Abstract
Protein drug substance is typically frozen to enable manufacturing flexibility through prolonging the shelf life of drug substance and providing better biochemical stability. The process of freezing and thawing of bulk protein solutions poses several challenges. It is important to understand the process and define mitigation strategies to address these challenges. Just not the process but the choice of storage container can have an impact on stability and downstream operation of formulation during drug product process. Therefore, understanding the options currently available in terms of drug substance storage containers and how to balance the need based on specific scenarios is critical. Storage temperature is as important as the container the drug substance is stored at. Furthermore, shipping drug substance in frozen state requires thorough understanding of logistics and dependence of shipping temperature on stability. This chapter fundamentally looks at the freezing and thawing process, discusses phenomenon of cryoconcentration in various containers and mitigation strategies, consequence of not choosing appropriate storage temperature, and provides considerations for storage and shipping of drug substance.
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References
Singh SK, et al. Frozen state storage instability of a monoclonal antibody: aggregation as a consequence of trehalose crystallization and protein unfolding. Pharm Res. 2011;28(4):873–85.
Kolhe P, Badkar A. Freeze-thaw of protein bulk drug substance. AAPS Sterile Prod Focus Group Ann Newsl. 2013:2–5.
Singh SK, Nema S. Freezing and thawing of protein solutions. In: Formulation and process development strategies for manufacturing biopharmaceuticals. Hoboken: Wiley; 2010.
Cocks FH, Brower WE. Phase diagram relationships in cryobiology. Cryobiology. 1974;11(4):340–58.
Angell CA. Liquid fragility and the glass transition in water and aqueous solutions. Chem Rev. 2002;102(8):2627–50.
Gayle FW, Cocks FH, Shepard ML. The H2O-NaCl-sucrose phasediagram and applications in cryobiology. J Appl Chem Biotechnol. 1977;27:599–607.
Shalaev EY, Franks F. Equilibrium phase diagram of the water-sucrose-NaCl system. Thermochim Acta. 1995;255.
Green JL, Angell CA. Phase relationships and vitrification in saccharidewater solutions and the trehalose anomaly. J Phys Chem. 1989;93:2880–2.
Siniti M, Jabrane S, Letoffe JM. Study of the respective binary phase diagrams of sorbitol with mannitol, maltitol and water. Thermochim Acta. 1999;325:171–80.
Fahy GM. Analysis of “solution effects” injury. Equations for calculating phase diagram information for the ternary systems NaCl-dimethylsulfoxide-water and NaCl-glycerol-water. Biophys J. 1980;32(2):837–50.
Shepard ML, Goldston CS, Cocks FH. The H2O-NaCl-glycerol phase diagram and its application in cryobiology. Cryobiology. 1976;13(1):9–23.
Jochem M, Korber C. Extended phase diagrams for the ternary solutions H2O-NaCl-glycerol and H2O-NaCl-hydroxyethylstarch (HES) determined by DSC. Cryobiology. 1987;24:513–36.
Shalaev EY, Kanev AN. Study of the solid-liquid state diagram of the water-glycine-sucrose system. Cryobiology, 1994;31:374–82.
Suzuki T, Franks F. Solid-liquid phase transitions and amorphous states in ternary sucrose-glycine-water systems. J Chem Soc Faraday Trans. 1993;89(17).
Chatterjee K, Shalaev EY, Suryanarayanan R. Partially crystalline systems in lyophilization: I. Use of ternary state diagrams to determine extent of crystallization of bulking agent. J Pharm Sci. 2005;94(4):798–808.
Akyurt M, Zaki G, Habeebullah B. Freezing phenomena in ice-water systems. Energy Conserv Manage. 2002;43:1773–89.
Bhatnagar BS, Bogner RH, Pikal MJ. Protein stability during freezing: separation of stresses and mechanisms of protein stabilization. Pharm Dev Technol. 2007;12(5):505–23.
Schenz TW. Glass transitions and product stability—an overview. Food Hydrocolloids. 1995;9:307–15.
