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Elucidating and Optimizing the Photochemical Mechanism of Coumarin-Caged Tertiary Amines.

Sambashiva BanalaXiao-Tao JinTanya L DilanShu-Hsien SheuDavid E ClaphamRyan M DrenanLuke D Lavis
Published in: Journal of the American Chemical Society (2024)
Photoactivatable or "caged" pharmacological agents combine the high spatiotemporal specificity of light application with the molecular specificity of drugs. A key factor in all optopharmacology experiments is the mechanism of uncaging, which dictates the photochemical quantum yield and determines the byproducts produced by the light-driven chemical reaction. In previous work, we demonstrated that coumarin-based photolabile groups could be used to cage tertiary amine drugs as quaternary ammonium salts. Although stable, water-soluble, and useful for experiments in brain tissue, these first-generation compounds exhibit relatively low uncaging quantum yield (Φ u < 1%) and release the toxic byproduct formaldehyde upon photolysis. Here, we elucidate the photochemical mechanisms of coumarin-caged tertiary amines and then optimize the major pathway using chemical modification. We discovered that the combination of 3,3-dicarboxyazetidine and bromine substituents shift the mechanism of release to heterolysis, eliminating the formaldehyde byproduct and giving photolabile tertiary amine drugs with Φ u > 20%─a 35-fold increase in uncaging efficiency. This new "ABC" cage allows synthesis of improved photoactivatable derivatives of escitalopram and nicotine along with a novel caged agonist of the oxytocin receptor.
Keyphrases
  • water soluble
  • fluorescent probe
  • molecular dynamics
  • ionic liquid
  • room temperature
  • drinking water
  • drug induced
  • resting state
  • single molecule
  • functional connectivity
  • quantum dots
  • energy transfer