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Search for "gold carbenes" in Full Text gives 7 result(s) in Beilstein Journal of Organic Chemistry.
The synthesis of functionalized bridged polycycles via C–H bond insertion
- Jiun-Le Shih,
- Po-An Chen and
- Jeremy A. May
Beilstein J. Org. Chem. 2016, 12, 985–999, doi:10.3762/bjoc.12.97
- gold ketocarbenes 104 from alkynes (Scheme 22) [95]. Those carbenes are then capable of further transformations, including C–H bond insertion and the reaction with other alkynes. Notably, this approach avoids the use of unstable diazo compounds. The Zhang group also demonstrated that the gold carbenes
Graphical Abstract
Figure 1: Bridged polycyclic natural products.
Figure 2: Strategic limitations.
Scheme 1: Bridged rings from N–H bond insertions.
Scheme 2: The synthesis of deoxystemodin.
Scheme 3: A model system for ingenol.
Scheme 4: Formal synthesis of platensimycin.
Scheme 5: The formal synthesis of gerryine.
Scheme 6: Copper-catalyzed bridged-ring synthesis.
Scheme 7: Factors influencing insertion selectivity.
Scheme 8: Bridged-lactam formation.
Scheme 9: The total synthesis of (+)-codeine.
Scheme 10: A model system for irroratin.
Scheme 11: The utility of 1,6-insertion.
Scheme 12: Piperidine functionalization.
Scheme 13: Wilkinson’s catalyst for C–H bond insertion.
Scheme 14: Bridgehead insertion and the total synthesis of albene and santalene.
Scheme 15: The total synthesis of neopupukean-10-one.
Scheme 16: An approach to phomoidride B.
Scheme 17: Carbene cascade for fused bicycles.
Scheme 18: Cascade formation of bridged rings.
Scheme 19: Conformational effects.
Scheme 20: Hydrazone cascade reaction.
Scheme 21: Mechanistic studies.
Scheme 22: Gold carbene formation from alkynes.
Scheme 23: Au-catalyzed bridged-bicycle formation.
Scheme 24: Gold carbene/alkyne cascade.
Scheme 25: Gold carbene/alkyne cascade with C–H bond insertion.
Scheme 26: Platinum cascades.
Scheme 27: Tungsten cascade.
Gold(I)-catalyzed enantioselective cycloaddition reactions
- Fernando López and
- José L. Mascareñas
Beilstein J. Org. Chem. 2013, 9, 2250–2264, doi:10.3762/bjoc.9.264
- could be formally categorized as a [2 + 1] cycloaddition. In particular, they showed that it is possible to trap the intermediate gold–carbenes resulting from a 1,2-acyloxy migration in propargyl esters such as 1, with external alkenes (e.g. vinylarenes), to give cyclopropane products [41]. The racemic
- -workers reported another example of a highly enantioselective gold-catalyzed cyclopropanation reaction by using diazo compounds as a source of gold carbenes. In particular, the authors demonstrated that the chiral bisgold complex Au6, derived from the spiroketal bisphosphine ligand, was a very efficient
Graphical Abstract
Figure 1: Gold-promoted 1,2-acyloxy migration on propargylic systems.
Scheme 1: Gold-catalyzed enantioselective intermolecular cyclopropanation.
Scheme 2: Gold-catalyzed enantioselective intramolecular cyclopropanation.
Scheme 3: Gold-catalyzed cyclohepta-annulation cascade.
Scheme 4: Application to the formal synthesis of frondosin A.
Scheme 5: Gold(I)-catalyzed enantioselective cyclopropenation of alkynes.
Scheme 6: Enantioselective cyclopropanation of diazooxindoles.
Figure 2: Proposed structures for gold-activated allene complexes.
Scheme 7: Gold-catalyzed enantioselective [2 + 2] cycloadditions of allenenes.
Scheme 8: Gold-catalyzed allenediene [4 + 3] and [4 + 2] cycloadditions.
Scheme 9: Gold-catalyzed enantioselective [4 + 2] cycloadditions of allenedienes.
Scheme 10: Gold-catalyzed enantioselective [4 + 3] cycloadditions of allenedienes.
Scheme 11: Gold-catalyzed enantioselective [4 + 2] cycloadditions of allenamides.
Scheme 12: Enantioselective [2 + 2] cycloadditions of allenamides.
Scheme 13: Mechanistic rational for the gold-catalyzed [2 + 2] cycloadditions.
