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Mechanistic modeling,simulation, and optimization of mixed-mode chromatography for an antibody polishing step |
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| Authors: | Tobias Hahn Nora Geng Katerina Petrushevska-Seebach Michael E. Dolan Marcus Scheindel Pia Graf Kosuke Takenaka Kyo Izumida Lijuan Li Zijian Ma Norbert Schuelke |
| Affiliation: | 1. GoSilico GmbH, Karlsruhe, Germany;2. GoSilico GmbH, Karlsruhe, Germany Contribution: Conceptualization (equal), Data curation (equal), Formal analysis (equal), Methodology (equal), Validation (equal), Writing - review & editing (equal);3. Takeda Pharmaceuticals, Vienna, Austria Contribution: Conceptualization (equal), Methodology (equal), Project administration (equal), Supervision (equal), Validation (equal), Writing - review & editing (equal);4. Takeda Pharmaceuticals, Lexington, Massachusetts, USA Contribution: Investigation (equal), Resources (equal), Validation (equal), Writing - review & editing (equal);5. Takeda Pharmaceuticals, Orth an der Donau, Austria Contribution: Validation (equal);6. GoSilico GmbH, Karlsruhe, Germany Contribution: Formal analysis (equal);7. Takeda Pharmaceuticals, Vienna, Austria Contribution: Validation (equal), Writing - review & editing (equal);8. Takeda Pharmaceuticals, Fujisawa, Kanagawa, Japan Contribution: Validation (equal), Writing - review & editing (equal);9. Takeda Pharmaceuticals, Lexington, Massachusetts, USA Contribution: Project administration (equal), Validation (equal), Writing - review & editing (equal);10. Takeda Pharmaceuticals, Lexington, Massachusetts, USA Contribution: Investigation (equal);11. Takeda Pharmaceuticals, Lexington, Massachusetts, USA Contribution: Funding acquisition (equal), Supervision (equal), Writing - review & editing (equal) |
| Abstract: | Mixed-mode chromatography combines features of ion-exchange chromatography and hydrophobic interaction chromatography and is increasingly used in antibody purification. As a replacement for flow-through operations on traditional unmixed resins or as a pH-controlled bind-and-elute step, the use of both interaction modes promises a better removal of product-specific impurities. However, the combination of the functionalities makes industrial process development significantly more complex, in particular the identification of the often small elution window that delivers the desired selectivity. Mechanistic modeling has proven that even difficult separation problems can be solved in a computer-optimized manner once the process dynamics have been modeled. The adsorption models described in the literature are also very complex, which makes model calibration difficult. In this work, we approach this problem with a newly constructed model that describes the adsorber saturation with the help of the surface coverage function of the colloidal particle adsorption model for ion-exchange chromatography. In a case study, a model for a pH-controlled antibody polishing step was created from six experiments. The behavior of fragments, aggregates, and host cell proteins was described with the help of offline analysis. After in silico optimization, a validation experiment confirmed an improved process performance in comparison to the historical process set point. In addition to these good results, the work also shows that the high dynamics of mixed-mode chromatography can produce unexpected results if process parameters deviate too far from tried and tested conditions. |
| Keywords: | antibody purification colloidal particle adsorption model mechanistic modeling mixed-mode chromatography process optimization |