Kinetic Modeling and Validation of Palladium-Catalyzed Reductive Carbonylation

Heteroaryl aldehydes serve as critical intermediates in the synthesis of biologically active compounds. The Pd-catalyzed formylation of aryl bromides has become a notably efficient method to produce carbonyl compounds among several other available methods. In reductive carbonylation processes, carbon monoxide (CO) is combined with a hydrogen donor, such as silyl or tin hydrides, or formate salts, to facilitate formylation. Among the various sources of CO and hydrogen for achieving formylation, synthesis gas (syngas, CO/H2) stands out as an environmentally friendly and atom-efficient option due to its accessibility and cost-effectiveness. While several aryl bromides have been successfully carbonylated using syngas, certain heteroaryl bromides pose challenges due to their propensity to undergo reductive dehalogenation.

In this study, we demonstrate the application of Pd-catalyzed syngas carbonylation for the synthesis of a Boehringer’s advanced API intermediate. During the process development, it was deemed essential to minimize the formation of dehalogenated byproduct during the syngas-mediated carbonylation. To achieve this, we developed a mechanism-based kinetic model using Reaction Lab software, which was employed to generate in-silico predictions aimed at reducing ArH. These predictions were subsequently validated through experimentation and further employed in the multi-kilo scale production of API.

• Discover how to build and validate a kinetic model that supports large-scale synthesis of drug substances.
• Understand the role of predictive technologies and artificial intelligence in optimizing reaction outcomes and catalyst development.
• Learn about the use of high-throughput screening and multivariate modeling to enhance reaction conditions and yields.
• Gain insights into transitioning reactions from lab scale to multi-kilogram scale while ensuring high selectivity and yield.