File(s) under permanent embargo
Reason: This item is currently closed access.
Application of process analytical technology-based feedback control strategies to improve purity and size distribution in biopharmaceutical crystallization
journal contributionposted on 2016-06-03, 12:20 authored by Elena Simone, Wei Zhang, Zoltan NagyZoltan Nagy
Purity is a critical quality attribute for both pharmaceutical and biopharmaceutical products. The presence of impurities (solvents, salts or byproducts of the synthetic path) in drugs can cause a reduction of their effectiveness or can even be toxic for the patients. Biopharmaceuticals are produced by biological processes which are difficult to control. Therefore the amount of impurities that has to be removed can be significantly higher than in the case of synthetic pharmaceuticals. The aim of this work is to exploit process analytical technology (PAT) tools and different feedback control strategies (T-control, direct nucleation control and supersaturation control) for the crystallization of a biopharmaceutical product. UV/Vis spectroscopy, focused beam reflectance measurement (FBRM) combined with a 2 crystallization process informatics system (CryPRINS) were used to improve the crystal size distribution and purity of crystallized vitamin B12. The different feedback control strategies were compared to classical crystallization techniques in terms of purity of the final crystal and quality of the crystal size distribution and it is shown that using suitable crystallization feedback control strategies, the purity and quality of crystals can be improved.
Financial support provided by the European Research Council grant no. [280106-CrySys].
- Aeronautical, Automotive, Chemical and Materials Engineering
- Chemical Engineering
Published inCRYSTAL GROWTH & DESIGN
Pages2908 - 2919 (12)
CitationSIMONE, E., ZHANG, W. and NAGY, Z.K., 2015. Application of process analytical technology-based feedback control strategies to improve purity and size distribution in biopharmaceutical crystallization. Crystal Growth & Design, 15(6), pp. 2908-2919.
Publisher© American Chemical Society
- SMUR (Submitted Manuscript Under Review)
Publisher statementThis work is made available according to the conditions of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International (CC BY-NC-ND 4.0) licence. Full details of this licence are available at: https://creativecommons.org/licenses/by-nc-nd/4.0/
NotesThis paper is in closed access.