Preparative chromatography for separation of proteins

Preparative Chromatography for Separation of Proteins addresses a wide range of modeling, techniques, strategies, and case studies of industrial separation of proteins and peptides. * Covers broad aspects of preparative chromatography with a unique combination of academic and industrial perspectives * Presents Combines modeling with compliantce useing of Quality-by-Design (QbD) approaches including modeling * Features a variety of chromatographic case studies not readily accessible to the general public * Represents an essential reference resource for academic, industrial, and pharmaceutical researchers

List of Contributors xv Series Preface xix Preface xxi 1 Model -Based Preparative Chromatography Process Development in the QbD Paradigm 1 Arne Staby, Satinder Ahuja, and Anurag S. Rathore 1.1 Motivation 1 1.2 Regulatory Context of Preparative Chromatography and Process Understanding 1 1.3 Application of Mathematical Modeling to Preparative Chromatography 6 Acknowledgements 8 References 8 2 Adsorption Isotherms: Fundamentals and Modeling Aspects 11 Jorgen M. Mollerup 2.1 Introduction 11 2.2 Definitions 12 2.3 The Solute Velocity Model 14 2.4 Introduction to the Theory of Equilibrium 17 2.5 Association Equilibria 21 2.6 The Classical Adsorption Isotherm 24 2.7 The Classical Ion Exchange Adsorption Isotherm 26 2.8 Hydrophobic Adsorbents, HIC and RPC 38 2.9 Protein-Protein Association and Adsorption Isotherms 47 2.10 The Adsorption Isotherm of a GLP -1 Analogue 51 2.11 Concluding Remarks 59 Appendix 2.A Classical Thermodynamics 60 References 77 3 Simulation of Process Chromatography 81 Bernt Nilsson and Niklas Andersson 3.1 Introduction 81 3.2 Simulation -Based Prediction of Chromatographic Processes 82 3.3 Numerical Methods for Chromatography Simulation 94 3.4 Simulation -Based Model Calibration and Parameter Estimation 96 3.5 Simulation -Based Parametric Analysis of Chromatography 97 3.6 Simulation -Based Optimization of Process Chromatography 101 3.7 Summary 106 Acknowledgement 107 References 108 4 Simplified Methods Based on Mechanistic Models for Understanding and Designing Chromatography Processes for Proteins and Other Biological Products 111 Noriko Yoshimoto and Shuichi Yamamoto 4.1 Introduction 111 4.2 HETP and Related Variables in Isocratic Elution 114 4.3 Linear Gradient Elution (LGE) 120 4.4 Applications of the Model 130 4.5 Summary 145 Appendix 4.A Mechanistic Models for Chromatography 149 Appendix 4.B Distribution Coefficient and Binding Sites [20- 149 References 152 5 Development of Continuous Capture Steps in Bioprocess Applications 159 Frank Riske and Tom Ransohoff 5.1 Introduction 159 5.2 Economic Rationale for Continuous Processing 160 5.3 Developing a Continuous Capture Step 162 5.4 The Operation of MCC Systems 165 5.5 Modeling MCC Operation 167 5.6 Processing Bioreactor Feeds on a Capture MCC 169 5.7 The Future of MCC 171 References 172 6 Computational Modeling in Bioprocess Development 177 Francis Insaidoo, Suvrajit Banerjee, David Roush, and Steven Cramer 6.1 Linkage of Chromatographic Thermodynamics (Affinity, Kinetics, and Capacity) 177 6.2 Binding Maps and Coarse -Grained Modeling 180 6.3 QSPR for Either Classification or Quantification Prediction 188 6.4 All Atoms MD Simulations for Free Solution Studies and Surfaces 192 6.5 Ensemble Average and Comparison of Binding of Different Proteins in Chromatographic Systems 204 6.6 Antibody Homology Modeling and Bioprocess Development 205 6.7 Summary of Gaps and Future State 209 Acknowledgment 212 References 212 7 Chromatographic Scale -Up on a Volume Basis 227 Ernst B. Hansen 7.1 Introduction 227 7.2 Theoretical Background 229 7.3 Proof of Concept Examples 232 7.4 Design Applications: How to Scale up from Development Data 233 7.5 Discussion 240 7.6 Recommendations 242 References 245 8 Scaling Up Industrial Protein Chromatography: Where Modeling Can Help 247 Chris Antoniou, Justin McCue, Venkatesh Natarajan, Joerg Thoemmes, and Qing Sarah Yuan 8.1 Introduction 247 8.2 Packing Quality: Why and How to Ensure Column Packing Quality Across Scales 248 8.3 Process Equipment: Using CFD to Describe Effects of Equipment Design on Column Performance 257 8.4 Long -Term Column Operation at Scale: Impact of Resin Lot -to -Lot Variability 264 8.5 Closing Remarks 265 References 265 9 High -Throughput Process Development 269 Silvia M. Pirrung and Marcel Ottens 9.1 Introduction to High -Throughput Process Development in Chromatography 269 9.2 Process Development Approaches 271 9.3 Case Descriptions 279 9.4 Future Directions 286 References 286 10 High -Throughput Column Chromatography Performed on Liquid Handling Stations 293 Patrick Diederich and Jurgen Hubbuch 10.1 Introduction 293 10.2 Chromatographic Methods 299 10.3 Results and Discussion 300 10.4 Summary and Conclusion 328 Acknowledgements 329 References 330 11 Lab -Scale Development of Chromatography Processes 333 Hong Li, Jennifer Pollard, and Nihal Tugcu 11.1 Introduction 333 11.2 Methodology and Proposed Workflow 336 11.3 Conclusions 377 Acknowledgments 377 References 377 12 Problem Solving by Using Modeling 381 Martin P. Breil, Soren S. Frederiksen, Steffen Kidal, and Thomas B. Hansen 12.1 Introduction 381 12.2 Theory 382 12.3 Materials and Methods 385 12.4 Determination of Model Parameters 385 12.5 Optimization In Silico 388 12.6 Extra -Column Effects 390 Abbreviations 397 References 398 13 Modeling Preparative Cation Exchange Chromatography of Monoclonal Antibodies 399 Stephen Hunt, Trent Larsen, and Robert J. Todd 13.1 Introduction 399 13.2 Theory 401 13.3 Model Development 403 13.4 Model Application 413 13.5 Conclusions 424 Nomenclature 425 Greek letters 425 References 426 14 Model -Based Process Development in the Biopharmaceutical Industry 429 Lars Sejergaard, Haleh Ahmadian, Thomas B. Hansen, Arne Staby, and Ernst B. Hansen 14.1 Introduction 429 14.2 Molecule-FVIII 430 14.3 Overall Process Design 431 14.4 Use of Mathematical Models to Ensure Process Robustness 432 14.5 Experimental Design of Verification Experiments 435 14.6 Discussion 438 14.7 Conclusion 439 Acknowledgements 439 Appendix 14.A Practical MATLAB Guideline to SEC 439 Appendix 14.B Derivation of Models Used for Column Simulations 449 References 455 15 Dynamic Simulations as a Predictive Model for a Multicolumn Chromatography Separation 457 Marc Bisschops and Mark Brower 15.1 Introduction 457 15.2 BioSMB Technology 459 15.3 Protein A Model Description 460 15.4 Fitting the Model Parameters 463 15.5 Case Studies 464 15.6 Results for Continuous Chromatography 469 15.7 Conclusions 475 References 476 16 Chemometrics Applications in Process Chromatography 479 Anurag S. Rathore and Sumit K. Singh 16.1 Introduction 479 16.2 Data Types 480 16.3 Data Preprocessing 481 16.4 Modeling Approaches 485 16.5 Case Studies of Use of Chemometrics in Process Chromatography 490 16.6 Guidance on Performing MVDA 495 References 497 17 Mid -UV Protein Absorption Spectra and Partial Least Squares Regression as Screening and PAT Tool 501 Sigrid Hansen, Nina Brestrich, Arne Staby, and Jurgen Hubbuch 17.1 Introduction 501 17.2 Mid -UV Protein Absorption Spectra and Partial Least Squares Regression 503 17.3 Spectral Similarity and Prediction Precision 511 17.4 Application as a Screening Tool: Analytics for High -Throughput Experiments 516 17.5 Application as a PAT Tool: Selective In -line Quantification and Real -Time Pooling 518 17.6 Case Studies 523 17.7 Conclusion and Outlook 532 References 532 18 Recent Progress Toward More Sustainable Biomanufacturing: Practical Considerations for Use in the Downstream Processing of Protein Products 537 Milton T. W. Hearn 18.1 Introduction 537 18.2 The Impact of Individualized Unit Operations versus Integrated Platform Technologies on Sustainable Manufacturing 543 18.3 Implications of Recycling and Reuse in Downstream Processing of Protein Products Generated by Biotechnological Processes: General Considerations 549 18.4 Metrics and Valorization Methods to Assess Process Sustainability 553 18.5 Conclusions and Perspectives 573 Acknowledgment 573 References 574 Index 583