Singh SK, et al. Large-scale freezing of biologics: a practitioner’s review, Part 1—freezing mechanisms. BioProcess Int. 2009;7(9):32–44.
Franks F. Protein stability: the value of ‘old literature’. Biophys Chem. 2002;96(2–3):117–27.
Chaplin M. Do we underestimate the importance of water in cell biology? Nat Rev Mol Cell Biol. 2006;7(11):861–6.
Carpenter JF, Crowe JH. The mechanism of cryoprotection of proteins by solutes. Cryobiology. 1988;25(3):244–55.
Franks F. Biophysics and biochemistry at low temperatures. 2012.
Piedmonte DM, et al. Sorbitol crystallization can lead to protein aggregation in frozen protein formulations. Pharm Res. 2007;24(1):136–46.
Levine H, Slade L. Thermomechanical properties of small carbohydrate-water glasses and ‘rubbers’: kinetically metastable systems at sub-zero temperatures. J Chem Soc Faraday Trans. 1988;84(8):2619–33.
Costantino H. Excipients for use in lyophilized pharmaceutical peptide, protein and other bioproducts. Lyophilization Biopharm, AAPS. 2004.
Williams ML, Landel RF, Ferry JD. The temperature dependence of relaxation mechanisms in amorphous polymers and other glass-forming liquids. JACS. 1955;77:3701–7.
Strambini GB, Gabellieri E. Proteins in frozen solutions: evidence of ice-induced partial unfolding. Biophys J. 1996;70(2):971–6.
Strambini GB, Gonnelli M. Protein stability in ice. Biophys J. 2007;92(6):2131–8.
Dong J, et al. Freezing-induced phase separation and spatial microheterogeneity in protein solutions. J Phys Chem B. 2009;113(30):10081–7.
Sundaramurthi P, Suryanarayanan R. Trehalose crystallization during freeze-drying: implications on lyoprotection. J Phys Chem Lett. 2010;1:510–4.
Levine H, Slade L. Principles of “cryostabilization” technology from structure/property relationships of carbohydrate/water systems: a review. Cryoletters. 1988;9:21–63.
Ablett S, Izzard MJ, Lillford PJ. Differential scanning calorimetric study of frozen sucrose and glycerol solutions. J Chem Soc, Faraday Trans. 1992;88(6):789–94.
Chang BS, Randall CS. Use of subambient thermal analysis to optimize protein lyophilization. Cryobiology. 1992;29:632–56.
Colandene JD, et al. Lyophilization cycle development for a high-concentration monoclonal antibody formulation lacking a crystalline bulking agent. J Pharm Sci. 2007;96(6):1598–608.
Chang BS, Kendrick BS, Carpenter JF. Surface-induced denaturation of proteins during freezing and its inhibition by surfactants. J Pharm Sci. 1996;85(12):1325–30.
Hsu CC, et al. Surface denaturation at solid-void interface—a possible pathway by which opalescent particulates form during the storage of lyophilized tissue-type plasminogen activator at high temperatures. Pharm Res. 1995;12(1):69–77.
Nema S, Avis KE. Freeze-thaw studies of a model protein, lactate dehydrogenase, in the presence of cryoprotectants. J Parenter Sci Technol. 1993;47(2):76–83.
Norde W. Adsorption of proteins from solution at the solid-liquid interface. Adv Colloid Interface Sci. 1986;25(4):267–340.
Sonnichsen FD, et al. Refined solution structure of type III antifreeze protein: hydrophobic groups may be involved in the energetics of the protein-ice interaction. Structure. 1996;4(11):1325–37.
Griko YV, et al. Cold denaturation of staphylococcal nuclease. Proc Natl Acad Sci U S A. 1988;85(10):3343–7.
Franks F. Protein destabilization at low temperatures. Adv Protein Chem. 1995;46:105–39.
Jaenicke R. Protein structure and function at low temperatures. Philos Trans R Soc Lond B Biol Sci. 1990;326(1237):535–51; discussion 551–3.
