34 research outputs found
A Facile Access to 4‑Substituted-2-naphthols via a Tandem Friedel–Crafts Reaction: A β‑Chlorovinyl Ketone Pathway
A one-pot
synthesis of 2-naphthol derivatives is accomplished using
a tandem Friedel–Crafts reaction sequence. The developed methodology
allows for a concomitant construction of up to three C–C bonds
between readily available alkynes and phenylacetyl chloride derivatives
by an intermolecular Friedel–Crafts acylation of alkynes followed
by an intramolecular Friedel–Crafts alkylation of β-chlorovinyl
ketone intermediates
A One-Pot Synthesis of Pyranone and Pyrrole Derivatives from β‑Chlorovinyl Ketones via Direct Conjugate Addition Approach
The direct conjugate
addition reactions of imino esters to β-chlorovinyl
ketones have been accomplished in the presence of a substoichiometric
amount of hard base, LiHMDS. An <i>in situ</i> generated
species from the conjugate addition reaction readily acted as autocatalyst
to convert the imino esters to its corresponding enolates. By utilizing
a sequence of conjugate addition/elimination/lactonization followed
by either reduction or reaction with amines, the novel one-pot syntheses
of highly functionalized pyranone and pyrrole derivatives were accomplished
in good to excellent yields
1,3-Dienones and 2<i>H</i>‑Pyran-2-ones from Soft α‑Vinyl Enolization of β‑Chlorovinyl Ketones: Defined Roles of Brönsted and Lewis Base
The eliminative reaction pathways
of (<i>E</i>)-β-chlorovinyl
ketones were investigated in the presence of both Brönsted
and Lewis bases. The Brönsted base, Et<sub>3</sub>N, effected
the soft α-vinyl enolization of (<i>E</i>)-β-chlorovinyl
ketones to [3]Âcumulenol intermediates; in turn, a catalytic amount
of Lewis base, PPh<sub>3</sub>, initiated isomerization to provide
1,3-dienones in high yields. The introduction of a carbon-based nucleophile
into the reaction mixture provided the highly efficient synthetic
route to 2<i>H</i>-pyran-2-ones in one pot, where the carbon-based
nucleophile generated by an extra equivalent of Brönsted base,
Et<sub>3</sub>N, attacked the electrophilic [3]Âcumulenol intermediates
to initiate cyclization to give 2<i>H</i>-pyran-2-ones
Visible-Light [4+2] Homodimerization of Decomposition-Prone Styrenes via Electron Transfer Catalysis of Diaryl Diselenides
The facile electron transfer catalysis of diaryl diselenides
was
utilized for the visible-light [4+2] homodimerization of decomposition-prone
styrenes. The reaction required only 0.5 mol % TPT+BF4– photocatalyst and 1.5 mol % electron transfer
catalyst (ArSe)2. The spontaneous electron transfer capability
of diaryl diselenides was demonstrated for the first time, leading
to the sequestration of redox-prone radical cation intermediates via
electron transfer processes. A variety of polymerization-prone styrenes
smoothly underwent the visible-light-promoted [4+2] homodimerization
to tetralin derivatives
Visible-Light [4+2] Homodimerization of Decomposition-Prone Styrenes via Electron Transfer Catalysis of Diaryl Diselenides
The facile electron transfer catalysis of diaryl diselenides
was
utilized for the visible-light [4+2] homodimerization of decomposition-prone
styrenes. The reaction required only 0.5 mol % TPT+BF4– photocatalyst and 1.5 mol % electron transfer
catalyst (ArSe)2. The spontaneous electron transfer capability
of diaryl diselenides was demonstrated for the first time, leading
to the sequestration of redox-prone radical cation intermediates via
electron transfer processes. A variety of polymerization-prone styrenes
smoothly underwent the visible-light-promoted [4+2] homodimerization
to tetralin derivatives
One-Pot Tandem Nickel-Catalyzed α‑Vinyl Aldol Reaction and Cycloaddition Approach to [1,2,3]Triazolo[1,5‑<i>a</i>]quinolines
A one-pot tandem approach to [1,2,3]triazolo[1,5-a]quinolines was developed from (E)-β-chlorovinyl
ketones and 2-azidoaryl carbonyls using a sequence of α-vinyl
aldol and azide–alkyne cycloaddition reactions. In particular,
the intramolecular azide–alkyne cycloaddition of allenol intermediates
was readily promoted by a synergistic action of NEt3 and
nickel catalysts. Given that the [1,2,3]triazolo[1,5-a]quinolines are useful synthetic precursors to α-diazoimines
through ring–chain isomerization process, the subsequent denitrogenative
transformations should provide ready access to valuable heterocyclic
compounds
Silver-Catalyzed Asymmetric Desymmetrization of Cyclopentenediones via [3 + 2] Cycloaddition with α‑Substituted Isocyanoacetates
A highly
selective and practical asymmetric AgÂ(I) catalyst system
has been developed for the [3 + 2] cycloaddition reactions between
isocyanoacetates and cyclopentenediones. The current AgÂ(I) catalyst
system tolerates moisture and air and readily utilizes class III solvents
such as EtOAc and acetone. The development of <i>on demand</i> generation of an active chiral catalyst in the presence of isocyanides
paves a way to the efficient asymmetric preparation of bicyclic pyrrolidines
with four stereogenic centers, including two quaternary centers in
80–97% ee
<i>o</i>‑Naphthoquinone-Catalyzed Aerobic Oxidation of Amines to (Ket)imines: A Modular Catalyst Approach
A modular aerobic
oxidation of amines to imines has been achieved
using an <i>ortho</i>-naphthoÂquinone (<i><b>o</b></i><b>-NQ</b>) catalyst. The cooperative catalyst
system of <i><b>o</b></i><b>-NQ</b> and CuÂ(OAc)<sub>2</sub> enabled the formation of homocoupled imines from benzylamines,
while the presence of TFA helped the formation of cross-coupled imines
in excellent yields. The current mild aerobic oxidation protocol could
also be applied to the oxidation of secondary amines to imines or
ketimines with the help of cocatalyst, Ag<sub>2</sub>CO<sub>3</sub>, with excellent yields
Direct Acyl Radical Addition to 2<i>H</i>‑Indazoles Using Ag-Catalyzed Decarboxylative Cross-Coupling of α‑Keto Acids
A direct acyl radical addition to
2<i>H</i>-indazoles
has been achieved for the first time, where the less-aromatic <i>quinonoid</i> 2<i>H</i>-indazoles readily accepted
radical species to the C-3 position. Motivated by the lack of direct
acylation strategy for 2<i>H</i>-indazoles, the current
method utilizes the radical acceptability of 2<i>H</i>-indazoles,
discovering an ambient temperature reaction to provide facile access
to a diverse array of 3-acyl-2<i>H</i>-indazoles with three
points of structural diversification in 25%–83% yields
Substituted Pyrrololactams via Ring Expansion of Spiro‑2<i>H</i>‑pyrroles from Intermolecular Alkyne–Isocyanide Click Reactions
The facile synthesis
of 6- to 8-membered pyrrololactams has been
developed using a ring expansion of spiro-2<i>H</i>-pyrroles,
the products of intermolecular alkyne–isocyanide click reactions.
The key to successful ring expansion of spiro-2<i>H</i>-pyrroles
to pyrrololactams is the enforced orbital overlap between the internal
alkene and the amide carbonyl group through the conformationally locked
bicyclic structures. The newly disclosed α-isocyano lactams,
substrates for click reactions, should find their utility in the synthesis
of pharmaceutically important heterocyclic compounds