Your search keyword '"Laura Rolinger"' showing total 4 results

1. Multi-attribute PAT for UF/DF of Proteins—Monitoring Concentration, particle sizes, and Buffer Exchange

Author

Jürgen Hubbuch, Juliane Diehm, Laura Rolinger, Jessica Chow-Hubbertz, Martin Heitmann, Matthias Rüdt, and Stefan Schleper

Subjects

Materials science, Correlation coefficient, Process analytical technology, Ultrafiltration, Analytical chemistry, 02 engineering and technology, Buffers, 01 natural sciences, Biochemistry, Light scattering, Analytical Chemistry, Glucose Oxidase, Dynamic light scattering, Animals, Humans, Technology, Pharmaceutical, Protein precipitation, Static light scattering, Particle Size, 010401 analytical chemistry, Antibodies, Monoclonal, Proteins, Equipment Design, 021001 nanoscience & nanotechnology, Dynamic Light Scattering, 0104 chemical sciences, Diafiltration, Muramidase, Spectrophotometry, Ultraviolet, 0210 nano-technology

Abstract

Ultrafiltration/diafiltration (UF/DF) plays an important role in the manufacturing of biopharmaceuticals. Monitoring critical process parameters and quality attributes by process analytical technology (PAT) during those steps can facilitate process development and assure consistent quality in production processes. In this study, a lab-scale cross-flow filtration (CFF) device was equipped with a variable pathlength (VP) ultraviolet and visible (UV/Vis) spectrometer, a light scattering photometer, and a liquid density sensor (microLDS). Based on the measured signals, the protein concentration, buffer exchange, apparent molecular weight, and hydrodynamic radius were monitored. The setup was tested in three case studies. First, lysozyme was used in an UF/DF run to show the comparability of on-line and off-line measurements. The corresponding correlation coefficients exceeded 0.97. Next, urea-induced changes in protein size of glucose oxidase (GOx) were monitored during two DF steps. Here, correlation coefficients were ≥ 0.92 for static light scattering (SLS) and dynamic light scattering (DLS). The correlation coefficient for the protein concentration was 0.82, possibly due to time-dependent protein precipitation. Finally, a case study was conducted with a monoclonal antibody (mAb) to show the full potential of this setup. Again, off-line and on-line measurements were in good agreement with all correlation coefficients exceeding 0.92. The protein concentration could be monitored in-line in a large range from 3 to 120 g L− 1. A buffer-dependent increase in apparent molecular weight of the mAb was observed during DF, providing interesting supplemental information for process development and stability assessment. In summary, the developed setup provides a powerful testing system for evaluating different UF/DF processes and may be a good starting point to develop process control strategies.

Published

2020

2. Comparison of UV- and Raman-based monitoring of the Protein A load phase and evaluation of data fusion by PLS models and CNNs

Author

Matthias Rüdt, Laura Rolinger, and Jürgen Hubbuch

Subjects

Models, Molecular, Mean squared error, Computer science, Process analytical technology, Bioengineering, Spectrum Analysis, Raman, Sensor fusion, Applied Microbiology and Biotechnology, Convolutional neural network, symbols.namesake, Chemical engineering, Linear regression, Partial least squares regression, symbols, ddc:660, Spectrophotometry, Ultraviolet, Neural Networks, Computer, Staphylococcal Protein A, Biological system, Raman spectroscopy, Nonlinear regression, Biotechnology

Abstract

A promising application of Process Analytical Technology to the downstream process of monoclonal antibodies (mAbs) is the monitoring of the Protein A load phase as its control promises economic benefits. Different spectroscopic techniques have been evaluated in literature with regard to the ability to quantify the mAb concentration in the column effluent. Raman and Ultraviolet (UV) spectroscopy are among the most promising techniques. In this study, both were investigated in an in-line setup and directly compared. The data of each sensor were analyzed independently with Partial-Least-Squares (PLS) models and Convolutional Neural Networks (CNNs) for regression. Furthermore, data fusion strategies were investigated by combining both sensors in hierarchical PLS models or in CNNs. Among the tested options, UV spectroscopy alone allowed for the most precise and accurate prediction of the mAb concentration. A Root Mean Square Error of Prediction (RMSEP) of 0.013 g L-1 was reached with the UV-based PLS model. The Raman-based PLS model reached an RMSEP of 0.232 g L-1 . The different data fusion techniques did not improve the prediction accuracy above the prediction accuracy of the UV-based PLS model. Data fusion by PLS models seems meritless when combining a very accurate sensor with a less accurate signal. Furthermore, the application of CNNs for UV and Raman spectra did not yield significant improvements in the prediction quality. For the presented application, linear regression techniques seem to be better suited compared with advanced nonlinear regression techniques, like, CNNs. In summary, the results support the application of UV spectroscopy and PLS modeling for future research and development activities aiming to implement spectroscopic real-time monitoring of the Protein A load phase.

