Digital twin of a continuous chromatography process for mAb purification: Design and model‐based control

Tiwari, Arvind; Masampally, Vishnu Swaroopji; Agarwal, Anshul; Rathore, Anurag S.

doi:10.1002/bit.28307

Cited by 6 publications

(3 citation statements)

References 36 publications

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“…In recent years, with the maturation of the first principle model for IEC, process development based on the mechanistic model has become increasingly common (Babi et al, 2022; Chen, Yao, et al, 2022; Hahn et al, 2015; Osberghaus et al, 2012; Pirrung et al, 2017), which can not only save a significant amount of wet experiments but also yield higher purity and recovery compared to traditional optimization methods such as the design of experiments. Furthermore, mechanistic models have found applications in real‐time process control (Gomis‐Fons et al, 2020; Rischawy et al, 2022, 2023; Tiwari et al, 2023). By connecting the mechanistic models to the input and output of different steps (such as protein capture, polishing, pH adjustment, etc.…”

Section: Introductionmentioning

confidence: 99%

Realization of digital twin for dynamic control toward sample variation of ion exchange chromatography in antibody separation

Shi,

Chen,

Zhong

et al. 2024

Biotech & Bioengineering

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Digital twin (DT) is a virtual and digital representation of physical objects or processes. In this paper, this concept is applied to dynamic control of the collection window in the ion exchange chromatography (IEC) toward sample variations. A possible structure of a feedforward model‐based control DT system was proposed. Initially, a precise IEC mechanistic model was established through experiments, model fitting, and validation. The average root mean square error (RMSE) of fitting and validation was 8.1% and 7.4%, respectively. Then a model‐based gradient optimization was performed, resulting in a 70.0% yield with a remarkable 11.2% increase. Subsequently, the DT was established by systematically integrating the model, chromatography system, online high‐performance liquid chromatography, and a server computer. The DT was validated under varying load conditions. The results demonstrated that the DT could offer an accurate control with acidic variants proportion and yield difference of less than 2% compared to the offline analysis. The embedding mechanistic model also showed a positive predictive performance with an average RMSE of 11.7% during the DT test under >10% sample variation. Practical scenario tests indicated that tightening the control target could further enhance the DT robustness, achieving over 98% success rate with an average yield of 72.7%. The results demonstrated that the constructed DT could accurately mimic real‐world situations and perform an automated and flexible pooling in IEC. Additionally, a detailed methodology for applying DT was summarized.

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Section: Introductionmentioning

confidence: 99%

Realization of digital twin for dynamic control toward sample variation of ion exchange chromatography in antibody separation

Shi,

Chen,

Zhong

et al. 2024

Biotech & Bioengineering

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show abstract

“…The development of these digital solutions becomes an important part of the process development and needs to be accounted for early in the development chain. Lab-scale automated continuous bioprocesses have been reported (Steinebach et al 2017, Feidl et al 2020, Gomis-Fons et al 2020B, Rathore et al 2021, Schwartz et al 2022, Tiwari et al 2022. The software used in these experimental platforms were very different from locally developed PLC to commercial process automation SCADA systems.…”

Section: Introductionmentioning

confidence: 99%

Methodology for fast development of digital solutions in integrated continuous downstream processing

Nilsson¹,

Andersson²,

Gomis-Fons³

et al. 2023

Preprint

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The methodology for production of biologics is going through a paradigm shift from batch-wise operation to continuous production. Lot of efforts are focused on integration, intensification and continuous operation for decreased foot-print, material, equipment and increased productivity and product quality. These integrated continuous processes with on-line analytics becomes complex processes, which requires automation, monitoring and control of the operation, even unmanned or remote, which means bioprocesses with high level of automation or even autonomous capabilities. The development of these digital solutions becomes an important part of the process development and needs to be assessed early in the development chain. This work discusses a platform that allow fast development, advanced studies and validation of digital solutions for integrated continuous downstream processes. It uses an open, flexible and extendable real-time supervisory controller, called Orbit, developed in Python. Orbit makes it possible to communicate with a set of different physical setups and on the same time perform real-time execution. Integrated continuous processing often imply parallel operation of several setups and network of Orbit controllers makes it possible to synchronize complex process system. Data handling, storage and analysis are important properties for handling heterogeneous and asynchronous data generated in complex downstream systems. Digital twin applications, such as advanced model-based and plant-wide monitoring and control, are exemplified using computational extensions in Orbit, exploiting data and models. Examples of novel digital solutions in integrated downstream processes are automatic operation parameter optimization, Kalman filter monitoring and model-based batch-to-batch control.

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“…The development of these digital solutions becomes an important part of the process development and needs to be accounted for early in the development chain. Lab‐scale automated continuous bioprocesses have been reported (Feidl et al, 2020; Gomis‐Fons et al, 2020, Gomis‐Fons, Schwarz, et al, 2020; Rathore et al, 2021; Schwarz et al, 2022; Steinebach et al, 2017; Tiwari et al, 2022). The software used in these experimental platforms were very different, ranking from locally developed PLC to commercial process automation SCADA systems.…”

Section: Introductionmentioning

confidence: 99%

Methodology for fast development of digital solutions in integrated continuous downstream processing

Andersson

Gomis-Fons

Isaksson

et al. 2023

Biotech & Bioengineering

View full text Add to dashboard Cite

The methodology for production of biologics is going through a paradigm shift from batch‐wise operation to continuous production. Lot of efforts are focused on integration, intensification, and continuous operation for decreased foot‐print, material, equipment, and increased productivity and product quality. These integrated continuous processes with on‐line analytics become complex processes, which requires automation, monitoring, and control of the operation, even unmanned or remote, which means bioprocesses with high level of automation or even autonomous capabilities. The development of these digital solutions becomes an important part of the process development and needs to be assessed early in the development chain. This work discusses a platform that allows fast development, advanced studies, and validation of digital solutions for integrated continuous downstream processes. It uses an open, flexible, and extendable real‐time supervisory controller, called Orbit, developed in Python. Orbit makes it possible to communicate with a set of different physical setups and on the same time perform real‐time execution. Integrated continuous processing often implies parallel operation of several setups and network of Orbit controllers makes it possible to synchronize complex process system. Data handling, storage, and analysis are important properties for handling heterogeneous and asynchronous data generated in complex downstream systems. Digital twin applications, such as advanced model‐based and plant‐wide monitoring and control, are exemplified using computational extensions in Orbit, exploiting data and models. Examples of novel digital solutions in integrated downstream processes are automatic operation parameter optimization, Kalman filter monitoring, and model‐based batch‐to‐batch control.

show abstract

Digital twin of a continuous chromatography process for mAb purification: Design and model‐based control

Cited by 6 publications

References 36 publications

Realization of digital twin for dynamic control toward sample variation of ion exchange chromatography in antibody separation

Realization of digital twin for dynamic control toward sample variation of ion exchange chromatography in antibody separation

Methodology for fast development of digital solutions in integrated continuous downstream processing

Methodology for fast development of digital solutions in integrated continuous downstream processing

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