Cell And Gene Therapy Manufacturing Process

  cell and gene therapy manufacturing process: Cell Therapy Adrian Gee, 2009-09-18 Cell Therapy: cGMP Facilities and Manufacturing is the source for a complete discussion of facility design and operation with practical approaches to a variety of day-to-day activities, such as staff training and competency, cleaning procedures, and environmental monitoring. This in-depth book also includes detailed reviews of quality, the framework of regulations, and professional standards. It meets a previously unmet need for a thorough facility-focused resource, Cell Therapy: cGMP Facilities and Manufacturing will be an important addition to the cell therapy professional’s library. Additional topics in Cell Therapy: cGMP Facilities and Manufacturing...Standard operating procedures - Supply management - Facility equipment - Product manufacturing, review, release and administration - Facility master file.
  cell and gene therapy manufacturing process: Stem Cell Manufacturing Joaquim M.S. Cabral, Claudia Lobato da Silva, Lucas G. Chase, M. Margardia Diogo, 2016-07-24 Stem Cell Manufacturing discusses the required technologies that enable the transfer of the current laboratory-based practice of stem cell tissue culture to the clinic environment as therapeutics, while concurrently achieving control, reproducibility, automation, validation, and safety of the process and the product. The advent of stem cell research unveiled the therapeutic potential of stem cells and their derivatives and increased the awareness of the public and scientific community for the topic. The successful manufacturing of stem cells and their derivatives is expected to have a positive impact in the society since it will contribute to widen the offer of therapeutic solutions to the patients. Fully defined cellular products can be used to restore the structure and function of damaged tissues and organs and to develop stem cell-based cellular therapies for the treatment of cancer and hematological disorders, autoimmune and other inflammatory diseases and genetic disorders. - Presents the first 'Flowchart' of stem cell manufacturing enabling easy understanding of the various processes in a sequential and coherent manner - Covers all bioprocess technologies required for the transfer of the bench findings to the clinic including the process components: cell signals, bioreactors, modeling, automation, safety, etc. - Presents comprehensive coverage of a true multidisciplinary topic by bringing together specialists in their particular area - Provides the basics of the processes and identifies the issues to be resolved for large scale cell culture by the bioengineer - Addresses the critical need in bioprocessing for the successful delivery of stem cell technology to the market place by involving professional engineers in sections of the book
  cell and gene therapy manufacturing process: Ex Vivo Cell Therapy Klaus Schindhelm, Robert Nordon, 1999 R.E. Nordon and K. Schindhelm, Introduction. -- L. Robb, A.G. Elefanty, and C.G. Begley, Transcriptional Control of Hematopoieses. -- R. Starr and N.A. Nicola, Cell Signaling by Hemopoietic Growth Factor Receptors. -- P.J. Simmons, D.N. Haylock, and J.-P. Lévesque, Influence of Cytokines and Adhesion Molecules on Hematopoietic Stem Cell Development. -- P.A. Rowlings, Allogeneic Hematopoietic Stem Cell Transplantation. -- U. Hahn and L.B. To, Autologous Stem Cell Transplantation. -- M.R. Vowels, Cord Blood Stem Cell Transplantation. -- S.R. Riddell, E.H. Warren, D. Lewinsohn, C. Yee, and P.D. Greenberg, Reconstitution of Immunity by Adoptive Immunotherapy with T Cells. -- L.Q. Sun, M. Miller, and G. Symonds, Exogenous Gene Transfer into Lymphoid and Hematopoietic Progenitor Cells. -- C. Dowding, T. Leemhuis, A. Jakubowski, and C. Reading, Process Development for Ex Vivo Cell Therapy. -- R.E. Nordon and K. Schindhelm, Cell Separation. -- P.W. Zandstra, C.J. Eaves, and J.M. Piret, Environ ...
  cell and gene therapy manufacturing process: Cell and Gene Therapies Miguel-Angel Perales, Syed A. Abutalib, Catherine Bollard, 2018-11-27 In this book, experts in the field express their well-reasoned opinions on a range of complex, clinically relevant issues across the full spectrum of cell and gene therapies with the aim of providing trainee and practicing hematologists, including hematopoietic transplant physicians, with information that is relevant to clinical practice and ongoing research. Each chapter focuses on a particular topic, and the concise text is supported by numerous working tables, algorithms, and figures. Whenever appropriate, guidance is provided regarding the availability of potentially high-impact clinical trials. The rapid evolution of cell and gene therapies is giving rise to numerous controversies that need to be carefully addressed. In meeting this challenge, this book will appeal to all residents, fellows, and faculty members responsible for the care of hematopoietic cell transplant patients. It will also offer a robust, engaging tool to aid vital activities in the daily work of every hematology and oncology trainee.
