ABSTRACT
Solid-state hydrogen-deuterium exchange with mass spectrometry (ssHDX-MS) was evaluated as an analytical method to rapidly screen and select an optimal lyophilized fragment antigen binding protein (Fab) formulation and the optimal lyophilization cycle. ssHDX-MS in lyophilized Fab formulations, varying in stabilizer type and stabilizer/protein ratio, was conducted under controlled humidity and temperature. The extent of deuterium incorporation was measured using mass spectrometry and correlated with solid-state stress degradation at 50 °C as measured by size exclusion chromatography (SEC) and ion-exchange chromatography (IEC). ssHDX-MS was also used to evaluate the impact of three different types of lyophilization processing on storage stability: controlled ice nucleation (CN), uncontrolled ice nucleation (UCN), and annealing (AN). The extent of deuterium incorporation for different Fab formulations agreed with the order of solid-state stress degradation, with formulations having lower deuterium incorporation showing lower stress-induced degradation (aggregation and charge modifications). For lyophilization processing, no significant effect of ice nucleation was observed in either solid-state stress degradation or in the extent of deuterium incorporation for high concentration Fab formulations (25 mg/mL). In contrast, for low concentration Fab formulations (2.5 mg/mL), solid-state stability from different lyophilization processes correlated with the extent of deuterium incorporation. The order of solid-state degradation (AN < CN < UCN) was the same as the extent of deuterium incorporation on ssHDX-MS (AN < CN < UCN). The extent of deuterium incorporation on ssHDX-MS correlated well with the solid-state stress degradation for different Fab formulations and lyophilization processing methods. Thus, ssHDX-MS can be used to rapidly screen and optimize the formulation and lyophilization process for a lyophilized Fab, reducing the need for time-consuming stress degradation studies.