Oberleitner, T., Zahel, T., Kunzelmann, M., Thoma, J., & Herwig, C. (2023). Incorporating random effects in biopharmaceutical control strategies. AAPS Open, 9, Article 4. https://doi.org/10.1186/s41120-022-00070-5
random effects; Process understanding; Control Strategy
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Abstract:
Objective
Random effects are often neglected when defining the control strategy for a biopharmaceutical process. In this article, we present a case study that highlights the importance of considering the variance introduced by random effects in the calculation of proven acceptable ranges (PAR), which form the basis of the control strategy.
Methods
Linear mixed models were used to model relations between process parameters and critical quality attributes in a set of unit operations that comprises a typical biopharmaceutical manufacturing process. Fitting such models yields estimates of fixed and random effect sizes as well as random and residual variance components. To form PARs, tolerance intervals specific to mixed models were applied that incorporate the random effect contribution to variance.
Results
We compared standardized fixed and random effect sizes for each unit operation and CQA. The results show that the investigated random effect is not only significant but in some unit operations even larger than the average fixed effect. A comparison between ordinary least squares and mixed models tolerance intervals shows that neglecting the contribution of the random effect can result in PARs that are too optimistic.
Conclusions
Uncontrollable effects such as week-to-week variability play a major role in process variability and can be modelled as a random effect. Following a workflow such as the one suggested in this article, random effects can be incorporated into a statistically sound control strategy, leading to lowered out of specification results and reduced patient risk.
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Project title:
Chemical Systems Engineering: 868615 (FFG - Österr. Forschungsförderungs- gesellschaft mbH)
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Project (external):
Austrian Research Promotion Agency (FFG)
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Project ID:
844608
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Research Areas:
Biological and Bioactive Materials: 50% Modeling and Simulation: 50%