Continuous Membrane-Assisted Crystallization To Increase the Attainable Product Quality of Pharmaceuticals and Design Space for Operation
Continuous manufacturing is an important paradigm shift in pharmaceutical industries and has renewed the interest in continuous crystallization. The combination of crystallization and membranes is a promising hybrid technology for separation and purification of pharmaceuticals. The impact of membran...
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| Veröffentlicht in: | Industrial & engineering chemistry research 2017-05, Vol.56 (19), p.5705-5714 |
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| container_title | Industrial & engineering chemistry research |
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| creator | Wang, Jiayuan Lakerveld, Richard |
| description | Continuous manufacturing is an important paradigm shift in pharmaceutical industries and has renewed the interest in continuous crystallization. The combination of crystallization and membranes is a promising hybrid technology for separation and purification of pharmaceuticals. The impact of membranes as an extension to conventional continuous crystallization processes on attainable product quality and design space is investigated systematically using model-based optimization. The proposed model is based on a full population balance such that all relevant crystallization phenomena can be included and is solved using a first-order discretization scheme with a hybrid grid. A case study involving continuous crystallization of paracetamol using a series of mixed suspension, mixed product removal (MSMPR) crystallizers is presented to illustrate the approach. The results show that the attainable size and design space can be enlarged significantly by extending conventional crystallization with membranes. In particular, larger crystals or shorter residence times can be achieved. Furthermore, to obtain a crystal size within a desired range, a broader range of temperatures can be applied, which increases operational flexibility. |
| doi_str_mv | 10.1021/acs.iecr.7b00514 |
| format | Article |
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The combination of crystallization and membranes is a promising hybrid technology for separation and purification of pharmaceuticals. The impact of membranes as an extension to conventional continuous crystallization processes on attainable product quality and design space is investigated systematically using model-based optimization. The proposed model is based on a full population balance such that all relevant crystallization phenomena can be included and is solved using a first-order discretization scheme with a hybrid grid. A case study involving continuous crystallization of paracetamol using a series of mixed suspension, mixed product removal (MSMPR) crystallizers is presented to illustrate the approach. The results show that the attainable size and design space can be enlarged significantly by extending conventional crystallization with membranes. In particular, larger crystals or shorter residence times can be achieved. 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| title | Continuous Membrane-Assisted Crystallization To Increase the Attainable Product Quality of Pharmaceuticals and Design Space for Operation |
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