  cell and gene therapy manufacturing process: Regulatory Aspects of Gene Therapy and Cell Therapy Products Maria Cristina Galli, Mercedes Serabian, 2015-09-15 This book discusses the different regulatory pathways for gene therapy (GT) and cell therapy (CT) medicinal products implemented by national and international bodies throughout the world (e.g. North and South America, Europe, and Asia). Each chapter, authored by experts from various regulatory bodies throughout the international community, walks the reader through the applications of nonclinical research to translational clinical research to licensure for these innovative products. More specifically, each chapter offers insights into fundamental considerations that are essential for developers of CT and GT products, in the areas of product manufacturing, pharmacology and toxicology, and clinical trial design, as well as pertinent must-know guidelines and regulations. Regulatory Aspects of Gene Therapy and Cell Therapy Products: A Global Perspective is part of the American Society of Gene and Cell Therapy sub-series of the highly successful Advances in Experimental Medicine and Biology series. It is essential reading for graduate students, clinicians, and researchers interested in gene and cell therapy and the regulation of pharmaceuticals.
  cell and gene therapy manufacturing process: The EBMT/EHA CAR-T Cell Handbook Nicolaus Kröger, John Gribben, Christian Chabannon, Ibrahim Yakoub-Agha, Hermann Einsele, 2022-02-07 This first open access European CAR-T Handbook, co-promoted by the European Society for Blood and Marrow Transplantation (EBMT) and the European Hematology Association (EHA), covers several aspects of CAR-T cell treatments, including the underlying biology, indications, management of side-effects, access and manufacturing issues. This book, written by leading experts in the field to enhance readers’ knowledge and practice skills, provides an unparalleled overview of the CAR-T cell technology and its application in clinical care, to enhance readers’ knowledge and practice skills.
  cell and gene therapy manufacturing process: The Challenge of CMC Regulatory Compliance for Biopharmaceuticals John Geigert, 2019-05-08 Biopharmaceuticals (i.e., biological medicines sourced from genetically-engineered living systems) for treatment of human diseases have become a significant percentage of the pharmaceutical industry. And not just the recombinant DNA-derived proteins and monoclonal antibodies (both from the innovators and biosimilars); but now, an increasing awareness of the importance of gene therapy and genetically engineered cellular medicinal products. These biopharmaceuticals are being developed by many companies whose Chemistry, Manufacturing & Control (CMC) teams have varying degrees of familiarity or experience with the CMC strategy and regulatory compliance requirements for these challenging products. Companies clearly plan out the strategy for their clinical study plans, but frequently, the development of a strategy for CMC is an afterthought. Coupled with the complexity of the biopharmaceutical manufacturing processes and products, and this can be a recipe for disaster. The third edition of this book provides insights and practical guidance for the CMC teams to develop an acceptable cost-effective, risk-based CMC regulatory compliance strategy for all biopharmaceuticals (recombinant proteins, monoclonal antibodies, genetically engineered viruses and genetically engineered human cells) from early clinical stage development through market approval. The third edition of this book provides added coverage for the biosimilars, antibody drug conjugates (ADCs), bispecific antibodies, genetically engineered viruses, and genetically engineered cells. This third edition of the book also addresses the heightened pressure on CMC regulatory compliance timelines due to the introduction of expedited clinical pathways moving the clinical development closer to a seamless phase process (e.g., FDA Breakthrough Therapy designation, CBER Regenerative Medicine Advanced Therapy (RMAT) designation, EMA Priority Medicines (PRIME) designation). The Challenge of CMC Regulatory Compliance for Biopharmaceuticals is essential, practical information for all pharmaceutical development scientists, Manufacturing and Quality Unit staff, Regulatory Affairs personnel, and senior management involved in the manufacture of biopharmaceuticals.
