Monitoring Product Quantity, Purity and Potency of Biopharmaceuticals in
Real-time by Predictive Chemometrics and Soft sensors
- Astrid Dürauer,
- Alois Jungbauer,
- Theresa Scharl
Astrid Dürauer
Universitat fur Bodenkultur Department fur Biotechnologie
Corresponding Author:astrid.duerauer@boku.ac.at
Author ProfileAlois Jungbauer
Universitat fur Bodenkultur Department fur Biotechnologie
Author ProfileTheresa Scharl
Universitat fur Bodenkultur Wien Institut fur Statistik
Author ProfileAbstract
The biopharmaceutical industry is still running in batch mode, mostly
because it is a highly regulated industry sector. In the past, sensors
were not readily available and in-process control was mainly executed
off-line. The most important product parameters are quantity, purity and
potency besides adventitious agents and bioburden. There is increasing
economic pressure on time-to-market and also on the environmental
sustainability of biopharmaceutical manufacturing. New concepts for
manufacturing using disposable single-use technologies and integrated
bioprocessing will dominate the future of bioprocessing. In order to
ensure the quality of pharmaceuticals initiatives such as Process
Analytical Technologies, Quality by Design and Continuous Integrated
Manufacturing have been established. The vision must be that these
initiatives together with technology development pave the way for
process automation and autonomous bioprocessing without any human
intervention. Then a real-time release would be realized leading to a
highly predictive and robust biomanufacturing system. The steps toward
such automated and autonomous bioprocessing are reviewed in context of
monitoring and control. Starting from statistical treatment of single
and multiple sensors, establishing soft sensors with predictive
chemometrics and hybrid models. A scenario is described how to integrate
soft sensors and predictive chemometrics into modern process control.
This will be exemplified by selective downstream processing steps such
as chromatography and membrane filtration, the most common unit
operations for separation of biopharmaceuticals.10 Mar 2023Submitted to Biotechnology and Bioengineering 16 Mar 2023Submission Checks Completed
16 Mar 2023Assigned to Editor
16 Mar 2023Review(s) Completed, Editorial Evaluation Pending
23 Apr 2023Reviewer(s) Assigned
19 May 2023Editorial Decision: Revise Major
13 Jun 20231st Revision Received
15 Jun 2023Submission Checks Completed
15 Jun 2023Assigned to Editor
15 Jun 2023Review(s) Completed, Editorial Evaluation Pending
07 Jul 2023Editorial Decision: Accept