posted on 2022-11-22, 21:29authored byMohammad
H. Samha, Julie L. H. Wahlman, Jacquelyne A. Read, Jacob Werth, Eric N. Jacobsen, Matthew S. Sigman
Hydrogen bond-based organocatalysts
rely on networks
of attractive
noncovalent interactions (NCIs) to impart enantioselectivity. As a
specific example, aryl pyrrolidine substituted urea, thiourea, and
squaramide organocatalysts function cooperatively through hydrogen
bonding and difficult-to-predict NCIs as a function of the reaction
partners. To uncover the synergistic effect of the structural components
of this catalyst class, we applied data science tools to study various
model reactions using a derivatized, aryl pyrrolidine-based, hydrogen-bond
donor (HBD) catalyst library. Through a combination of experimentally
collected data and data mined from previous reports, statistical models
were constructed, illuminating the general features necessary for
high enantioselectivity. A distinct dependence on the identity of
the electrophilic reaction partner and HBD catalyst is observed, suggesting
that a general interaction is conserved throughout the reactions analyzed.
The resulting models also demonstrate predictive capability by the
successful improvement of a previously reported reaction using out-of-sample
reaction components. Overall, this study highlights the power of data
science in exploring mechanistic hypotheses in asymmetric HBD catalysis
and provides a prediction platform applicable in future reaction optimization.