Published

2021

3. A multisensor approach for improved protein A load phase monitoring by conductivity-based background subtraction of UV spectra

Author

Laura Rolinger, Jürgen Hubbuch, and Matthias Rüdt

Subjects

0106 biological sciences, 0301 basic medicine, Mean squared error, Computer science, Process analytical technology, Bioengineering, 01 natural sciences, Applied Microbiology and Biotechnology, antibody quantification, Continuous production, 03 medical and health sciences, Chemical engineering, 010608 biotechnology, Partial least squares regression, Linear regression, Staphylococcal Protein A, protein A chromatography, Background subtraction, Subtraction, partial least squares regression, 030104 developmental biology, Models, Chemical, ddc:660, Spectrophotometry, Ultraviolet, process analyticaltechnology, capture step, Algorithm, Model building, Biotechnology

Abstract

Real‐time monitoring and control of protein A capture steps by process analytical technologies (PATs) promises significant economic benefits due to the improved usage of the column's binding capacity, by eliminating time‐consuming off‐line analytics and costly resin lifetime studies, and enabling continuous production. The PAT method proposed in this study relies on ultraviolet (UV) spectroscopy with a dynamic background subtraction based on the leveling out of the conductivity signal. This point in time can be used to collect a reference spectrum for removing the majority of spectral contributions by process‐related contaminants. The removal of the background spectrum facilitates chemometric model building and model accuracy. To demonstrate the benefits of this method, five different feedstocks from our industry partner were used to mix the load material for a case study. To our knowledge, such a large design space, which covers possible variations in upstream condition besides the product concentration, has not been disclosed yet. By applying the conductivity‐based background subtraction, the root mean square error of prediction (RMSEP) of the partial least squares (PLS) model improved from 0.2080 to 0.0131 gL$^{-1}$. Finally, the potential of the background subtraction method was further evaluated for single wavelength‐based predictions to facilitate implementation in production processes. An RMSEP of 0.0890 gL$^{-1}$ with univariate linear regression was achieved, showing that by subtraction of the background better prediction accuracy is achieved then without subtraction and a PLS model. In summary, the developed background subtraction method is versatile, enables accurate prediction results, and is easily implemented into existing chromatography setups with typically already integrated sensors.

Published

2021

4. A critical review of recent trends, and a future perspective of optical spectroscopy as PAT in biopharmaceutical downstream processing

Author

Laura Rolinger, Jürgen Hubbuch, and Matthias Rüdt

Subjects

0106 biological sciences, Process (engineering), Computer science, Process analytical technology, Review, Biologics, Spectrum Analysis, Raman, 01 natural sciences, Biochemistry, Analytical Chemistry, Machine Learning, Chemical engineering, Downstream (manufacturing), 010608 biotechnology, Animals, Humans, Technology, Pharmaceutical, Chemometrics, Spectroscopy, Biological Products, Spectroscopy, Near-Infrared, 010401 analytical chemistry, Process automation system, 0104 chemical sciences, Cost reduction, Model predictive control, Spectrometry, Fluorescence, Biopharmaceutical, Downstream processing, Systems engineering, Data analysis, ddc:660, Spectrophotometry, Ultraviolet

Abstract

As competition in the biopharmaceutical market gets keener due to the market entry of biosimilars, process analytical technologies (PATs) play an important role for process automation and cost reduction. This article will give a general overview and address the recent innovations and applications of spectroscopic methods as PAT tools in the downstream processing of biologics. As data analysis strategies are a crucial part of PAT, the review discusses frequently used data analysis techniques and addresses data fusion methodologies as the combination of several sensors is moving forward in the field. The last chapter will give an outlook on the application of spectroscopic methods in combination with chemometrics and model predictive control (MPC) for downstream processes. Graphical abstract Electronic supplementary material The online version of this article (10.1007/s00216-020-02407-z) contains supplementary material, which is available to authorized users.

Published

2020