posted on 2018-06-04, 00:00authored byNa Yang, Qing Tang, Ping Hu, Michael J. Lewis
Major
degradation pathways such as deamidation, isomerization,
oxidation, and glycation may be accelerated after administration of
antibody therapeutics to the patient. Tracking in vivo product degradation
is important because certain post-translational modifications can
inactivate the protein and reduce product efficacy. However, in vivo
characterization of protein therapeutics is not routinely performed
because of technical challenges and limited sample availability. In
vitro models offer several potential advantages, including larger
sample supplies, simpler and faster methods for sample preparation
and analysis, and the potential to distinguish differences in product
degradation from differences in product clearance. In this study,
we compared the rates of in vivo product degradation using mAb1 recovered
from clinical serum samples with the rates of in vitro product degradation
using mAb1 recovered from spiked phosphate buffered saline (PBS) and
spiked human serum samples to determine if results from the in vitro
model systems could be used to predict the in vivo results. The antibody
samples were characterized by peptide mapping or intact mass analysis
to quantify multiple quality attributes simultaneously, including
deamidation, isomerization, oxidation, N-terminal pyroglutamate formation,
and glycation. It was clearly demonstrated that both the spiked PBS
and spiked serum models were effective in predicting in vivo results
for deamidation, isomerization, N-terminal pyroglutamate formation
and glycation, whereas only the spiked serum model was effective in
predicting in vivo results for oxidation.