Sorbitol Crystallization Can Lead to Protein Aggregation in Frozen Protein Formulations

PurposeThis work examines the cause of aggregation of an Fc-fusion protein formulated in sorbitol upon frozen storage for extended periods of time at −30°C.Materials and MethodsWe designed sub-ambient differential scanning calorimetry (DSC) experiments to capture the effects of long-term frozen storage. The physical stability of formulation samples was monitored by size exclusion high performance liquid chromatography (SE-HPLC).ResultsDSC analysis of non-frozen samples shows the expected glass transitions (Tg′) at −45°C for samples in sorbitol and at −32°C in sucrose. In time course studies where sorbitol formulations were stored at −30°C and analyzed by DSC without thawing, two endothermic transitions were observed: a melting endotherm at −20°C dissipated over time, and a second endotherm at −8°C was seen after approximately 2 weeks and persisted in all later time points. Protein aggregation was only seen in the samples formulated in sorbitol and stored at −30°C, correlating aggregation with the aforementioned melts.ConclusionsThe observed melts are characteristic of crystalline substances and suggest that the sorbitol crystallizes over time. During freezing, the excipient must remain in the same phase as the protein to ensure protein stability. By crystallizing, the sorbitol is phase-separated from the protein, which leads to protein aggregation.

[1]  E. Gabellieri,et al.  Proteins in frozen solutions: evidence of ice-induced partial unfolding. , 1996, Biophysical journal.

[2]  Hansson Ub Aggregation of human immunoglobulin G upon freezing. , 1968 .

[3]  P. Privalov,et al.  Cold Denaturation of Protein , 1990 .

[4]  L. van den Berg,et al.  Effect of freezing on the pH and composition of sodium and potassium phosphate solutions; the reciprocal system KH2PO4-Na2-HPO4-H2O. , 1959, Archives of biochemistry and biophysics.

[5]  E. Gabellieri,et al.  Perturbation of protein tertiary structure in frozen solutions revealed by 1-anilino-8-naphthalene sulfonate fluorescence. , 2003, Biophysical journal.

[6]  B. Chang,et al.  Use of subambient thermal analysis to optimize protein lyophilization , 1992 .

[7]  J. Carpenter,et al.  Effects of Sugars and Polymers on Crystallization of Poly(ethylene glycol) in Frozen Solutions: Phase Separation Between Incompatible Polymers , 1996, Pharmaceutical Research.

[8]  J. Lee,et al.  The stabilization of proteins by sucrose. , 1981, The Journal of biological chemistry.

[9]  David Ouellette,et al.  Mechanism of protein stabilization by sugars during freeze-drying and storage: native structure preservation, specific interaction, and/or immobilization in a glassy matrix? , 2005, Journal of pharmaceutical sciences.

[10]  S J Prestrelski,et al.  Separation of freezing- and drying-induced denaturation of lyophilized proteins using stress-specific stabilization. I. Enzyme activity and calorimetric studies. , 1993, Archives of biochemistry and biophysics.

[11]  F. Franks Solid aqueous solutions , 1993 .

[12]  S. Yoshioka,et al.  Effect of mannitol crystallinity on the stabilization of enzymes during freeze-drying. , 1994, Chemical & pharmaceutical bulletin.

[13]  Michael J Pikal,et al.  Effect of sorbitol and residual moisture on the stability of lyophilized antibodies: Implications for the mechanism of protein stabilization in the solid state. , 2005, Journal of pharmaceutical sciences.

[14]  J. Carpenter,et al.  The mechanism of cryoprotection of proteins by solutes. , 1988, Cryobiology.

[15]  B. Chang,et al.  Surface-induced denaturation of proteins during freezing and its inhibition by surfactants. , 1996, Journal of pharmaceutical sciences.

[16]  R. Suryanarayanan,et al.  Influence of the Active Pharmaceutical Ingredient Concentration on the Physical State of Mannitol—Implications in Freeze-Drying , 2005, Pharmaceutical Research.

[17]  M. Lafrance,et al.  Aseptic concentration of living microbial cells by cross-flow filtration , 1989 .

[18]  M. Manning,et al.  Effect of Tween 20 on freeze-thawing- and agitation-induced aggregation of recombinant human factor XIII. , 1998, Journal of pharmaceutical sciences.

[19]  George M. Beringer,et al.  American Pharmaceutical Association: Organized 1851. Incorporated 1888 , 1914 .

[20]  F. Franks Freeze-drying: from empiricism to predictability. The significance of glass transitions. , 1992, Developments in biological standardization.

[21]  C. A. Mitchell,et al.  Crystallization and Polymorphism of Conformationally Flexible Molecules: Problems, Patterns, and Strategies , 2000 .

[22]  Raymond C Rowe,et al.  Handbook of Pharmaceutical Excipients , 1994 .

[23]  S. Yoshioka,et al.  Decreased Protein-Stabilizing Effects of Cryoprotectants Due to Crystallization , 1993, Pharmaceutical Research.

[24]  M. Deras,et al.  Electrolyte-Induced Changes in Glass Transition Temperatures of Freeze-Concentrated Solutes , 1995, Pharmaceutical Research.

[25]  L. Slade,et al.  Thermomechanical properties of small-carbohydrate–water glasses and ‘rubbers’. Kinetically metastable systems at sub-zero temperatures , 1988 .

[26]  F. Franks,et al.  Protein destabilization at low temperatures. , 1995, Advances in protein chemistry.

[27]  T. Randolph,et al.  Phase separation of excipients during lyophilization: effects on protein stability. , 1997, Journal of pharmaceutical sciences.

[28]  R. Suryanarayanan,et al.  Crystallization Behavior of Mannitol in Frozen Aqueous Solutions , 2004, Pharmaceutical Research.

[29]  S. Kojima,et al.  Freeze-Concentration Separates Proteins and Polymer Excipients Into Different Amorphous Phases , 2000, Pharmaceutical Research.

[30]  G. A. Jeffrey,et al.  Conformations of the alditols , 1970 .

[31]  J. Guillory GENERATION OF POLYMORPHS, HYDRATES, SOLVATES, AND AMORPHOUS SOLIDS , 1999 .

[32]  S. Nail,et al.  Characterization of frozen solutions of glycine. , 2001, Journal of pharmaceutical sciences.