Privalov PL. Cold denaturation of proteins. Crit Rev Biochem Mol Biol. 1990;25(4):281–305.
Brandts JF, Fu J, Nordin JH. Low temperature denaturation of chymotrypsinogen in aqueous solution and in frozen aqueous solution. In: Wolstenholme GEW, O’Connor M, editors. The frozen cell, A Ciba foundation symposium. London: J & A Churchill; 1970. p. 189–212.
Franks F, Hatley RHM. Low temperature unfolding of chymotrypsinogen. Cryoltters. 1985;6(3).
Privalov PL, et al. Cold denaturation of myoglobin. J Mol Biol. 1986;190(3):487–98.
Griko YV, Privalov PL. Calorimetric study of the heat and cold denaturation of beta-lactoglobulin. Biochemistry. 1992;31(37):8810–5.
Zhang J, et al. NMR study of the cold, heat, and pressure unfolding of ribonuclease A. Biochemistry. 1995;34(27):8631–41.
Tang XC, Pikal MJ. Measurement of the kinetics of protein unfolding in viscous systems and implications for protein stability in freeze-drying. Pharm Res. 2005;22(7):1176–85.
Adrover M, et al. The role of hydration in protein stability: comparison of the cold and heat unfolded states of Yfh1. J Mol Biol. 2012;417(5):413–24.
Zhang L, et al. Mapping hydration dynamics around a protein surface. Proc Natl Acad Sci U S A. 2007;104(47):18461–6.
Remmele RL Jr, Stushnoff C, Carpenter JF. Real-time in situ monitoring of lysozyme during lyophilization using infrared spectroscopy: dehydration stress in the presence of sucrose. Pharm Res. 1997;14(11):1548–55.
Gomez G, Pikal MJ, Rodriguez-Hornedo N. Effect of initial buffer composition on pH changes during far-from-equilibrium freezing of sodium phosphate buffer solutions. Pharm Res. 2001;18(1):90–7.
Murase N, Franks F. Salt precipitation during the freeze-concentration of phosphate buffer solutions. Biophys Chem. 1989;34(3):293–300.
Van Den Berg L. The effect of addition of sodium and potassium chloride to the reciprocal system: KH2PO4-Na2HPO4-H2O on pH and composition during freezing. Arch Biochem Biophys. 1959;84:305–15.
Van Den Berg L, Rose D. Effect of freezing on the pH and composition of sodium and potassium phosphate solutions; the reciprocal system KH2PO4-Na2-HPO4-H2O. Arch Biochem Biophys. 1959;81(2):319–29.
Pikal-Cleland KA, et al. Protein denaturation during freezing and thawing in phosphate buffer systems: monomeric and tetrameric beta-galactosidase. Arch Biochem Biophys. 2000;384(2):398–406.
Kolhe P, Amend E, Singh SK. Impact of freezing on pH of buffered solutions and consequences for monoclonal antibody aggregation. Biotechnol Prog. 2010;26(3):727–33.
Pikal MJ, et al. The effects of formulation variables on the stability of freeze-dried human growth hormone. Pharm Res. 1991;8(4):427–36.
Sarciaux JM, et al. Effects of buffer composition and processing conditions on aggregation of bovine IgG during freeze-drying. J Pharm Sci. 1999;88(12):1354–61.
Shalaev EY, et al. Thermophysical properties of pharmaceutically compatible buffers at sub-zero temperatures: implications for freeze-drying. Pharm Res. 2002;19(2):195–201.
Heller MC, Carpenter JF, Randolph TW. Application of a thermodynamic model to the prediction of phase separations in freeze-concentrated formulations for protein lyophilization. Arch Biochem Biophys. 1999;363(2):191–201.
Heller MC, Carpenter JF, Randolph TW. Protein formulation and lyophilization cycle design: prevention of damage due to freeze-concentration induced phase separation. Biotechnol Bioeng. 1999;63(2):166–74.
