Abstract
There has been an increasing interest in the use of automated self-optimising continuous flow platforms for the development and manufacture in synthesis in recent years. Such processes include multiple reactive and work-up steps, which need to be efficiently optimised. Here, we report the combination of multi-objective optimisation based on machine learning methods (TSEMO algorithm) with self-optimising platforms for the optimisation of multi-step continuous reaction processes. This is demonstrated for a pharmaceutically relevant Sonogashira reaction. We demonstrate how optimum reaction conditions are re-evaluated with the changing downstream work-up specifications in the active learning process. Furthermore, a Claisen-Schmidt condensation reaction with subsequent liquid-liquid separation was optimised with respect to three-objectives. This approach provides the ability to simultaneously optimise multi-step processes with respect to multiple objectives, and thus has the potential to make substantial savings in time and resources.
Highlights
Since the industrial revolution, the use of mechanised tools to improve manufacturing processes has been a predominant feature in many areas of technology
The ability of self-optimisation to efficiently identify optimal operating conditions in a multivariate parameter space has presented many opportunities for more efficient process development. Such advantages align with the rising interest in continuous flow chemistry towards the ‘greener’ synthesis of active pharmaceutical ingredients (APIs), and offer the potential to reduce the drug development timeline [6,7,8]
The motivations for transferring this step to flow included: (i) TMS-propyne could be safely exchanged for propyne gas, removing the need for additional additives; (ii) downstream lithiation/borylation chemistry is well suited for flow which would enable a telescoped synthesis, providing a significant manufacturing cost saving; (iii) precise control of reaction parameters in flow would give more consistent product quality [37]
Summary
The use of mechanised tools to improve manufacturing processes has been a predominant feature in many areas of technology. The majority of self-optimisation applications to date have focused on single-objective optimisation of single-step reactions, utilising the following algorithms: model-based design of experiments [10,11,12], SNOBFIT [13,14,15,16], Nelder-Mead SIMPLEX or variations thereof [17,18,19,20,21,22,23] These algorithms are not data-efficient as they do not utilise all the available experimental data to build a global surrogate model. We describe the application of this methodology to: (i) a pharmaceutically relevant Sonogashira reaction; (ii) a multi-step Claisen-Schmidt condensation reaction with in-line liquid–liquid extraction
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