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N-1 Perfusion Platform Development Using a Capacitance Probe for Biomanufacturing

Emily S. C. Rittershaus, Matthew S. Rehmann, Jianlin Xu, Qin He, Charles G. Hill, Jeffrey Swanberg, Michael Borys, Zheng Jian Li, Anurag Khetan

2022Bioengineering21 citationsDOIOpen Access PDF

Abstract

Fed-batch process intensification with a significantly shorter culture duration or higher titer for monoclonal antibody (mAb) production by Chinese hamster ovary (CHO) cells can be achieved by implementing perfusion operation at the N-1 stage for biomanufacturing. N-1 perfusion seed with much higher final viable cell density (VCD) than a conventional N-1 batch seed can be used to significantly increase the inoculation VCD for the subsequent fed-batch production (referred as N stage), which results in a shorter cell growth phase, higher peak VCD, or higher titer. In this report, we incorporated a process analytical technology (PAT) tool into our N-1 perfusion platform, using an in-line capacitance probe to automatically adjust the perfusion rate based on real-time VCD measurements. The capacitance measurements correlated linearly with the offline VCD at all cell densities tested (i.e., up to 130 × 106 cells/mL). Online control of the perfusion rate via the cell-specific perfusion rate (CSPR) decreased media usage by approximately 25% when compared with a platform volume-specific perfusion rate approach and did not lead to any detrimental effects on cell growth. This PAT tool was applied to six mAbs, and a platform CSPR of 0.04 nL/cell/day was selected, which enabled rapid growth and maintenance of high viabilities for four of six cell lines. In addition, small-scale capacitance data were used in the scaling-up of N-1 perfusion processes in the pilot plant and in the GMP manufacturing suite. Implementing a platform approach based on capacitance measurements to control perfusion rates led to efficient process development of perfusion N-1 for supporting high-density CHO cell cultures for the fed-batch process intensification.

Topics & Concepts

BiomanufacturingPerfusionCapacitanceChinese hamster ovary cellBiomedical engineeringCell cultureMaterials scienceChemistryBiologyMedicineBiotechnologyInternal medicineElectrodePhysical chemistryGeneticsViral Infectious Diseases and Gene Expression in InsectsProtein purification and stability3D Printing in Biomedical Research