cycloaddition reactions with a precise control of absolute stereochemistry. A series of control experiments show that a chiral ammonium phosphine hybrid ligand enabled the individual, yet simultaneous stereocontrol of each chiral center in the annulation reaction. The reaction mechanism is also discussed with particular focus on the stereodetermining processes.

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Palladium‐Catalyzed Asymmetric Decarboxylative Cycloaddition of Vinylethylene Carbonates with Michael Acceptors: Construction of Vicinal Quaternary Stereocenters

Cited by 242 publications

References 54 publications

Cycloadditions to Epoxides Catalyzed by Group III–V Transition‐Metal Complexes

Cycloadditions to Epoxides Catalyzed by Group III–V Transition‐Metal Complexes

Recent Advances in the Catalytic Preparation of Cyclic Organic Carbonates

Multiple Absolute Stereocontrol in Pd-Catalyzed [3+2] Cycloaddition of Oxazolidinones and Trisubstituted Alkenes Using Chiral Ammonium–Phosphine Hybrid Ligands

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