A key pharmaceutical intermediate (1) for production of edivoxetine•HCl was prepared in >99% ee via a continuous Barbier reaction, which improves the greenness of the process relative to a traditional Grignard batch process. The Barbier flow process was run optimally by Eli Lilly and Company in a series of continuous stirred tank reactors (CSTR) where residence times, solvent composition, stoichiometry, and operations temperature were optimized to produce 12 g h −1 crude ketone 6 with 98% ee and 88% in situ yield for 47 hours total flow time. Continuous salt formation and isolation of intermediate 1 from the ketone solution was demonstrated at 89% yield, >99% purity, and 22 g h −1 production rates using MSMPRs in series for 18 hours total flow time. Key benefits to this continuous approach include greater than 30% reduced process mass intensity and magnesium usage relative to a traditional batch process. In addition, the flow process imparts significant process safety benefits for Barbier/Grignard processes including >100× less excess magnesium to quench, >100× less diisobutylaluminum hydride to initiate, and in this system, maximum long-term scale is expected to be 50 L which replaces 4000-6000 L batch reactors.
A flow Barbier process
was developed to produce a key intermediate
in the edivoxetine·HCl registered sequence. The control strategy
was developed based on a critical understanding of integrated parameters
and design space requirements for a continuous stirred tank reactor
(CSTR) process. In this flow Barbier process, the Grignard reagent
formation and reaction occurs in a single CSTR, with quenching of
the resulting tetrahedral intermediate in a second CSTR. Real time
Process Analytical Technology (PAT) monitoring was used to assist
process development and understanding. The postquench liquid–liquid
separation was continuous, and the quenched intermediate flowed directly
into a neutralization CSTR to minimize the epimerization potential
of the quenched intermediate. The optimized process was run for 80
consecutive hours in 2 L CSTRs where magnesium was recharged every
4 h for the first half of the continuous campaign and every 8 h for
the second half with no quantifiable differences in performance. The
Barbier process delivered in situ >99% ee which
is
sufficient for telescoping into the next step. The process development
is intended to support a Quality by Design (Qbd) regulatory submission.
Efficient continuous
Grignard and lithiation processes were developed
to produce one of the key regulatory starting materials for the production
of edivoxetine hydrochoride. For the Grignard process, organometallic
reagent formation, Bouveault formylation, reduction, and workup steps
were run in continuous stirred tank reactors (CSTRs). The lithiation
utilized a hybrid approach where plug flow reactors (PFRs) were used
for the metal halogen exchange and Bouveault formylation steps, while
the reduction and workup steps were performed in CSTRs. Relative to
traditional batch processing, both approaches offer significant advantages.
Both processes were high-yielding and produced the product in high
purity. The two main processes were directly compared from a number
of perspectives including reagent and operational safety, fouling
potential, process footprint, need for manual operation, and product
yield and purity.
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