A wide range of halogenated bicyclo[1.1.1]pentanes are accessed by functional group tolerant radical ring-opening of tricyclo[1.1.1.01,3]pentane, using triethylborane as initiator.
A computationally guided development of the first efficient protocol to trifluoromethylthiolate aryl and vinyl Csp2–O bonds is presented, showcasing important reactivity requirements for the introduction of potentially reactive functional groups under homogeneous Ni-catalysis.
We herein showcase the ability of NHC‐coordinated dinuclear NiI–NiI complexes to override fundamental reactivity limits of mononuclear (NHC)Ni0 catalysts in cross‐couplings. This is demonstrated with the development of a chemoselective trifluoromethylselenolation of aryl iodides catalyzed by a NiI dimer. A novel SeCF3‐bridged NiI dimer was isolated and shown to selectively react with Ar−I bonds. Our computational and experimental reactivity data suggest dinuclear NiI catalysis to be operative. The corresponding Ni0 species, on the other hand, suffers from preferred reaction with the product, ArSeCF3, over productive cross‐coupling and is hence inactive.
A stereoselective one-pot synthesis of spiropyrazolones through an organocatalytic
asymmetric Michael addition and a formal Conia-ene reaction has been developed.
Depending on the nitroalkene, the 5-exo-dig-cyclization could be achieved by
silver-catalyzed alkyne activation or by oxidation of the intermediate enolate. The
mechanistic pathways have been investigated using computational chemistry and
mechanistic experiments.
The advent of total-body Positron EmissionTomography (PET) has vastly broadened the range of research and clinical applications of this powerful molecular imaging technology. 1 Such possibilities have accelerated progress in 18 F-radiochemistry with numerous methods available to 18 F-label (hetero)arenes and alkanes. 2 However, access to 18 F-difluoromethylated molecules in high molar activity (Am) is largely an unsolved problem, despite the indispensability of the difluoromethyl group for pharmaceutical drug discovery. 3 We report herein a general solution by introducing carbene chemistry to the field of nuclear imaging with a [ 18 F]difluorocarbene reagent capable of a myriad of 18 F-difluoromethylation processes. In contrast to the tens of known difluorocarbene reagents, this 18 F-reagent is carefully designed for facile accessibility, high molar activity and versatility. The issue of Am is solved using an assay examining the likelihood of isotopic dilution upon variation of the electronics of the difluorocarbene precursor. Versatility is demonstrated with multiple [ 18 F]difluorocarbene based reactions including O-H, S-H and N-H insertions, and cross-couplings that harness the reactivity of ubiquitous functional groups such as (thio)phenols, N-heteroarenes, and aryl boronic acids that are easy to install. Impact is illustrated with the labelling of highly complex and functionalised biologically relevant molecules and radiotracers.
Asymmetric catalytic azidation has increased in importance to access enantioenriched nitrogen containing molecules, but methods that employ inexpensive sodium azide remain scarce. This encouraged us to undertake a detailed study on the application of hydrogen bonding phase-transfer catalysis (HB-PTC) to enantioselective azidation with sodium azide. So far, this phase-transfer manifold has been applied exclusively to insoluble metal alkali fluorides for carbon−fluorine bond formation. Herein, we disclose the asymmetric ring opening of meso aziridinium electrophiles derived from β-chloroamines with sodium azide in the presence of a chiral bisurea catalyst. The structure of novel hydrogen bonded azide complexes was analyzed computationally, in the solid state by X-ray diffraction, and in solution phase by 1 H and 14 N/ 15 N NMR spectroscopy. With N-isopropylated BINAMderived bisurea, end-on binding of azide in a tripodal fashion to all three NH bonds is energetically favorable, an arrangement reminiscent of the corresponding dynamically more rigid trifurcated hydrogen-bonded fluoride complex. Computational analysis informs that the most stable transition state leading to the major enantiomer displays attack from the hydrogen-bonded end of the azide anion. All three H-bonds are retained in the transition state; however, as seen in asymmetric HB-PTC fluorination, the H-bond between the nucleophile and the monodentate urea lengthens most noticeably along the reaction coordinate. Kinetic studies corroborate with the turnover rate limiting event resulting in a chiral ion pair containing an aziridinium cation and a catalyst-bound azide anion, along with catalyst inhibition incurred by accumulation of NaCl. This study demonstrates that HB-PTC can serve as an activation mode for inorganic salts other than metal alkali fluorides for applications in asymmetric synthesis.
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