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PREFACE <br> <br> Volume 1<br> <br> PART ONE: Upstream Technologies<br> <br> STRATEGIES FOR PLASMID DNA PRODUCTION IN ESCHERICHIA COLI <br> Introduction<br> Requirements for a Plasmid DNA Production Process<br> Structure of a DNA Vaccine Production Process <br> Choice of Antigen <br> Vector DNA Construct <br> Host Strains <br> Cultivation Medium and Process Conditions <br> Lysis/Extraction of Plasmid DNA <br> Purification <br> Formulation<br> Conclusions<br> <br> ADVANCES IN PROTEIN PRODUCTION TECHNOLOGIES <br> Introduction <br> Glycoengineering for Homogenous Human-Like Glycoproteins <br> Bacteria as Protein Factories <br> Mammalian Cell Technology <br> Yeast Protein Production <br> Baculovirus -<br> Insect Cell Technology <br> Transgenic Animal Protein Production <br> Plant Molecular Farming <br> Cell-Free Protein Production <br> Future Prospects <br> <br> PART TWO: Protein Recovery<br> <br> RELEASING BIOPHARMACEUTICAL PRODUCTS FROM CELLS <br> Introduction <br> Cell Structure and Strategies for Disruption <br> Cell Mechanical Strength <br> Homogenization <br> Bead Milling <br> Chemical Treatment <br> Cellular Debris <br> Conclusions <br> <br> CONTINUOUS CHROMATOGRAPHY (MULTICOLUMN COUNTERCURRENT SOLVENT GRADIENT PURIFI CATION) FOR PROTEIN <br> PURIFI CATION <br> Introduction <br> Overview of Continuous Chromatographic Processes <br> Principles of MCSGP <br> Application Examples of MCSGP <br> Enabling Features and Economic Impact of MCSGP <br> Annex 1: Chromatographic Process Decision Tree <br> <br> VIRUS-LIKE PARTICLE BIOPROCESSING <br> Introduction <br> Upstream Processing <br> Downstream Processing <br> Analysis <br> Conclusions <br> Nomenclature <br> <br> THERAPEUTIC PROTEIN STABILITY AND FORMULATION <br> Introduction <br> Protein Stability <br> Formulation and Materials <br> Screening Methods <br> Accelerated and Long-Term Stability Testing <br> Analytical Techniques for Stability Testing <br> Conclusions <br> <br> PRODUCTION OF PEGYLATED PROTEINS <br> Introduction <br> General Considerations<br> PEGylation Chemistry <br> PEGylated Protein Purification<br> Conclusions<br> <br> PART THREE: Advances in Process Development <br> <br> AFFINITY CHROMATOGRAPHY: HISTORICAL AND PROSPECTIVE OVERVIEW <br> History and Role of Affinity Chromatography in the Separation Sciences <br> Overview of Affinity Chromatography: Theory and Methods<br> Affinity Ligands <br> Affinity Ligands in Practice: Biopharmaceutical Production <br> Conclusions and Future Perspectives <br> <br> HYDROXYAPATITE IN BIOPROCESSING <br> Introduction <br> Materials and Interaction Mechanisms <br> Setting up a Separation<br> Separation Examples <br> Conclusions <br> <br> MONOLITHS IN BIOPROCESSING <br> Introduction<br> Properties of Chromatographic Monoliths <br> Monolithic Analytical Columns for Process Analytical Technology Applications <br> Monoliths for Preparative Chromatography <br> Enzyme Reactors <br> Conclusions <br> <br> MEMBRANE CHROMATOGRAPHY FOR BIOPHARMACEUTICAL MANUFACTURING <br> Membrane Adsorbers -<br> Introduction and Technical Specifications <br> Comparing Resins and Membrane Adsorbers<br> Membrane Chromatography Applications and Case Studies<br> Conclusions <br> <br> MODELING AND EXPERIMENTAL MODEL PARAMETER DETERMINATION WITH QUALITY BY DESIGN FOR BIOPROCESSES <br> Introduction <br> QbD Fundamentals <br> Process Modeling and Experimental Model Parameter Determination <br> Process Robustness Study <br> Conclusions <br> Nomenclature <br> <br> Volume 2<br> <br> PART FOUR: Analytical Technologies <br> <br> BIOSENSORS IN THE PROCESSING AND ANALYSIS OF BIOPHARMACEUTICALS <br> Introduction <br> Principles and Commercial Applications of Biosensors <br> Use of Biosensors in Biopharmaceutical Production and Processing <br> Conclusions <br> <br> PROTEOMICS TOOLKIT: APPLICATIONS IN PROTEIN BIOLOGICAL PRODUCTION AND METHOD DEVELOPMENT <br> Introduction<br> Applications of Proteomics <br> Myths and Misconceptions -<br> Perceived Drawbacks of Proteomics <br> Critical Factors for Industrialization of Proteomics <br> Case Studies <br> Conclusions <br> <br> SCIENCE OF PROTEOMICS: HISTORICAL PERSPECTIVES AND POSSIBLE ROLE IN HUMAN HEALTHCARE <br> Science of 'Omics' <br> Major Advances in Biology That Led to the Sciences of 'Omics'<br> Mendel's Principles of Inheritance <br> One Gene/One Enzyme Concept of Beadle and Tatum <br> Watson -<br> Crick Structure of DNA <br> Development of Different Technologies Responsible for the Emergence of Genomics and Proteomics <br> Genomics <br> Proteomics <br> Interactomics: Complexity of an Organism Based on the Interactions of Proteins <br> Relation between Diseases, Genes, and Proteins: Diseasome Concept <br> Proteins as Biomarkers of Human Diseases<br> Metabolomics <br> Proteomics and Drug Discovery <br> Current and Future Benefits of Proteomics in Human Healthcare <br> <br> PART FIVE: Quality Control <br> <br> CONSISTENCY OF SCALE-UP FROM BIOPROCESS DEVELOPMENT TO PRODUCTION <br> Inhomogeneities in Industrial Fed-Batch Processes <br> Effects of Conditions in Industrial-Scale Fed-Batch Processes on the Main Carbon Metabolism <br> Effects of Conditions in Industrial-Scale Fed-Batch Processes on Amino Acid Synthesis <br> Scale-Down Reactors for Imitating Large-Scale Fed-Batch Process Conditions at the Laboratory Scale <br> Improved Two-Compartment Reactor System to Imitate Large-Scale Conditions at the Laboratory Scale <br> Description of the Hydrodynamic Conditions in the PFR Part of the Presented Two-Compartment Reactor <br> Description of Oxygen Transfer in the PFR Part of the Two-Compartment Reactor <br> E. coli Fed-Batch Cultivations in the Two-Compartment Reactor System <br> Future Perspectives for the Application of a Two-Compartment Reactor <br> <br> SYSTEMATIC APPROACH TO OPTIMIZATION AND COMPARABILITY OF BIOPHARMACEUTICAL GLYCOSYLATION THROUGHOUT THE DRUG LIFE CYCLE <br> Costs of Inconsistent, Unoptimized Drug Glycosylation <br> Scheme 1: Traditional Approach to Comparability of Drug Glycosylation <br> Scheme 2: Comparability of Drug Glycosylation Using QbD DS <br> Scheme 3: Enhanced QbD Approach to Comparability of Drug Glycosylation <br> Conclusions <br> <br> QUALITY AND RISK MANAGEMENT IN ENSURING THE VIRUS SAFETY OF BIOPHARMACEUTICALS <br> Introduction <br> QRM and Virus Safety <br> Pillars of Safety <br> Committee for Proprietary Medicinal Products Guidelines for Investigational Medicinal Products -<br> Risk Management in Practice <br> Developing a Robust Risk Minimization Strategy -<br> What Is the Correct Paradigm? <br> <br> ENSURING QUALITY AND EFFI CIENCY OF BIOPROCESSES BY THE TAILORED APPLICATION OF PROCESS ANALYTICAL TECHNOLOGY AND QUALITY BY DESIGN <br> Introduction <br> PAT and QbD in Bioprocessing -<br> Engineering Meets Biology <br> Aspects of Biological Demands -<br> Selected Examples <br> Technical and Engineering Solutions <br> Conclusions <br> <br> PART SIX: Process Design and Management <br> <br> BIOPROCESS DESIGN AND PRODUCTION TECHNOLOGY FOR THE FUTURE <br> Introduction <br> Analysis of Biomanufacturing Technologies <br> AAC: Anything and Chromatography <br> Process Integration <br> Process Design and QbD <br> Package Unit Engineering and Standardization <br> Downstream of Downstream Processing <br> Conclusions <br> <br> INTEGRATED PROCESS DESIGN: CHARACTERIZATION OF PROCESS AND PRODUCT DEFINITION OF DESIGN SPACES <br> Introductory Principles <br> Original Process Development Paradigm <br> The Essential QbD Concepts <br> Conclusion <br> <br> EVALUATING AND VISUALIZING THE COST-EFFECTIVENESS AND ROBUSTNESS OF BIOPHARMACEUTICAL