Scheme 14: Enantioselective cascade cycloadditions between allenamides and oxoalkenes.
Scheme 15: Enantioselective [3 + 2] cycloadditions of nitrones and allenamides.
Scheme 16: Enantioselective formal [4 + 3] cycloadditions leading to 1,2-oxazepane derivatives.
Scheme 17: Enantioselective gold(I)-catalyzed 1,3-dipolar [3 + 3] cycloaddition between 2-(1-alkynyl)-2-alken-...
Scheme 18: Enantioselective [4 + 3] cycloaddition leading to 5,7-fused bicyclic furo[3,4-d][1,2]oxazepines.
Gold-catalyzed regioselective oxidation of propargylic carboxylates: a reliable access to α-carboxy-α,β-unsaturated ketones/aldehydes
- Kegong Ji,
- Jonathan Nelson and
- Liming Zhang
Beilstein J. Org. Chem. 2013, 9, 1925–1930, doi:10.3762/bjoc.9.227
- carboxylate; Introduction We reported in 2010 [1] that α-oxo gold carbenes could be conveniently generated as reactive intermediates in gold-catalyzed intermolecular oxidation of alkynes. By using pyridine N-oxides [1] and later 8-substituted quinoline N-oxides [2] as the external oxidants, this approach
- permits a safe and efficient access to α-oxo gold carbenes without resorting to the dediazotization strategy [3][4][5] using hazardous and potentially explosive diazo substrates (Scheme 1). Since then an array of versatile synthetic methods has been developed based on the general approach by us [2][6][7
- migration might be an even less meaningful event in the reaction; b) it is known that the gold carbenes of type B can be readily oxidized by Ph2S=O [33], which, however, is an inefficient oxidant for generating α-oxo gold carbenes of type A via alkyne oxidation [34][35]; when the N-oxide 3 is replaced by
Graphical Abstract
Scheme 1: Generation of α-oxo gold carbenes via intermolecular oxidation of alkynes: a non-diazo approach.
Scheme 2: Gold-catalyzed regioselective oxidation of a sterically biased internal alkyne.
Scheme 3: Gold-catalyzed oxidation of the propargylic acetate 4a and the mechanistic rationale.
Scheme 4: A drastically different outcome by using diphenyl sulfoxide as the oxidant.
Figure 1: The impact of ligands on the ratio of 5a-OAc and 5a-H in the gold-catalyzed oxidation of 4a (reacti...
Figure 2: Natural charges at and the 13C chemical shifts of the alkynyl carbons in 4a.
Recent advances in the gold-catalyzed additions to C–C multiple bonds
- He Huang,
- Yu Zhou and
- Hong Liu
Beilstein J. Org. Chem. 2011, 7, 897–936, doi:10.3762/bjoc.7.103
- gold-catalyzed synthesis of dihydrofuran-3-ones 63, in which terminal alkynes 62 were used as equivalents of α-diazo ketones to generate α-oxo gold carbenes (Scheme 12) [37]. The α-oxo gold carbenes were produced via gold-catalyzed intermolecular oxidation of 62. This provides improved synthetic
Graphical Abstract
Scheme 1: Gold-catalyzed addition of alcohols.
Scheme 2: Gold-catalyzed cycloaddition of alcohols.
Scheme 3: Ionic liquids as the solvent in gold-catalyzed cycloaddition.
Scheme 4: Gold-catalyzed cycloaddition of diynes.
Scheme 5: Gold(I) chloride catalyzed cycloisomerization of 2-alkynyl-1,5-diols.
Scheme 6: Gold-catalyzed cycloaddition of glycols and dihydroxy compounds.
Scheme 7: Gold-catalyzed ring-opening of cyclopropenes.
Scheme 8: Gold-catalyzed intermolecular hydroalkoxylation of alkynes. PR3 = 41–45.
Scheme 9: Gold-catalyzed intramolecular 6-endo-dig cyclization of β-hydroxy-α,α-difluoroynones.
Scheme 10: Gold-catalyzed intermolecular hydroalkoxylation of non-activated olefins.
Scheme 11: Preparation of unsymmetrical ethers from alcohols.
Scheme 12: Expedient synthesis of dihydrofuran-3-ones.
Scheme 13: Catalytic approach to functionalized divinyl ketones.
Scheme 14: Gold-catalyzed glycosylation.
Scheme 15: Gold-catalyzed cycloaddition of aldehydes and ketones.
