Steering Asymmetric Lewis Acid Catalysis Exclusively with Octahedral Metal-Centered Chirality

Zhang, Lilu; Meggers, Eric

doi:10.1021/acs.accounts.6b00586

Cited by 284 publications

(166 citation statements)

References 82 publications

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“…312 The design of bioorthogonal synthetic catalyst/substratepairs, which can passively diffuse into cells for use as tools in chemical biology studies, is a highly formidable challenge that has only recently started to be investigated. 313 Recently, unique opportunities, arising from the catalysis of transition metals, 314,315 have been explored.…”

Section: Ru(ii) Complexes For Bioorthogonal Catalysismentioning

confidence: 99%

The development of anticancer ruthenium(ii) complexes: from single molecule compounds to nanomaterials

et al. 2017

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Cancer is rapidly becoming the top killer in the world. Most of the FDA approved anticancer drugs are organic molecules, while metallodrugs are very scarce. The advent of first metal based therapeutic agent, cisplatin, launched a new era in the application of transition metal complexes for therapeutic design. Due to their unique and versatile biochemical properties, ruthenium-based compounds have emerged as promising anti-cancer agents that serve as alternatives to cisplatin and its derivertives. The ruthenium(III) complexes have successfully been used in clinical research and their mechanisms of anticancer action have been reported in large volumes over the past few decades. Ruthenium(II) complexes have also attracted significant attention as anticancer candidates; however, only few of them have been reported comprehensively. In this review, we discuss the development of ruthenium(II) complexes as anticancer candidates and biocatalysts, including arene ruthenium complexes, polypyridyl ruthenium complexes, and ruthenium nanomaterial complexes. This review focuses on the likely mechanisms of action of ruthenium(II)-based anticancer drugs and the relationship between their chemical structures and biological properties. This review also highlights the catalytic activity and the photoinduced activation of ruthenium(II) complexes, their targeted delivery, and their activity in nanomaterial systems.

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Section: Ru(ii) Complexes For Bioorthogonal Catalysismentioning

confidence: 99%

The development of anticancer ruthenium(ii) complexes: from single molecule compounds to nanomaterials

et al. 2017

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“…Our design is based on our recently introduced bis-cyclometalated chiral rhodium-based Lewis acids (LAs) 13,14 for the electronic activation of substrates through two-point binding and employs Hantzsch esters ( HE s) 15 as a photoredox mediator for the generation of radical species under mild conditions (Fig. 2).…”

Section: Reaction Designmentioning

confidence: 99%

Combining the catalytic enantioselective reaction of visible-light-generated radicals with a by-product utilization system

et al. 2017

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“…[2] In such systems,t he photochemistry is not part of the catalytic cycle and often serves as an inducer of at hermal chain process.T his role is distinct from mechanistic scenarios in which the photoexcited state is directly embedded within an asymmetric catalysis cycle, thereby opening untapped opportunities for exploiting the special reactivity of photoexcited states in the context of asymmetric catalysis. [4,5] Upon binding to as ubstrate and undergoing selective visible-light activation of the formed catalyst/ substrate complexes,s uch photoexcited assemblies are capa-ble of undergoing stereocontrolled chemical transformations, either through an initial outersphere electron transfer or by engaging in direct stereocontrolled bond-forming reactions ( Figure 1). [4,5] Upon binding to as ubstrate and undergoing selective visible-light activation of the formed catalyst/ substrate complexes,s uch photoexcited assemblies are capa-ble of undergoing stereocontrolled chemical transformations, either through an initial outersphere electron transfer or by engaging in direct stereocontrolled bond-forming reactions ( Figure 1).…”

Section: Introductionmentioning

confidence: 99%

Asymmetric Photocatalysis by Intramolecular Hydrogen‐Atom Transfer in Photoexcited Catalyst–Substrate Complex

Zhang

Chen

et al. 2019

Angew Chem Int Ed

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3-(2-Formylphenyl)-1-pyrazol-1-yl-propenones undergo an asymmetric photorearrangement to benzo- [d]cyclopropa [b]pyranones with up to > 99 %e e, which is catalyzedb yabis-cyclometalated rhodium catalyst in the presence of visible light. Mechanistic experiments and DFT calculations support am echanism in which ap hotoexcited catalyst/substrate complex triggers an intramolecular hydrogen-atom transfer followed by ahighly stereocontrolled hetero-Diels-Alder reaction. In this reaction scheme,t he rhodium catalyst fulfills multiple functions by 1) enabling visible-light p!p*e xcitation of the catalyst-bound enone substrate, 2) facilitating the hydrogen-atom transfer,a nd 3) providing the asymmetric induction for the hetero-Diels-Alder reaction.Photochemistry provides new synthetic and mechanistic opportunities for asymmetric catalysis. [1] Forexample,visible light has been used as aconvenient and mild source of energy to generate free radicals,w hich are then interfaced with an asymmetric catalysis cycle. [2] In such systems,t he photochemistry is not part of the catalytic cycle and often serves as an inducer of at hermal chain process.T his role is distinct from mechanistic scenarios in which the photoexcited state is directly embedded within an asymmetric catalysis cycle, thereby opening untapped opportunities for exploiting the special reactivity of photoexcited states in the context of asymmetric catalysis. [3] Our group recently demonstrated that bis-cyclometalated iridium(III) and especially rhodium(III) complexes are exquisite catalysts for realizing visible-light-activated asymmetric catalysis. [4,5] Upon binding to as ubstrate and undergoing selective visible-light activation of the formed catalyst/ substrate complexes,s uch photoexcited assemblies are capa-ble of undergoing stereocontrolled chemical transformations, either through an initial outersphere electron transfer or by engaging in direct stereocontrolled bond-forming reactions (Figure 1). [5] Ther ealization of new reaction modes of photoexcited catalyst/substrate complexes is highly desirable for developing visible-light-activated asymmetric conversions that are otherwise elusive.Here we report au nique example of av isible-lightactivated catalyst/substrate complex engaging in ahydrogenatom transfer (HAT) reaction to generate ac atalyst-bound reactive intermediate,w hich is then primed to undergo ah ighly stereocontrolled intramolecular hetero-Diels-Alder reaction.We previously found that upon binding to bis-cyclometalated rhodium catalysts, a,b-unsaturated N-acyl pyrazoles can undergo p!p*e xcitation under visible light. We further demonstrated that these ligand-centered excited states can perform stereocontrolled cycloaddition reactions. [3d,f,6] At the onset of this study we were speculating that such photoexcited catalyst-bound enones might instead be capable of engaging in HATreactions to generate catalyst-bound reactive intermediates followed by stereocontrolled transformations.W e were inspired by areaction reported by Xia and co-workers in ...

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Steering Asymmetric Lewis Acid Catalysis Exclusively with Octahedral Metal-Centered Chirality

Cited by 284 publications

References 82 publications

The development of anticancer ruthenium(ii) complexes: from single molecule compounds to nanomaterials

The development of anticancer ruthenium(ii) complexes: from single molecule compounds to nanomaterials

Combining the catalytic enantioselective reaction of visible-light-generated radicals with a by-product utilization system

Asymmetric Photocatalysis by Intramolecular Hydrogen‐Atom Transfer in Photoexcited Catalyst–Substrate Complex

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