The experimental approach taken and challenges overcome in developing a high-purity production (>100 g) scale process for the telescoped synthesis of the antibiotic ciprofloxacin is outlined. The process was first optimized for each step sequentially with regard to purity and yield, with necessary process changes identified and implemented before scaling for longer runs. These changes included implementing a continuous liquid−liquid extraction (CLLE) step and eliminating and replacing the base 1,8- diazabicyclo[5.4.0]undec-7-ene (DBU) initially used in the ring-closure step due to DBU plausibly forming a decomposition side product that negatively impacted the final product purity. Process conditions were scaled 1.5−2-fold in order to enable the ultimate project goal of producing enough crude ciprofloxacin within 24 h to manufacture 1000 250 mg tablets. Working toward this goal, several production-scale runs were carried out to assess the reproducibility and robustness of the finalized process conditions, with the first three steps being run continuously up to 22 h and the last two steps being run continuously up to 10 h. The end result is a process with a throughput of ∼29 g/h (∼700 g/24 h) with a crude product stream profile of 94 ± 2% and 34 ± 3 mg/mL after five chemical transformations across four reactors and one continuous CLLE unit operation with each intermediate step maintaining a purity >95% by HPLC.

• Massachusetts Institute of Technology (MIT) (MIT)
• Virginia Commonwealth University

• PAT
• Oral solid dose

1. Continuous liquid-liquid extraction
2. continuous pharmaceutical manufacturing
3. Design of experiments
4. flow chemistry
5. oral solid dose
6. pat
7. Research Article