Scheme 16: Gold-catalyzed annulations of 2-(ynol)aryl aldehydes and o-alkynyl benzaldehydes.
Scheme 17: Gold-catalyzed addition of carboxylates.
Scheme 18: Dual-catalyzed rearrangement reaction of allenoates.
Scheme 19: Meyer–Schuster rearrangement of propargylic alcohols.
Scheme 20: Propargylic alcohol rearrangements.
Scheme 21: Gold-catalyzed synthesis of imines and amine alkylation.
Scheme 22: Hydroamination of allenes and allenamides.
Scheme 23: Gold-catalyzed inter- and intramolecular amination of alkynes and alkenes.
Scheme 24: Gold-catalyzed cycloisomerization of O-propioloyl oximes and β-allenylhydrazones.
Scheme 25: Intra- and intermolecular amination with ureas.
Scheme 26: Gold-catalyzed cyclization of ortho-alkynyl-N-sulfonylanilines and but-3-yn-1-amines.
Scheme 27: Gold-catalyzed piperidine ring synthesis.
Scheme 28: Ring expansion of alkylnyl cyclopropanes.
Scheme 29: Gold-catalyzed annulations of N-propargyl-β-enaminones and azomethine imines.
Scheme 30: Gold(I)-catalyzed cycloisomerization of aziridines.
Scheme 31: AuCl3/AgSbF6-catalyzed intramolecular amination of 2-(tosylamino)phenylprop-1-en-3-ols.
Scheme 32: Gold-catalyzed cyclization via a 7-endo-dig pathway.
Scheme 33: Gold-catalyzed synthesis of fused xanthines.
Scheme 34: Gold-catalyzed synthesis of amides and isoquinolines.
Scheme 35: Gold-catalyzed oxidative cross-coupling reactions of propargylic acetates.
Scheme 36: Gold-catalyzed nucleophilic addition to allenamides.
Scheme 37: Gold-catalyzed direct carbon–carbon bond coupling reactions.
Scheme 38: Gold-catalyzed C−H functionalization of indole/pyrrole heterocycles and non-activated arenes.
Scheme 39: Gold-catalyzed cycloisomerization of cyclic compounds.
Scheme 40: Gold-catalyzed cycloaddition of 1-aryl-1-allen-6-enes and propargyl acetates.
Scheme 41: Gold(I)-catalyzed cycloaddition with ligand-controlled regiochemistry.
Scheme 42: Gold(I)-catalyzed cycloaddition of dienes and enynes.
Scheme 43: Gold-catalyzed intramolecular cycloaddition of 3-alkoxy-1,5-enynes and 2,2-dipropargylmalonates.
Scheme 44: Gold-catalyzed intramolecular cycloaddition of 1,5-allenynes.
Scheme 45: Gold(I)-catalyzed cycloaddition of indoles.
Scheme 46: Gold-catalyzed annulation reactions.
Scheme 47: Gold–carbenoid induced cleavage of a sp3-hybridized C−H bond.
Scheme 48: Furan- and indole-based cascade reactions.
Scheme 49: Tandem process using aromatic alkynes.
Scheme 50: Gold-catalyzed cycloaddition of 1,3-dien-5-ynes.
Scheme 51: Gold-catalyzed cascade cyclization of diynes, propargylic esters, and 1,3-enynyl ketones.
Scheme 52: Tandem reaction of β-phenoxyimino ketones and alkynyl oxime ethers.
Scheme 53: Gold-catalyzed tandem cyclization of enynes, 2-(tosylamino)phenylprop-1-yn-3-ols, and allenoates.
Scheme 54: Cyclization of 2,4-dien-6-yne carboxylic acids.
Scheme 55: Gold(I)-catalyzed tandem cyclization approach to tetracyclic indolines.
Scheme 56: Gold-catalyzed tandem reactions of alkynes.
Scheme 57: Aminoarylation and oxyarylation of alkenes.
Scheme 58: Cycloaddition of 2-ethynylnitrobenzene with various alkenes.
Scheme 59: Gold-catalyzed tandem reactions of allenoates and alkynes.
Scheme 60: Gold-catalyzed asymmetric synthesis of 2,3-dihydropyrroles.
Scheme 61: Chiral [NHC–Au(I)]-catalyzed cyclization of enyne.
Scheme 62: Gold-catalyzed hydroaminations and hydroalkoxylations.
Scheme 63: Gold(I)-catalyzed asymmetric hydroalkoxylation of 1,3-dihydroxymethyl-2-alkynylbenzene chromium com...
