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Understanding mAb aggregation during low pH viral inactivation and subsequent neutralization.

Ruben WälchliMariana RessurreiçãoSebastian VoggFabian FeidlJames M AngeloXuankuo XuSanchayita GhoseZheng-Jian LiXavier Le SaoûtJonathan SouquetHervé BrolyMassimo Morbidelli
Published in: Biotechnology and bioengineering (2019)
Monoclonal antibodies (mAbs) and related recombinant proteins continue to gain importance in the treatment of a great variety of diseases. Despite significant advances, their manufacturing can still present challenges owing to their molecular complexity and stringent regulations with respect to product purity, stability, safety, and so forth. In this context, protein aggregates are of particular concern due to their immunogenic potential. During manufacturing, mAbs routinely undergo acidic treatment to inactivate viral contamination, which can lead to their aggregation and thereby to product loss. To better understand the underlying mechanism so as to propose strategies to mitigate the issue, we systematically investigated the denaturation and aggregation of two mAbs at low pH as well as after neutralization. We observed that at low pH and low ionic strength, mAb surface hydrophobicity increased whereas molecular size remained constant. After neutralization of acidic mAb solutions, the fraction of monomeric mAb started to decrease accompanied by an increase on average mAb size. This indicates that electrostatic repulsion prevents denatured mAb molecules from aggregation under acidic pH and low ionic strength, whereas neutralization reduces this repulsion and coagulation initiates. Limiting denaturation at low pH by d-sorbitol addition or temperature reduction effectively improved monomer recovery after neutralization. Our findings might be used to develop innovative viral inactivation procedures during mAb manufacturing that result in higher product yields.
Keyphrases
  • monoclonal antibody
  • ionic liquid
  • sars cov
  • risk assessment
  • mass spectrometry
  • human health
  • single molecule
  • heavy metals
  • climate change
  • molecularly imprinted