Towards Heat-stable Oxytocin Formulations: Analysis of Degradation Kinetics and Identification of Degradation Products

Recombinant DNA technology has now made it possible to produce proteins for pharmaceutical applications. Consequently, proteins produced via biotechnology now comprise a significant portion of the drugs currently under development. Isolation, purification, formulation, and delivery of proteins represent significant challenges to pharmaceutical scientists, as proteins possess unique chemical and physical properties. These properties pose difficult stability problems. A summary of both chemical and physical decomposition pathways for proteins is given. Chemical instability can include proteolysis, deamidation, oxidation, racemization, and beta-elimination. Physical instability refers to processes such as aggregation, precipitation, denaturation, and adsorption to surfaces. Current methodology to stabilize proteins is presented, including additives, excipients, chemical modification, and the use of site-directed mutagenesis to produce a more stable protein species.

This article describes chromatographic and spectroscopic techniques that have multiple applications in the preparation, isolation, and analysis of dityrosine. A three-step chromatographic procedure facilitates the preparation of 120 mg or more (yield > 26% of theoretical maximum) of dityrosine from the enzyme-catalyzed oxidation of tyrosine. DEAE-cellulose chromatography performed in a boric acid-sodium borate buffer removes most of the contaminating pigments. Two-dimensional pH-dependent chromatography on BioGel P-2 separates dityrosine from tyrosine, residual pigments, salts, etc. Elemental analysis indicates that the purified product is approximately 92% dityrosine by weight. Fast atom bombardment mass spectrometry and two types of reverse-phase high-performance liquid chromatography (HPLC), monitored in fluorescence and absorbance measurements, verify the purity of the dityrosine. The distinctive pH-dependent chromatography of dityrosine on BioGel P-2, with reversible adsorption to the matrix occurring at pH values less than 3, is useful for the isolation of varying quantities of dityrosine and for analysis per se. Affinity chromatography on immobilized phenyl boronate (Matrex Gel PBA-60) is an alternate method for the isolation and determination of dityrosine, which undergoes specific interactions with the boronate moiety and possible hydrophobic association with the phenyl group. Two new reverse-phase HPLC techniques expedite the analysis of picomole quantities of dityrosine. One employs isocratic elution (92% H2O, 8% acetonitrile, and 0.1% trifluoroacetic acid) of an ODS II Spherisorb column, with both fluorometric and spectrophotometric detection. The other procedure may be performed in conjunction with total amino acid analysis. A rapid gradient program, developed with a Phenomenex Ultracarb 20 column, clearly separates dabsylated dityrosine and tyrosine from other dabsylated amino acids. It is especially useful when dityrosine is a trace component.

Asparagine deamidation is a decisive event in chemotherapy-induced apoptosis and a major obstacle in the formulation of monoclonal antibodies. Despite the importance of deamidation, little is known about the elementary reactions involved. B3LYP/6-31+G(d,p)/COSMO-RS calculations were used to obtain stable structures and transition states for a network of reactions. Calculated rate constants were incorporated into a kinetic model of the pH dependence and compared to a pseudo-steady-state model. At low pH, the calculations show that deamidation occurs by direct acid-catalyzed hydrolysis to aspartate. At neutral to basic pH, deamidation proceeds by the initial formation of a tetrahedral intermediate. The intermediate can be converted to succinimide by two pathways and three rate-determining steps that shift in relative importance with pH. The calculated pH-dependent rate constant qualitatively agrees with the experimental pH dependence. The rate-determining transition state structures may help to understand chemotherapy-induced apoptosis and improve protein formulations.