Above a concentration threshold, the viscosity of solutions
of
proteins increases abruptly, which hampers the injectability of therapeutic
formulations. Concentrations above 200 g/L are an ideal goal for subcutaneous
application of antibodies. Molecular additives, such as amino acids
(e.g., arginine) help decrease the viscosity, but they are used at
concentrations as high as about 200 mmol/L. We addressed the question
of whether poly(amino acids) could be more efficient than small molecular
additives. We observed marked fluidification of a model therapeutic
monoclonal antibody (mAb) solution by poly(d,l-glutamic
acid) and poly(l-glutamic acid) derivatives added at concentrations
of <6.5 g/L (i.e., a mAb/polymer chain molar ratio
between 4:1 and 1:1 mol/mol). The bare poly(glutamate) parent chains
were compared with polyethylene glycol-grafted chains as PEGylation
is a common way to enhance stability. Viscosity could be decreased
to ∼20 mPa s as compared to values of ∼100 mPa s in
the absence of polymers at 200 g/L mAb. Formation of complexes between
the mAb and the polyglutamates was characterized by capillary electrophoresis
analysis in dilute solutions (1 g/L mAb) and by observation of phase
separation at higher concentrations, suggesting tight association
at about 2:1 mol/mol mAb/polymer. Altogether, these results show that
polyglutamate derivatives hold an untapped potential as an excipient
for fluidification of concentrated protein solutions.