Abstract
In addition to the analytical challenges related to the size and complexity of biopharmaceutical drugs, the inherent variability that arises due to their manufacturing process requires monitoring throughout the production process to ensure the safety and efficacy of the finished product. In this step, validation data should demonstrate that the process is controlled and reproducible, whereas the manufacturing process must ensure the quality and consistency of the product. For this, the manufacturer sets specification limits according with regulatory guidance. In such a situation, the comparison of different batches is required in order to describe and analyze the variability between them. However, it is unclear how great the variability of the analytical method would be or that in producing the batches. The estimation of the β-expectation tolerance intervals based on the variance components to account for both between-batch and within-batch variability was proposed as a specification limit to control the heterogeneity between batches at the time of manufacture and to verify whether batches meet specification limits. At this point, the variance components were computed by the maximum likelihood method using a linear random model. For this, the protein content, expressed as a percentage of the actual concentration relative to the claim value, and the dimer content (expressed as percentage) were used as critical quality attributes (CQAs) in the monitoring and control process. We used real data from six bevacizumab commercial batches.
Highlights
Monoclonal antibodies represent highly targeted and efficient biotherapeutic agents with widespread uses in the treatment of different disorders, including cancer, autoimmune, and inflammatory diseases [1]
The main objective in any internal quality control is the maintenance of validation conditions over a long time period, specially, in small laboratory
The reproducibility assay confirmed that the method is in control and stable, providing appropriate accuracy and precision
Summary
Monoclonal antibodies (mAbs) represent highly targeted and efficient biotherapeutic agents with widespread uses in the treatment of different disorders, including cancer, autoimmune, and inflammatory diseases [1]. Compared to small biotherapeutic molecules, mAbs are formulated in elevated concentrations, making them highly susceptible to physical and chemical changes [2]. Characterization included biochemical studies (primary structure, glycosylation, disulfide structure, charge variants and size variants), biophysical studies (secondary structure, tertiary structure and thermal stability), biological studies (mechanism of action, including antigen specificity and Fc functionality) and forced degradation studies under specific stress conditions. Under these circumstances, product-related impurities that may be formed during this stress step can compromise the safety and potency of mAbs, and their immunogenicity [5,6]
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