MANUFACTURING STRATEGIES <br> Introduction <br> Scope of Research on Decision-Support Tools for the Biotech Sector <br> Capturing Process Robustness Under Uncertainty <br> Reconciling Multiple Conflicting Outputs Under Uncertainty <br> Searching Large Decision Spaces Efficiently <br> Integrating Stochastic Simulation with Multivariate Analysis <br> Conclusions<br> <br> PART SEVEN: Changing Face of Processing <br> <br> FULL PLASTICS: CONSEQUENT EVOLUTION IN PHARMACEUTICAL BIOMANUFACTURING<br> FROM VIAL TO WAREHOUSE <br> Increased Demand, Reduced Volumes, and Maximum Flexibility -<br> Driving Force to Plastic Devices <br> Plastic - The Flexible All-Round Replacer: From Material to Function <br> Pollution with Plastics: Leachables and Extractables <br> Plastics for Storage: Vial and Bag<br> Plastics for Cultivation: Flask, Tube, and Unstirred and Stirred Bioreactor <br> Plastics for Purification: Column and Membrane <br> Case Study: Comparability of Plastic Bag-Based Bioreactors in Cultivation Processes <br> Conclusions and Prospects <br> <br> BIOSMB -<br> TECHNOLOGY: CONTINUOUS COUNTERCURRENT CHROMATOGRAPHY ENABLING A FULLY DISPOSABLE PROCESS <br> Introduction <br> Continuous Chromatography in Biopharmaceutical Industries<br> Process Design Principles <br> Case Studies <br> Conclusions <br> <br> SINGLE-USE TECHNOLOGY: OPPORTUNITIES IN BIOPHARMACEUTICAL PROCESSES <br> Current Single-Use Technologies <br> Future Single-Use Operations <br> Automation Requirements in Single-Use Manufacturing <br> Qualification and Validation Expectations <br> Operator Training <br> <br> SINGLE-USE BIOTECHNOLOGIES AND MODULAR MANUFACTURING ENVIRONMENTS INVITE PARADIGM SHIFTS IN BIOPROCESS DEVELOPMENT AND BIOPHARMACEUTICAL MANUFACTURING <br> Introduction <br> Paradigm Shift at Crucell<br> Conclusions and General Outlook <br>

Dr. Ganapathy Subramanian is a biotechnology consultant with over 30 years experience in industry and academia, encompassing the application and development of processing, purification methodologies, and chromatographic systems for largescale use in environmental science, food science, perfumery, cosmetics, and pharmaceuticals. He has also taught extensively in the area of food and medical technology.<br> <br> A chemistry graduate from Madras, India, Dr. Subramanian was awarded his doctorate, from the University of Glasgow, for work on natural products. His main research interests lie in the utilization of natural material separation processes and bioconversions.<br> <br> Dr. Subramanian has written and edited a number of books and articles in the field of biotechnology. For the last 10 years, he has been organizing conferences promoting the integration and sharing of knowledge between academia and industry.

Cost-effective manufacturing of biopharmaceutical products is rapidly gaining in importance, while healthcare systems across the globe are looking to contain costs and improve efficiency. To adapt to these changes, industries need to review and streamline their manufacturing processes.<br> <br> This two volume handbook systematically addresses the key steps and challenges in the production process and provides valuable information for medium to large scale producers of biopharmaceuticals. <br> <br> It is divided into seven major parts:<br> - Upstream Technologies<br> - Protein Recovery<br> - Advances in Process Development<br> - Analytical Technologies<br> - Quality Control<br> - Process Design and Management<br> - Changing Face of Processing<br> <br> With contributions by around 40 experts from academia as well as small and large biopharmaceutical companies, this unique handbook is full of first-hand knowledge on how to produce biopharmaceuticals in a cost-effective and quality-controlled manner.

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