
Flowing Towards Online HPLC
The adoption of true, online HPLC is impeded by the real-world requirements of implementation. Notably, samples for HPLC analysis must be removed from the reaction mixture, quenched and diluted before initiating analysis. There are numerous physical and engineering issues associated with these steps that cause online application to be problematic. In this work, the authors report and demonstrate that DirectInject-LC technology mitigates these issues. In a first-time demonstration, a photocatalytic reaction that is performed both in batch and continuous flow is analyzed in real-time by online HPLC PAT.
A photoredox C−N coupling reaction between 4-bromobenzotrifluoride and pyrrolidine, catalyzed by Ru(bpy)₃(PF₆)₂ and NiBr₂·3H₂O was selected as a model reaction and performed initially in an EasyMax™ batch reactor with irradiation through the reactor window. Both EasySampler™ and ReactIR™ probes were inserted into the reaction vessel in order to collect both HPLC and FTIR data for tracking starting material and product. DirectInject-LC provided a liquid chromatography data point every 7.5 minutes; the IR data point was accumulated every 30 seconds and strong correlation between the data from both techniques was observed. Next, the EasySampler probe was adapted for flow measurements using a custom designed flow cell arrangement. The reaction was performed using a Vapourtec UV-150 plug flow photoreactor using a 405 nm LED array. The reaction was first performed using different residence times from 1-60 minutes holding the temperature constant at 35 °C.
It was determined that residence times greater than 30 minutes yielded conversion greater than 95%. The authors commented that due to the online HPLC there was no need to stop and resume the flow, which permitted real-time monitoring for each tested condition and minimized resource-intensive use of both time and materials. Varying reaction temperature was also evaluated and using a residence time of 5 minutes at a temperature of 60 °C provided an accelerated reaction rate while maintaining excellent conversion.
The authors commented that “The DILC™ system has demonstrated significant effectiveness in flow reactions by facilitating reaction optimization, enhancing sustainability, and minimizing human intervention. Furthermore, the DILC™ has proven to be an excellent online tool for calibrating spectroscopic data. This innovative methodology not only streamlines analytical workflows but also lays the groundwork for future advancements in automated in-process control (IPC) technologies.”
Qin, Y., Ayesa, U., Lévesque, F., & Ji, Y. (2025). Novel Application of Direct Inject Liquid Chromatography (DILC™) as Real-time Process Analytical Technology for Flow Reactions. ChemRxiv. https://doi.org/10.26434/chemrxiv-2025-c3680