  cell and gene therapy manufacturing process: Exploring Novel Clinical Trial Designs for Gene-Based Therapies National Academies of Sciences, Engineering, and Medicine, Health and Medicine Division, Board on Health Sciences Policy, Forum on Regenerative Medicine, 2020-08-27 Recognizing the potential design complexities and ethical issues associated with clinical trials for gene therapies, the Forum on Regenerative Medicine of the National Academies of Sciences, Engineering, and Medicine held a 1-day workshop in Washington, DC, on November 13, 2019. Speakers at the workshop discussed patient recruitment and selection for gene-based clinical trials, explored how the safety of new therapies is assessed, reviewed the challenges involving dose escalation, and spoke about ethical issues such as informed consent and the role of clinicians in recommending trials as options to their patients. The workshop also included discussions of topics related to gene therapies in the context of other available and potentially curative treatments, such as bone marrow transplantation for hemoglobinopathies. This publication summarizes the presentation and discussion of the workshop.
  cell and gene therapy manufacturing process: Somatic Gene Therapy P.L. Chang, 2018-01-17 As human gene therapy becomes a clinical reality, a new era in medicine dawns. Novel and innovative developments in molecular genetics now provide opportunities to treat the genetic bases of diseases often untreatable before. Somatic Gene Therapy documents these historical clinical trials, reviews current advances in the field, evaluates the use of the many different cell types and organs amenable to gene transfer, and examines the prospects of various exciting strategies for gene therapy.
  cell and gene therapy manufacturing process: A Handbook of Gene and Cell Therapy Clévio Nóbrega, Liliana Mendonça, Carlos A. Matos, 2020-06-27 This is a reference handbook for young researchers exploring gene and cell therapy. Gene therapy could be defined as a set of strategies modifying gene expression or correcting mutant/defective genes through the administration of DNA (or RNA) to cells, in order to treat disease. Important advances like the discovery of RNA interference, the completion of the Human Genome project or the development of induced pluripotent stem cells (iPSc) and the basics of gene therapy are covered. This is a great book for students, teachers, biomedical researchers delving into gene/cell therapy or researchers borrowing skills from this scientific field.
  cell and gene therapy manufacturing process: Operations Research and Health Care Margaret L. Brandeau, Francois Sainfort, William P. Pierskalla, 2006-04-04 In both rich and poor nations, public resources for health care are inadequate to meet demand. Policy makers and health care providers must determine how to provide the most effective health care to citizens using the limited resources that are available. This chapter describes current and future challenges in the delivery of health care, and outlines the role that operations research (OR) models can play in helping to solve those problems. The chapter concludes with an overview of this book – its intended audience, the areas covered, and a description of the subsequent chapters. KEY WORDS Health care delivery, Health care planning HEALTH CARE DELIVERY: PROBLEMS AND CHALLENGES 3 1.1 WORLDWIDE HEALTH: THE PAST 50 YEARS Human health has improved significantly in the last 50 years. In 1950, global life expectancy was 46 years [1]. That figure rose to 61 years by 1980 and to 67 years by 1998 [2]. Much of these gains occurred in low- and middle-income countries, and were due in large part to improved nutrition and sanitation, medical innovations, and improvements in public health infrastructure.
  cell and gene therapy manufacturing process: A Guide to Human Gene Therapy Roland W. Herzog, Sergei Zolotukhin, 2010 1. Non-viral gene therapy / Sean M. Sullivan -- 2. Adenoviral vectors / Stuart A. Nicklin and Andrew H. Baker -- 3. Retroviral vectors and integration analysis / Cynthia C. Bartholomae [und weitere] -- 4. Lentiviral vectors / Janka Matrai, Marinee K.L. Chuah and Thierry VandenDriessche -- 5. Herpes simplex virus vectors / William F. Goins [und weitere] -- 6. Adeno-Associated Viral (AAV) vectors / Nicholas Muzyczka -- 7. Regulatory RNA in gene therapy / Alfred. S. Lewin -- 8. DNA integrating vectors (Transposon, Integrase) / Lauren E. Woodard and Michele P. Calos -- 9. Homologous recombination and targeted gene modification for gene therapy / Matthew Porteus -- 10. Gene switches for pre-clinical studies in gene therapy / Caroline Le Guiner [und weitere] -- 11. Gene therapy for central nervous system disorders / Deborah Young and Patricia A. Lawlor -- 12. Gene therapy of hemoglobinopathies / Angela E. Rivers and Arun Srivastava -- 13. Gene therapy for primary immunodeficiencies / Aisha Sauer, Barbara Cassani and Alessandro Aiuti -- 14. Gene therapy for hemophilia / David Markusic, Babak Moghimi and Roland Herzog -- 15. Gene therapy for obesity and diabetes / Sergei Zolotukhin and Clive H. Wasserfall -- 16. Gene therapy for Duchenne muscular dystrophy / Takashi Okada and Shin'ichi Takeda -- 17. Cancer gene therapy / Kirsten A.K. Weigel-Van Aken -- 18. Gene therapy for autoimmune disorders / Daniel F. Gaddy, Melanie A. Ruffner and Paul D. Robbins -- 19. Gene therapy for inherited metabolic storage diseases / Cathryn Mah -- 20. Retinal diseases / Shannon E. Boye, Sanford L. Boye and William W. Hauswirth -- 21. A brief guide to gene therapy treatments for pulmonary diseases / Ashley T. Martino, Christian Mueller and Terence R. Flotte -- 22. Cardiovascular disease / Darin J. Falk, Cathryn S. Mah and Barry J. Byrne
