Development of a Calibration Model for Real-Time Solute Concentration Monitoring during Crystallization of Ceritinib Using Raman Spectroscopy and In-Line Process Microscopy

Gavran, Matea; Ujević Andrijić, Željka; Bolf, Nenad; Rimac, Nikola; Sacher, Josip; Šahnić, Damir

doi:10.3390/pr11123439

Processes

2023

DOI: 10.3390/pr11123439

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Development of a Calibration Model for Real-Time Solute Concentration Monitoring during Crystallization of Ceritinib Using Raman Spectroscopy and In-Line Process Microscopy

Matea Gavran,

Željka Ujević Andrijić,

Nenad Bolf

et al.

Abstract: Raman spectroscopy is a useful tool for polymorphic form-monitoring during the crystallization process. However, its application to solute concentration estimation in two-phase systems like crystallization is rare, as the Raman signal is influenced by various changing factors in the crystallization process. The development of a robust calibration model that covers all variations is complex and represents a major challenge for the implementation of Raman spectroscopy for in-line monitoring and control of the so… Show more

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Cited by 2 publications

References 38 publications

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Applications of machine learning for modeling and advanced control of crystallization processes: Developments and perspectives

Lima,

de Moraes,

Barreto

et al. 2025

Digital Chemical Engineering

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Applications of machine learning for modeling and advanced control of crystallization processes: Developments and perspectives

Lima,

de Moraes,

Barreto

et al. 2025

Digital Chemical Engineering

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Batch Cooling Crystallization of a Model System Using Direct Nucleation Control and High-Performance In Situ Microscopy

Budimir Sacher,

Bolf,

Sejdić

2024

Crystals

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The aim of this study was to investigate the use of automated high performance in situ microscopy (HPM) for monitoring and direct nucleation control (DNC) during cooling crystallization. Compared to other techniques, HPM enables the detection of small crystals in the range of 1 to 10 μm. Therefore, a novel DNC-controlled variable was investigated to determine the potential improvement of the method. The laboratory system and process control software were developed in-house. A well-studied crystallization model system, the seeded batch cooling crystallization of α-glycine from water, was investigated under normal conditions and temperatures below 60 °C. It was postulated that length-weighted edge-to-edge counts in the range of 1 to 10 μm would be most sensitive to the onset of secondary nucleation and are therefore, used as a control variable. Linear cooling experiments were conducted to determine the initial setpoint for the DNC experiments. Three DNC experiments were then performed with different setpoints and an upper and lower counts limit. It was found that the DNC method can be destabilized with a low setpoint and narrow counts limits. In addition, the new controlled variable is highly sensitive to the formation of bubbles at the microscope window and requires careful evaluation. To address the advantages of the DNC method, an additional linear cooling experiment of the same duration was performed, and it was found that the DNC method resulted in a larger average crystal size. Overall, it can be concluded that the HPM method is suitable for DNC control and could be improved by modifying the image processing algorithm.

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Development of a Calibration Model for Real-Time Solute Concentration Monitoring during Crystallization of Ceritinib Using Raman Spectroscopy and In-Line Process Microscopy

Cited by 2 publications

References 38 publications

Applications of machine learning for modeling and advanced control of crystallization processes: Developments and perspectives

Applications of machine learning for modeling and advanced control of crystallization processes: Developments and perspectives

Batch Cooling Crystallization of a Model System Using Direct Nucleation Control and High-Performance In Situ Microscopy

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