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Treffer: Data-Driven Multi-Objective Optimization Tactics for Catalytic Asymmetric Reactions Using Bisphosphine Ligands

Title:
Data-Driven Multi-Objective Optimization Tactics for Catalytic Asymmetric Reactions Using Bisphosphine Ligands
Authors:
Jordan J. Dotson (9017687), Lucy van Dijk (14305678), Jacob C. Timmerman (5412011), Samantha Grosslight (6889559), Richard C. Walroth (1414450), Francis Gosselin (1442914), Kurt Püntener (1702408), Kyle A. Mack (3595676), Matthew S. Sigman (1306671)
Publication Year:
1753
Subject Terms:
Biophysics, Biochemistry, Genetics, Molecular Biology, Biotechnology, Immunology, Plant Biology, Computational Biology, Biological Sciences not elsewhere classified, Information Systems not elsewhere classified, machine learning workflow, identify active catalysts, g ., yield, density functional theory, active pharmaceutical ingredient, significantly improved ligands, model reaction selectivity, 550 bisphosphine ligands, objective optimization tactics, bisphosphine ligands, objective optimization, reaction outputs, reaction optimizations, readily implemented, linear regression, general strategy, formidable challenge, derived database, catalytic reactions
Document Type:
Fachzeitschrift article in journal/newspaper
Language:
unknown
Relation:
https://figshare.com/articles/journal_contribution/Data-Driven_Multi-Objective_Optimization_Tactics_for_Catalytic_Asymmetric_Reactions_Using_Bisphosphine_Ligands/21785485
DOI:
10.1021/jacs.2c08513.s003
Availability:
https://doi.org/10.1021/jacs.2c08513.s003
Rights:
CC BY-NC 4.0
Accession Number:
edsbas.A26274A1
Database:
BASE

Weitere Informationen

Optimization of the catalyst structure to simultaneously improve multiple reaction objectives (e.g., yield, enantioselectivity, and regioselectivity) remains a formidable challenge. Herein, we describe a machine learning workflow for the multi-objective optimization of catalytic reactions that employ chiral bisphosphine ligands. This was demonstrated through the optimization of two sequential reactions required in the asymmetric synthesis of an active pharmaceutical ingredient. To accomplish this, a density functional theory-derived database of >550 bisphosphine ligands was constructed, and a designer chemical space mapping technique was established. The protocol used classification methods to identify active catalysts, followed by linear regression to model reaction selectivity. This led to the prediction and validation of significantly improved ligands for all reaction outputs, suggesting a general strategy that can be readily implemented for reaction optimizations where performance is controlled by bisphosphine ligands.