  cell and gene therapy manufacturing process: Pharmaceutical Biotechnology Daan J. A. Crommelin, Robert D. Sindelar, 2002-11-14 The field of pharmaceutical biotechnology is evolving rapidly. A whole new arsenal of protein pharmaceuticals is being produced by recombinant techniques for cancer, viral infections, cardiovascular and hereditary disorders, and other diseases. In addition, scientists are confronted with new technologies such as polymerase chain reactions, combinatorial chemistry and gene therapy. This introductory textbook provides extensive coverage of both the basic science and the applications of biotechnology-produced pharmaceuticals, with special emphasis on their clinical use. Pharmaceutical Biotechnology serves as a complete one-stop source for undergraduate pharmacists, and it is valuable for researchers and professionals in the pharmaceutical industry as well.
  cell and gene therapy manufacturing process: Mesenchymal Stem Cell Therapy Lucas G. Chase, Mohan C Vemuri, 2012-12-12 Over the past decade, significant efforts have been made to develop stem cell-based therapies for difficult to treat diseases. Multipotent mesenchymal stromal cells, also referred to as mesenchymal stem cells (MSCs), appear to hold great promise in regards to a regenerative cell-based therapy for the treatment of these diseases. Currently, more than 200 clinical trials are underway worldwide exploring the use of MSCs for the treatment of a wide range of disorders including bone, cartilage and tendon damage, myocardial infarction, graft-versus-host disease, Crohn’s disease, diabetes, multiple sclerosis, critical limb ischemia and many others. MSCs were first identified by Friendenstein and colleagues as an adherent stromal cell population within the bone marrow with the ability to form clonogenic colonies in vitro. In regards to the basic biology associated with MSCs, there has been tremendous progress towards understanding this cell population’s phenotype and function from a range of tissue sources. Despite enormous progress and an overall increased understanding of MSCs at the molecular and cellular level, several critical questions remain to be answered in regards to the use of these cells in therapeutic applications. Clinically, both autologous and allogenic approaches for the transplantation of MSCs are being explored. Several of the processing steps needed for the clinical application of MSCs, including isolation from various tissues, scalable in vitro expansion, cell banking, dose preparation, quality control parameters, delivery methods and numerous others are being extensively studied. Despite a significant number of ongoing clinical trials, none of the current therapeutic approaches have, at this point, become a standard of care treatment. Although exceptionally promising, the clinical translation of MSC-based therapies is still a work in progress. The extensive number of ongoing clinical trials is expected to provide a clearer path forward for the realization and implementation of MSCs in regenerative medicine. Towards this end, reviews of current clinical trial results and discussions of relevant topics association with the clinical application of MSCs are compiled in this book from some of the leading researchers in this exciting and rapidly advancing field. Although not absolutely all-inclusive, we hope the chapters within this book can promote and enable a better understanding of the translation of MSCs from bench-to-bedside and inspire researchers to further explore this promising and quickly evolving field.
  cell and gene therapy manufacturing process: Gene Therapy of the Central Nervous System: From Bench to Bedside Michael G. Kaplitt, Matthew During, 2006 Few areas of biomedical research provide greater opportunities to capitalize upon the revolution in genomics and molecular biology than gene therapy. This is particularly true for the brain and nervous system, where gene transfer has become a key technology for basic research and has recently been translated to human therapy in several landmark clinical trials. Gene Therapy in the Brain: From Bench to Bedside represents the definitive volume on this subject. Edited by two pioneers of neurological gene therapy, this volume contains contributions by leaders who helped to create the field as well as those who are expanding the promise of gene therapy for the future of basic and clinical neuroscience. Drawing upon this extensive collective experience, this book provides clear and informative reviews on a variety of subjects which would be of interest to anyone who is currently using or contemplating exploring gene therapy for neurobiological applications. Basic gene transfer technologies are discussed, with particular emphases upon novel vehicles, immunological issues and the role of gene therapy in stem cells. Numerous research applications are reviewed, particularly in complex fields such as behavioral neurobiology. Several preclinical areas are also covered which are likely to translate into clinical studies in the near future, including epilepsy, pain and amyotrophic lateral sclerosis. Among the most exciting advances in recent years has been the use of neurological gene therapy in human clinical trials, including Parkinson's disease, Canavan disease and Batten disease. Finally, readers will find insider information on technological and regulatory issues which can often limit effective translation of even the most promising idea into clinical use. This work provides up-to-date information and key insights into those gene therapy issues which are important to both scientists and clinicians focusing upon the brain and central nervous system.