Scheme 64: Gold-catalyzed synthesis of julolidine derivatives.
Scheme 65: Gold-catalyzed the synthesis of chiral fused heterocycles.
Scheme 66: Gold-catalyzed asymmetric reactions with 3,5-(t-Bu)2-4-MeO-MeOBIPHEP.
Scheme 67: Gold-catalyzed cyclization of o-(alkynyl) styrenes.
Scheme 68: Asymmetric gold(I)-catalyzed redox-neutral domino reactions of enynes.
Scheme 69: Gold(I)-catalyzed enantioselective polyene cyclization reaction.
Scheme 70: Gold(I)-catalyzed enantioselective synthesis of benzopyrans.
Scheme 71: Gold(I)-catalyzed enantioselective ring expansion of allenylcyclopropanols.
Synthetic applications of gold-catalyzed ring expansions
- David Garayalde and
- Cristina Nevado
Beilstein J. Org. Chem. 2011, 7, 767–780, doi:10.3762/bjoc.7.87
- 88 upon cyclopropyl ring expansion. Nevado and co-workers [59] have also recently used cyclopropyl intermediates, generated in situ via alkene cyclopropanations mediated by gold carbenes, for the stereocontrolled synthesis of 5- and 7-membered-rings (Scheme 27). This method was subsequently applied
Graphical Abstract
Scheme 1: Transition metal promoted rearrangements of bicyclo[1.1.0]butanes.
Scheme 2: Gold-catalyzed rearrangements of strained rings.
Scheme 3: Gold-catalyzed ring expansions of cyclopropanols and cyclobutanols.
Scheme 4: Mechanism of the cycloisomerization of alkynyl cyclopropanols and cyclobutanols.
Scheme 5: Proposed mechanism for the Au-catalyzed isomerization of alkynyl cyclobutanols.
Scheme 6: Gold-catalyzed cycloisomerization of 1-allenylcyclopropanols.
Scheme 7: Gold-catalyzed cycloisomerization of cyclopropylmethanols.
Scheme 8: Gold-catalyzed cycloisomerization of aryl alkyl epoxides.
Scheme 9: Gold-catalyzed synthesis of furans.
Scheme 10: Transformations of alkynyl oxiranes.
Scheme 11: Transformations of alkynyl oxiranes into ketals.
Scheme 12: Gold-catalyzed cycloisomerization of cyclopropyl alkynes.
Scheme 13: Gold-catalyzed synthesis of substituted furans.
Scheme 14: Proposed mechanism for the isomerization of alkynyl cyclopropyl ketones.
Scheme 15: Cycloisomerization of cyclobutylazides.
Scheme 16: Cycloisomerization of alkynyl aziridines.
Scheme 17: Gold-catalyzed synthesis of disubstituted cyclohexadienes.
Scheme 18: Gold-catalyzed synthesis of indenes.
Scheme 19: Gold-catalyzed [n + m] annulation processes.
Scheme 20: Gold-catalyzed generation of 1,4-dipoles.
Scheme 21: Gold-catalyzed synthesis of repraesentin F.
Scheme 22: Gold-catalyzed ring expansion of cyclopropyl 1,6-enynes.
Scheme 23: Gold-catalyzed synthesis of ventricos-7(13)-ene.
Scheme 24: 1,2- vs 1,3-Carboxylate migration.
Scheme 25: Gold-catalyzed cycloisomerization of vinyl alkynyl cyclopropanes.
Scheme 26: Proposed mechanism for the cycloisomerization of vinyl alkynyl cyclopropanes.
Scheme 27: Gold-catalyzed 1,2-acyloxy rearrangement/cyclopropanation/cycloisomerization cascades.
Scheme 28: Formal total synthesis of frondosin A.
Scheme 29: Gold-catalyzed rearrangement/cycloisomerization of cyclopropyl propargyl acetates.
