Computationally-Guided Development of a Chelated NHC-P Iridium(I) Complex for the Directed Hydrogen Isotope Exchange of Aryl Sulfones | Zendy

William J. Kerr | Zendy; Gary J. Knox | Zendy; Marc Reid | Zendy; Tell Tuttle | Zendy; Jonas Bergare | Zendy; Ryan A. Bragg | Zendy

Open Access

Computationally-Guided Development of a Chelated NHC-P Iridium(I) Complex for the Directed Hydrogen Isotope Exchange of Aryl Sulfones

Author(s) -

William J. Kerr,

Gary J. Knox,

Marc Reid,

Tell Tuttle,

Jonas Bergare,

Ryan A. Bragg

Publication year - 2020

Publication title -

acs catalysis

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 4.898

H-Index - 198

ISSN - 2155-5435

DOI - 10.1021/acscatal.0c03031

Subject(s) - iridium , phosphine , catalysis , rational design , aryl , combinatorial chemistry , chemistry , deuterium , ligand (biochemistry) , chelation , organic chemistry , nanotechnology , materials science , biochemistry , alkyl , physics , receptor , quantum mechanics

Herein, we report the rational, computationally-guided design of an iridium(I) catalyst system capable of enabling directed hydrogen isotope exchange (HIE) with the challenging sulfone directing group. Substrate binding energy was used as a parameter to guide rational ligand design via an in silico catalyst screen, resulting in a lead series of chelated iridium(I) NHC-phosphine complexes. Subsequent preparative studies show that the optimal catalyst system displays high levels of activity in HIE, and we demonstrate the labeling of a broad scope of substituted aryl sulfones. We also show that the activity of the catalyst is maintained at low pressures of deuterium gas and apply these conditions to tritium radiolabeling, including the expedient synthesis of a tritium-labeled drug molecule.

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