• Towards an improved prediction of concentrated antibody solution viscosity using the Huggins coefficient.

      Roche, Aisling; Gentiluomo, Lorenzo; Sibanda, Nicole; Roessner, Dierk; Friess, Wolfgang; Trainoff, Steven P; Curtis, Robin; email: r.curtis@manchester.ac.uk (2021-09-04)
      The viscosity of a monoclonal antibody solution must be monitored and controlled as it can adversely affect product processing, packaging and administration. Engineering low viscosity mAb formulations is challenging as prohibitive amounts of material are required for concentrated solution analysis, and it is difficult to predict viscosity from parameters obtained through low-volume, high-throughput measurements such as the interaction parameter, k , and the second osmotic virial coefficient, B . As a measure encompassing the effect of intermolecular interactions on dilute solution viscosity, the Huggins coefficient, k , is a promising candidate as a parameter measureable at low concentrations, but indicative of concentrated solution viscosity. In this study, a differential viscometry technique is developed to measure the intrinsic viscosity, [η], and the Huggins coefficient, k , of protein solutions. To understand the effect of colloidal protein-protein interactions on the viscosity of concentrated protein formulations, the viscometric parameters are compared to k and B of two mAbs, tuning the contributions of repulsive and attractive forces to the net protein-protein interaction by adjusting solution pH and ionic strength. We find a strong correlation between the concentrated protein solution viscosity and the k but this was not observed for the k or the b , which have been previously used as indicators of high concentration viscosity. Trends observed in [η] and k values as a function of pH and ionic strength are rationalised in terms of protein-protein interactions. [Abstract copyright: Copyright © 2021. Published by Elsevier Inc.]