When cyclopropenes meet gold catalysts
- Frédéric Miege,
- Christophe Meyer and
- Janine Cossy
Beilstein J. Org. Chem. 2011, 7, 717–734, doi:10.3762/bjoc.7.82
- in a variety of gold-catalyzed reactions. The different contributions in this growing research area are summarized in this review. Keywords: cyclopropenes; gold carbenes; gold catalysis; gold-stabilized allylic cations; ring-opening; Review Introduction Homogeneous gold catalysis has become a
- gold-carbon order in the so-called organogold carbenoids. In the broad repertoire of gold-catalyzed organic transformations, gold-stabilized carbocations or, more often gold carbenes, can be found as intermediates in proposed mechanistic pathways, but the true nature of the organogold species had been
- a matter of debate [27]. Structural considerations: Gold-stabilized carbocations or gold carbenes? In 2008, Fürstner et al. took advantage of the ring-opening of 3,3-disubstituted cyclopropenes to generate organogold species and characterize them by NMR spectroscopy [16]. Whereas, 3,3
Graphical Abstract
Scheme 1: General reactivity of cyclopropenes in the presence of gold catalysts.
Scheme 2: Cationic organogold species generated from cyclopropenone acetals.
Scheme 3: Rotation barriers around the C2–C3 bond (M06 DFT calculations).
Scheme 4: Au–C1 bond length in organogold species of type D.
Scheme 5: Gold-catalyzed addition of alcohols or water to cyclopropene 8.
Scheme 6: Gold-catalyzed addition of alcohols to cyclopropene 10.
Scheme 7: Mechanism of the gold-catalyzed addition of alcohols to cyclopropenes.
Scheme 8: Synthesis of tert-allylic ethers from cyclopropenes and allenes.
Scheme 9: Oxidation of the intermediate gold–carbene with diphenylsulfoxide.
Scheme 10: Gold, copper and Lewis acid-catalyzed reactions of cyclopropene 18.
Scheme 11: Mechanism of the Lewis acid-catalyzed reactions of cyclopropene 18.
Scheme 12: Gold-catalyzed rearrangement of vinylcyclopropenes 25.
Scheme 13: Gold-catalyzed rearrangement of cyclopropenes 27 to indenes 28.
Scheme 14: Gold-catalyzed rearrangement of cyclopropenes 29 to indenes 30.
Scheme 15: Gold-catalyzed rearrangement of cyclopropenyl ester 34a.
Scheme 16: Gold-catalyzed reactions of cyclopropenyl esters 34b–34d.
Scheme 17: Gold-catalyzed reactions of cyclopropenylsilane 34e.
Scheme 18: Gold-catalyzed rearrangement of cyclopropenylmethyl acetates.
Scheme 19: Mechanism of the gold-catalyzed rearrangement of cyclopropenes 39.
Scheme 20: Gold-catalyzed cyclopropanation of styrene with cyclopropene 8.
Scheme 21: Representative reactions of carbene precursors on gold metal.
Scheme 22: Intermolecular olefin cyclopropanation with gold carbenes generated from cyclopropenes.
Scheme 23: Gold-catalyzed formation of trienes from cyclopropenes and furans.
Scheme 24: Gold-catalyzed formation of trienes from cyclopropenes and furans.
Scheme 25: Gold-catalyzed formation of trienes from cyclopropenes and furans.
Scheme 26: Gold-catalyzed cycloisomerization of cyclopropene-ene 59.
Scheme 27: Gold-catalyzed cycloisomerization of substituted allyl cyclopropenyl carbinyl ethers 62a–62f.
Scheme 28: Gold-catalyzed cycloisomerization of cyclopropene-enes.
Scheme 29: Gold-catalyzed cycloisomerization of cyclopropene-ynes.
Scheme 30: Formation of products arising from a double cleavage process in the gold-catalyzed cycloisomerizati...
Scheme 31: Gold-catalyzed cycloisomerization of cyclopropene-ynes involving a double cleavage process.
Scheme 32: Gold-catalyzed reaction of cyclopropene-ynes, cyclopropene-enes and cyclopropene-allenes.
Gold-catalyzed regioselective oxidation of terminal allenes: formation of α-methanesulfonyloxy methyl ketones
- Yingdong Luo,
- Guozhu Zhang,
- Erik S. Hwang,
- Thomas A. Wilcoxon and
- Liming Zhang
Beilstein J. Org. Chem. 2011, 7, 596–600, doi:10.3762/bjoc.7.69
- ][13][14][15][16][17] or via allenes generated in situ [18][19][20][21]. We have recently shown that highly reactive gold carbenes can be generated from alkynes via gold-promoted intermolecular oxidation by pyridine/quinoline N-oxides [22][23][24][25], making benign alkynes effective surrogates of
Graphical Abstract
Scheme 1: Gold-catalyzed intermolecular oxidation of alkynes and allenes.
Scheme 2: A side reaction from 1l.
Scheme 3: A proposed reaction mechanism.
