Should charge variants of monoclonal antibody therapeutics be considered critical quality attributes? (original) (raw)
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Intact Mass Analysis of Monoclonal Antibody (MAb) Charge Variants Separated Using Linear pH Gradient
2013
Monoclonal antibodies can be highly heterogeneous due to modifications such as sialylation, deamidation, and C-terminal lysine truncation. Salt gradient cationexchange chromatography has been used with some success in characterizing MAb charge variants. However, additional effort is often required to tailor the salt gradient method for an individual MAb. In the fast-paced drug development environment, a platform method is desired to accommodate the majority of the MAb analyses.
Journal of Pharmaceutical Sciences, 2017
Characterizing molecular charge variants or isoforms is essential for understanding safety, potency, and bioavailability of antibody therapeutics. However, there is little information on how they influence stability and viscositydproperties governing immunogenicity and delivery. To bridge this gap, we studied antibody stability as a function of charge variant content generated via bioreactor process. We were able to systematically vary acidic variant levels as a function of bioreactor harvest time. Importantly, we do not observe any impact on aggregation behavior of a formulated antibody at high protein concentration as a function of acidic variant level. Furthermore, we confirm that acidic variants enriched using fractionation do not influence viscosity, colloidal or conformational stability. Interestingly, variants with the most acidic isoelectric points contribute disproportionately to formulation color. We discuss our findings in context of antibody manufacturing processes that may yield increased charge variant content.
Biologicals, 2016
Estimating impact of the various product-related variants and impurities on a biotherapeutic's safety and efficacy is an essential requirement in the quality by design paradigm. In view of the limited role that clinical studies offer in this regard, we demonstrate a preclinical approach to achieve this for granulocyte colony-stimulating factor (GCSF). While our repeated-dose toxicity data suggest that these variants do not elicit any adverse effects or histopathological changes, aggregated GCSF impurity caused sluggishness in animal behavior manifested by a possible muscular injury. Cell assay data revealed that the cys-64-cys74 disulfide bond in reduced GCSF imparts stabilization in absence of the cys-36-cys42 bond. PK data demonstrate variability in half lives of different species when compared to the native GCSF. PD data along with differential expression of JAK-2 and STAT5a genes show that all the tested variants triggered the required signal transduction pathways for neutrophil proliferation and activation.
Biologicals, 2011
To assess the impact of manufacturing changes on antibody structure and function during the course of product development, three comparability studies were performed for each of two different IgG1 monoclonal antibody product candidates. Comparability study #1 evaluated the effect of changing the cell line and bulk drug substance manufacturing process for cell culture and purification. Results indicated that these process changes led to differences in sialylation of N-glycans and/or C-terminal lysine levels. Comparability study #2 results confirmed that scale-up of the bulk process and transfer to the commercial site, combined with changing from a lyophilized to a liquid dosage form, did not impact the structural or functional integrity of the antibodies. Comparability study #3 examined possible differences arising when the liquid formulation filled into pre-filled syringes and vials. Results indicated nearly identical molecular structure, biological activity, and degradation profiles except for a small yet statistically significant increase in the levels of subvisible particles in pre-filled syringes. These results from comparability studies with two different monoclonal antibodies are discussed with respect to the timing of the manufacturing changes and overall comparability strategies to assure safety and efficacy during development.
Structure, heterogeneity and developability assessment of therapeutic antibodies
mAbs, 2018
Increasing attention has been paid to developability assessment with the understanding that thorough evaluation of monoclonal antibody lead candidates at an early stage can avoid delays during late-stage development. The concept of developability is based on the knowledge gained from the successful development of approximately 80 marketed antibody and Fc-fusion protein drug products and from the lessons learned from many failed development programs over the last three decades. Here, we reviewed antibody quality attributes that are critical to development and traditional and state-of-the-art analytical methods to monitor those attributes. Based on our collective experiences, a practical workflow is proposed as a best practice for developability assessment including in silico evaluation, extended characterization and forced degradation using appropriate analytical methods that allow characterization with limited material consumption and fast turnaround time.
Analytical comparability study of recombinant monoclonal antibody therapeutics
mAbs
Process changes are inevitable in the life cycle of recombinant monoclonal antibody therapeutics. Products made using pre-and post-change processes are required to be comparable as demonstrated by comparability studies to qualify for continuous development and commercial supply. Establishment of comparability is a systematic process of gathering and evaluating data based on scientific understanding and clinical experience of the relationship between product quality attributes and their impact on safety and efficacy. This review summarizes the current understanding of various modifications of recombinant monoclonal antibodies. It further outlines the critical steps in designing and executing successful comparability studies to support process changes at different stages of a product's lifecycle.
Method Development and Qualification of pH-Based CEX UPLC Method for Monoclonal Antibodies
BioTech
Post-translational modifications (“PTMs”) in monoclonal antibodies (mAbs) contribute to charge variant distribution, which will affect biological efficacy and safety. For the characterization of mAbs, charge variants are used as a critical quality attributes for product quality, stability consistency and effectiveness. Charge variants in mAbs are characterized by a time-consuming and a multistep process starting from cation/anion exchange chromatography, acidic/basic fractions collection and subsequent reverse phase (RP) liquid chromatography, coupled with mass spectrometry (MS) analysis. Hence, an alternative characterization approach that would be highly selective for ion exchange chromatography-based charge variant analysis, which is compatible with on-line MS detection, is needed in the biopharma industry. Against this backdrop, multiple studies are being conducted to develop a simple straight on-line charge variant analysis method. In this regard, we apply the current study, wh...
Main Quality Attributes of Monoclonal Antibodies and Effect of Cell Culture Components
Iranian Biomedical Journal
The culture media optimization is an inevitable part of upstream process development in therapeutic monoclonal antibodies (mAbs) production. The quality by design (QbD) approach defines the assured quality of the final product through the development stage. An important step in QbD is determination of the main quality attributes. During the media optimization, some of the main quality attributes such as glycosylation pattern, charge variants, aggregates, and low-molecular-weight species could be significantly altered. Here, we provide an overview of how cell culture medium components affect the main quality attributes of the mAbs. Knowing the relationship between the culture media components and the main quality attributes could be successfully utilized for rational optimization of mammalian cell culture media for industrial mAbs production.