Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
2487343 | Journal of Pharmaceutical Sciences | 2008 | 17 Pages |
Abstract
At high protein concentrations (i.e., 50-100 mg/mL) and 37°C, low solution ionic strength accelerates aggregation of recombinant human interleukin-1 receptor antagonist (rhIL-1ra). We have used a variety of physical and spectroscopic techniques to explain this observation. A population balance model was applied to a continuous mixed suspension, mixed product removal (MSMPR) reactor at steady-state to determine aggregate nucleation and growth rates. Nucleation rates increase at low ionic strength, while growth rates are unaffected. At low rhIL-1ra concentrations (i.e., <1 mg/mL), no conformational changes or differences in free energies of unfolding (ÎGunf) were observed at 37°C over the solution ionic strength range of 0.025-0.184 molal used for aggregation studies. However, increasing the protein concentration to 100 mg/mL shifts the rhIL-1ra monomer-dimer equilibrium significantly at low ionic strength to favor dimerization, which is reflected in subtle conformational changes in the circular dichroism and second-derivative FTIR spectra. In addition to a reversible dimer, an irreversible dimer forms by second-order kinetics during incubation at 37°C. This noncovalent dimer does not significantly participate in further aggregation. The loss of native protein due to aggregation at 37°C was third order in protein thermodynamic activity due to the rate-limiting formation of an aggregation-prone trimer. This trimer forms from irreversible attractive monomer-reversible dimer interactions, which were quantified using second osmotic cross virial coefficients. Lastly, the activity coefficient of rhIL-1ra estimated from aggregation rates is 50% higher at 100 mg/mL protein concentration than at 50 mg/mL, in close agreement with predictions from a hard-sphere model for activity coefficients.
Keywords
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Authors
John R. Alford, Brent S. Kendrick, John F. Carpenter, Theodore W. Randolph,