50 research outputs found
Total Synthesis of (−)-Rhazinilam and Formal Synthesis of (+)-Eburenine and (+)-Aspidospermidine: Asymmetric Cu-Catalyzed Propargylic Substitution
A total synthesis of (−)-rhazinilam
and formal syntheses
of (+)-eburenine and (+)-aspidospermidine that rely on a copperÂ(I)-catalyzed
asymmetric propargylic substitution as the key step are reported.
A salient feature of the reaction is the asymmetric construction of
a quaternary stereocenter in high yield and enantiomeric excess
Expedient Preparation of Trifluoromethyl-Substituted Benzofuranols
Direct access to 3-trifluoromethyl-substituted benzofuranols is presented. The products are obtained in good yields from commercially available salicylaldehydes by using in situ generated trifluoromethyl diazomethane and boron trifluoride as an activator. As shown in a representative example, the products can be transformed into the corresponding trifluoromethyl-substituted benzofurans
Total Synthesis of (±)-Gelsemoxonine
Gelsemoxonine (<b>1</b>) is a <i>Gelsemium</i> alkaloid
incorporating an unusual azetidine. Its total synthesis was achieved
employing a novel ring contraction of a spirocyclopropane isoxazolidine
to furnish a β-lactam intermediate. This β-lactam ring
was further elaborated into the azetidine of Gelsemoxonine. In addition,
the synthesis includes a highly diastereoselective reductive Heck
cyclization for the installation of the oxindole ring system as well
as a directed hydrosilylation of an alkyne to access the ethyl ketone
of the natural product
Total Synthesis of Gelsemoxonine through a Spirocyclopropane Isoxazolidine Ring Contraction
Plants of the species Gelsemium have
found application in traditional Asian medicine for over a thousand
years. Gelsemoxonine represents a novel constituent of this plant
incorporating a highly functionalized azetidine at its core. We herein
report a full account of our studies directed toward the total synthesis
of gelsemoxonine that relies on a conceptually new approach for the
construction of the central azacyclobutane. A spirocyclopropane isoxazolidine
ring contraction was employed to access a key β-lactam intermediate,
which could be further elaborated to the azetidine of the natural
product. In the course of our studies, we have gained detailed insight
into this intriguing transformation. Furthermore, we report on previously
unnoticed oligomerization chemistry of gelsemoxonine. We also document
an enantioselective synthesis of a key precursor en route to gelsemoxonine
Rh-Catalyzed Stereospecific Synthesis of Allenes from Propargylic Benzoates and Arylboronic Acids
An enantiospecific
approach to the synthesis of optically active,
trisubstituted allenes from chiral propargylic benzoates and arylboronic
acids has been developed. The transformation is catalyzed by a Rh–(P,olefin)
complex formed <i>in situ</i> from [{RhÂ(cod)ÂCl}<sub>2</sub>] and a readily available phosphoramidite ligand. The method furnishes
an assortment of diverse allenes in high yields and excellent enantiospecificity
under mild conditions
Total Synthesis of (±)-Gelsemoxonine
Gelsemoxonine (<b>1</b>) is a <i>Gelsemium</i> alkaloid
incorporating an unusual azetidine. Its total synthesis was achieved
employing a novel ring contraction of a spirocyclopropane isoxazolidine
to furnish a β-lactam intermediate. This β-lactam ring
was further elaborated into the azetidine of Gelsemoxonine. In addition,
the synthesis includes a highly diastereoselective reductive Heck
cyclization for the installation of the oxindole ring system as well
as a directed hydrosilylation of an alkyne to access the ethyl ketone
of the natural product
Ir-Catalyzed Preparation of SF<sub>5</sub>‑Substituted Potassium Aryl Trifluoroborates via C–H Borylation and Their Application in the Suzuki–Miyaura Reaction
The preparation of new pentafluorosulfanyl-substituted potassium aryltrifluoroborates via Ir-catalyzed C–H borylation is reported. The utility of these novel building blocks was demonstrated in the Suzuki–Miyaura cross-coupling reaction, giving access to 3,5-disubstituted pentafluorosulfanylbenzenes
Total Synthesis of Gelsemoxonine through a Spirocyclopropane Isoxazolidine Ring Contraction
Plants of the species Gelsemium have
found application in traditional Asian medicine for over a thousand
years. Gelsemoxonine represents a novel constituent of this plant
incorporating a highly functionalized azetidine at its core. We herein
report a full account of our studies directed toward the total synthesis
of gelsemoxonine that relies on a conceptually new approach for the
construction of the central azacyclobutane. A spirocyclopropane isoxazolidine
ring contraction was employed to access a key β-lactam intermediate,
which could be further elaborated to the azetidine of the natural
product. In the course of our studies, we have gained detailed insight
into this intriguing transformation. Furthermore, we report on previously
unnoticed oligomerization chemistry of gelsemoxonine. We also document
an enantioselective synthesis of a key precursor en route to gelsemoxonine
Total Synthesis of Gelsemoxonine through a Spirocyclopropane Isoxazolidine Ring Contraction
Plants of the species Gelsemium have
found application in traditional Asian medicine for over a thousand
years. Gelsemoxonine represents a novel constituent of this plant
incorporating a highly functionalized azetidine at its core. We herein
report a full account of our studies directed toward the total synthesis
of gelsemoxonine that relies on a conceptually new approach for the
construction of the central azacyclobutane. A spirocyclopropane isoxazolidine
ring contraction was employed to access a key β-lactam intermediate,
which could be further elaborated to the azetidine of the natural
product. In the course of our studies, we have gained detailed insight
into this intriguing transformation. Furthermore, we report on previously
unnoticed oligomerization chemistry of gelsemoxonine. We also document
an enantioselective synthesis of a key precursor en route to gelsemoxonine
Formaldehyde <i>N</i>,<i>N</i>‑Dialkylhydrazones as Neutral Formyl Anion Equivalents in Iridium-Catalyzed Asymmetric Allylic Substitution
The
use of formaldehyde <i>N</i>,<i>N</i>-dialkylhydrazones
as neutral C1-nucleophiles in the iridium-catalyzed substitution of
allylic carbonates is described for two processes. Kinetic resolution
or, alternatively, stereospecific substitution affords configurationally
stable α,α-disubstituted aldehyde hydrazones in high enantiomeric
excess and yield. This umpolung approach allows for the construction
of optically active allylic nitriles and dithiolanes as well as branched
α-aryl aldehydes. A catalyst-controlled reaction with Enders’
chiral hydrazone derivatives followed by diastereoselective nucleophilic
addition to the hydrazone products constitutes a two-step stereodivergent
synthesis of chiral amines