5 research outputs found
A Unifying Stereochemical Analysis for the Formation of Halogenated C<sub>15</sub>-Acetogenin Medium-Ring Ethers From <i>Laurencia</i> Species via Intramolecular Bromonium Ion Assisted Epoxide Ring-Opening and Experimental Corroboration with a Model Epoxide
A unifying stereochemical analysis for the formation
of the constitutional
isomeric halogenated C<sub>15</sub>-acetogenin medium-ring ether natural
products from <i>Laurencia</i> species is presented, where
an intramolecular bromonium ion assisted epoxide ring-opening reaction
of enantiomerically pure epoxides can account for ring-size, the position
of the halogen substituents, and relative and absolute configurations
of the known natural products. Experimentally, a model epoxide corroborates
the feasibility of this process for concurrent formation of 7-, 8-
and 9-ring ethers corresponding to the halogenated medium-ring ethers
of known metabolites from <i>Laurencia</i> species
Mechanistic and Performance Studies on the Ligand-Promoted Ullmann Amination Reaction
Over the last two decades many different
auxiliary ligand systems
have been utilized in the copper-catalyzed Ullmann amination reaction.
However, there has been little consensus on the relative merits of
the varied ligands and the exact role they might play in the catalytic
process. Accordingly, in this work some of the most commonly employed
auxiliary ligands have been evaluated for C–N coupling using
reaction progress kinetic analysis (RPKA) methodology. The results
reveal not only the relative kinetic competencies of the different
auxiliary ligands but also their markedly different influences on
catalyst degradation rates. For the model Ullmann reaction between
piperidine and iodobenzene using the soluble organic base bis(tetra-<i>n</i>-butylphosphonium) malonate (TBPM) at room temperature, <i>N</i>-methylglycine was shown to give the best performance in
terms of high catalytic rate of reaction and comparatively low catalyst
deactivation rates. Further experimental and rate data indicate a
common catalytic cycle for all auxiliary ligands studied, although
additional off-cycle processes are observed for some of the ligands
(notably phenanthroline). The ability of the auxiliary ligand, base
(malonate dianion), and substrate (amine) to all act competitively
as ligands for the copper center is also demonstrated. On the basis
of these results an improved protocol for room-temperature copper-catalyzed
C–N couplings is presented with 27 different examples reported
Mechanistic Studies on the Copper-Catalyzed N‑Arylation of Alkylamines Promoted by Organic Soluble Ionic Bases
Experimental studies on the mechanism
of copper-catalyzed amination
of aryl halides have been undertaken for the coupling of piperidine
with iodobenzene using a Cu(I) catalyst and the organic base tetrabutylphosphonium
malonate (TBPM). The use of TBPM led to high reactivity and high conversion
rates in the coupling reaction, as well as obviating any mass transfer
effects. The often commonly employed O,O-chelating ligand 2-acetylcyclohexanone
was surprisingly found to have a negligible effect on the reaction
rate, and on the basis of NMR, calorimetric, and kinetic modeling
studies, the malonate dianion in TBPM is instead postulated to act
as an ancillary ligand in this system. Kinetic profiling using reaction
progress kinetic analysis (RPKA) methods show the reaction rate to
have a dependence on all of the reaction components in the concentration
range studied, with first-order kinetics with respect to [amine],
[aryl halide], and [Cu]<sub>total</sub>. Unexpectedly, negative first-order
kinetics in [TBPM] was observed. This negative rate dependence in
[TBPM] can be explained by the formation of an off-cycle copper(I)
dimalonate species, which is also argued to undergo disproportionation
and is thus responsible for catalyst deactivation. The key role of
the amine in minimizing catalyst deactivation is also highlighted
by the kinetic studies. An examination of the aryl halide activation
mechanism using radical probes was undertaken, which is consistent
with an oxidative addition pathway. On the basis of these findings,
a more detailed mechanistic cycle for the C–N coupling is proposed,
including catalyst deactivation pathways
Tetramethyl Orthosilicate (TMOS) as a Reagent for Direct Amidation of Carboxylic Acids
Tetramethyl orthosilicate
(TMOS) is shown to be an effective reagent
for direct amidation of aliphatic and aromatic carboxylic acids with
amines and anilines. The amide products are obtained in good to quantitative
yields in pure form directly after workup without the need for any
further purification. A silyl ester as the putative activated intermediate
is observed by NMR methods. Amidations on a 1 mol scale are demonstrated
with a favorable process mass intensity
Epimeric Face-Selective Oxidations and Diastereodivergent Transannular Oxonium Ion Formation Fragmentations: Computational Modeling and Total Syntheses of 12-Epoxyobtusallene IV, 12-Epoxyobtusallene II, Obtusallene X, Marilzabicycloallene C, and Marilzabicycloallene D
The total syntheses
of 12-epoxyobtusallene IV, 12-epoxyobtusallene
II, obtusallene X, marilzabicycloallene C, and marilzabicycloallene
D as halogenated C<sub>15</sub>-acetogenin 12-membered bicyclic and
tricyclic ether bromoallene-containing marine metabolites from <i>Laurencia</i> species are described. Two enantiomerically pure
C<sub>4</sub>-epimeric dioxabicyclo[8.2.1]tridecenes were synthesized
by <i>E</i>-selective ring-closing metathesis where their
absolute stereochemistry was previously set via catalytic asymmetric
homoallylic epoxidation and elaborated via regioselective epoxide-ring
opening and diastereoselective bromoetherification. Epimeric face-selective
oxidation of their Δ<sup>12,13</sup> olefins followed by bromoallene
installation allowed access to the oppositely configured 12,13-epoxides
of 12-epoxyobtusallene II and 12-epoxyobtusallene IV. Subsequent exploration
of their putative biomimetic oxonium ion formation–fragmentations
reactions revealed diastereodivergent pathways giving marilzabicycloallene
C and obtusallene X, respectively. The original configurations of
the substrates evidently control oxonium ion formation and their subsequent
preferred mode of fragmentation by nucleophilic attack at C<sub>9</sub> or C<sub>12</sub>. Quantum modeling of this stereoselectivity at
the ωB97X-D/Def2-TZVPPD/SCRF = methanol level revealed that
in addition to direction resulting from hydrogen bonding, the dipole
moment of the ion-pair transition state is an important factor. Marilzabicycloallene
D as a pentahalogenated 12-membered bicyclic ether bromoallene was
synthesized by a face-selective chloronium ion initiated oxonium ion
formation–fragmentation process followed by subsequent bromoallene
installation