Abstract
Physical instabilities of proteins in the form of protein aggregation continue to be a major challenge in the development of protein drug candidates. Aggregation can occur during different stages of product lifecycle such as freeze–thaw, manufacturing, shipping, and storage, and can potentially delay commercialization of candidates. A lack of clear understanding of the underlying mechanism(s) behind protein aggregation and the potential immunogenic reactions renders the presence of aggregates in biotherapeutic products undesirable. Understanding and minimizing aggregation can potentially reduce immunogenic responses and make protein therapeutics safer. Therefore, it is imperative to identify, understand, and control aggregation during early formulation development and develop reliable and orthogonal analytical methodologies to detect and monitor levels of aggregation. Freezing and thawing are typical steps involved in the manufacturing of drug product and could result in complex physical and chemical changes, which in turn could potentially cause protein aggregation. This study provides a systematic approach in understanding and selecting the ideal freeze–thaw conditions for manufacturing of protein-based therapeutics. It identifies the importance of balancing different excipients with an overall goal of sufficiently reducing or eliminating aggregation and developing a stable and scalable formulation. The results demonstrated that the freeze–thaw damage of mAb-1 in aqueous solutions was significantly reduced by identification of optimal freeze–thaw conditions using first a small-scale model with subsequent at-scale verifications. The work provides a framework for successful transfer of drug product manufacturing process from small-scale to the manufacturing scale production environment especially for molecules that are susceptible to freeze–thaw induced degradations.
Highlights
Physical instabilities of proteins in the form of protein aggregation continue to be a major challenge in the development of protein drug candidates
Protein therapeutics serve as powerful tools to provide treatment for several diseases
One of the most common examples of protein instabilities is observed at all stages of drug development and presents major challenges to successful progression of drug candidates
Summary
Physical instabilities of proteins in the form of protein aggregation continue to be a major challenge in the development of protein drug candidates. Often passive freezing and thawing techniques are implemented during the manufacturing of monoclonal antibodies without gaining product and process specific knowledge Such non-optimized approach can negatively impact the physical and chemical properties of protein solutions during F/T events resulting in increased overall development costs and time. With consideration of this and limited material availability at early stages of a program, in the present study, the rate combinations of slow freezefast thaw and fast freeze- slow thaw was systematically examined; depending on the type and lifecycle phase of the molecule, such information may be required early on when large amounts of material are generally not available. While the formulation excipients had been previously identified based on extensive (pre)formulation screening studies of mAb-1, the objective of this study was to present a F/T characterization approach by systematically evaluating the effects of process and formulation variables that contribute to aggregation of mAb-1, and develop a scalable process for transfer to an off-site fill/finish facility
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