Butler MF. Freeze concentration of solutes at the ice/solution interface studied by optical interferometry. Crystal Growth Des. 2002;2(6):541–8.
Korber C. Phenomena at the advancing ice-liquid interface: solutes, particles and biological cells. Q Rev Biophys. 1988;21(2):229–98.
Chen YH, Cao E, Cui ZF. An experimental study of freeze concentration in biological media. Food Bioprod Process. 2001;79(1):35–40.
Rodrigues MA, et al. Effect of freezing rate and dendritic ice formation on concentration profiles of proteins frozen in cylindrical vessels. J Pharm Sci. 2011;100(4):1316–29.
Ayel V, et al. Crystallisation of undercooled aqueous solutions: Experimental study of free dendritic growth in cylindrical geometry. Int J Heat Mass Transf. 2006;49:1876–84.
Miller MA, et al. Frozen-state storage stability of a monoclonal antibody: aggregation is impacted by freezing rate and solute distribution. J Pharm Sci. 2013;102(4):1194–208.
Wilkins J, Sesin SD, Wisniewski R. Large-scale cryopreservation of biotherapeutic products. Innov Pharm Technol. 2001;8:174–80.
Miyawaki O, Liu L, Nakamura K. Effective partition constant of solute between ice and liquid phases in progressive freeze-concentration. J Food Sci. 1998;63(5):756–8.
Wisniewski R, Wu V. Large-scale freezing and thawing of pharmaceutical products. In Biotechnology and biopharmaceutical manufacturing, processing preservation. Boca Raton: CRC Press;1996. p. 7–59.
Butler MF. Instability formation and directional dendritic growth of ice studied by optical interferometry. Cryst Growth Des. 2000;1(3):213–23.
Wisniewski R. Developing large-scale cryopreservation systems for biopharmaceutical products. BioPharm. 1998;11:50–6.
Kolhe P, Holding E, Lary A, Chico S, Singh SK. Large scale freezing of biologics: understanding protein and solute concentration changes in a cryovessel—Part II. Biopharm Int. 2010;23(7):40–9.
Kolhe P, Badkar A. Protein and solute distribution in drug substance containers during frozen storage as well as post-thawing: a tool to understand and define freezing-thawing parameters in biotechnology process development. Biotechnol Bioeng. 2009;27(2):494–504.
Kolhe P, Holding E, Lary A, Chico S, Singh SK. Large scale freezing of biologics: understanding protein and solute concentration changes in a cryovessel—Part I. Biopharm Int. 2010;23(6):53–60.
Maity H, Karkaria C, Davagnino J. Mapping of solution components, pH changes, protein stability and the elimination of protein precipitation during freeze-thawing of fibroblast growth factor 20. Int J Pharm. 2009;378(1–2):122–35.
Padala C, et al. Impact of uncontrolled vs controlled rate freeze-thaw technologies on process performance and product quality. PDA J Pharm Sci Technol. 2010;64(4):290–8.
Tschoepe M, Schmidt R. Impact of freeze/thaw processing on monoclonal antibody stability. In: Bioprocess International conference. 2008.
Webb SDW, Webb JN, Hughes TG, Sesin DF, Kincaid AC. Freezing biopharmaceutical using common techniques and the magnitude of bulk scale freeze-concentration. Bioprocess Int. 2002;15(5):22–34.
Wisniewski R, Wu VL. Large-scale freezing and thawing of biopharmaceutical products. In: Wu VL, Avis KE, editors. Biotechnology and biopharmaceutical manufacturing, processing, and preservation. Boca Raton: CRC Press; 1996. p. 7–60.
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Kolhe, P., Goswami, S. (2018). Bulk Protein Solution: Freeze–Thaw Process, Storage and Shipping Considerations. In: Warne, N., Mahler, HC. (eds) Challenges in Protein Product Development. AAPS Advances in the Pharmaceutical Sciences Series, vol 38. Springer, Cham. https://doi.org/10.1007/978-3-319-90603-4_15
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