  cell and gene therapy manufacturing process: Biodefense in the Age of Synthetic Biology National Academies of Sciences, Engineering, and Medicine, Division on Earth and Life Studies, Board on Life Sciences, Board on Chemical Sciences and Technology, Committee on Strategies for Identifying and Addressing Potential Biodefense Vulnerabilities Posed by Synthetic Biology, 2019-01-05 Scientific advances over the past several decades have accelerated the ability to engineer existing organisms and to potentially create novel ones not found in nature. Synthetic biology, which collectively refers to concepts, approaches, and tools that enable the modification or creation of biological organisms, is being pursued overwhelmingly for beneficial purposes ranging from reducing the burden of disease to improving agricultural yields to remediating pollution. Although the contributions synthetic biology can make in these and other areas hold great promise, it is also possible to imagine malicious uses that could threaten U.S. citizens and military personnel. Making informed decisions about how to address such concerns requires a realistic assessment of the capabilities that could be misused. Biodefense in the Age of Synthetic Biology explores and envisions potential misuses of synthetic biology. This report develops a framework to guide an assessment of the security concerns related to advances in synthetic biology, assesses the levels of concern warranted for such advances, and identifies options that could help mitigate those concerns.
  cell and gene therapy manufacturing process: Human Genome Editing National Academies of Sciences, Engineering, and Medicine, National Academy of Medicine, National Academy of Sciences, Committee on Human Gene Editing: Scientific, Medical, and Ethical Considerations, 2017-08-13 Genome editing is a powerful new tool for making precise alterations to an organism's genetic material. Recent scientific advances have made genome editing more efficient, precise, and flexible than ever before. These advances have spurred an explosion of interest from around the globe in the possible ways in which genome editing can improve human health. The speed at which these technologies are being developed and applied has led many policymakers and stakeholders to express concern about whether appropriate systems are in place to govern these technologies and how and when the public should be engaged in these decisions. Human Genome Editing considers important questions about the human application of genome editing including: balancing potential benefits with unintended risks, governing the use of genome editing, incorporating societal values into clinical applications and policy decisions, and respecting the inevitable differences across nations and cultures that will shape how and whether to use these new technologies. This report proposes criteria for heritable germline editing, provides conclusions on the crucial need for public education and engagement, and presents 7 general principles for the governance of human genome editing.
  cell and gene therapy manufacturing process: Muscle Gene Therapy Dongsheng Duan, 2009-11-26 Muscle disease represents an important health threat to the general population. There is essentially no cure. Gene therapy holds great promise to correct the genetic defects and eventually achieve full recovery in these diseases. Significant progresses have been made in the field of muscle gene therapy over the last few years. The development of novel gene delivery vectors has substantially enhanced specificity and efficiency of muscle gene delivery. The new knowledge on the immune response to viral vectors has added new insight in overcoming the immune obstacles. Most importantly, the field has finally moved from small experimental animal models to human patients. This book will bring together the leaders in the field of muscle gene transfer to provide an updated overview on the progress of muscle gene therapy. It will also highlight important clinical applications of muscle gene therapy.
  cell and gene therapy manufacturing process: Cell Culture Engineering Wei-Shu Hu, 2006-08-16 Since the introduction of recombinant human growth hormone and insulin a quarter century ago, protein therapeutics has greatly broadened the ho- zon of health care. Many patients suffering with life-threatening diseases or chronic dysfunctions, which were medically untreatable not long ago, can attest to the wonder these drugs have achieved. Although the ?rst generation of p- tein therapeutics was produced in recombinant Escherichia coli, most recent products use mammalian cells as production hosts. Not long after the ?rst p- duction of recombinant proteins in E. coli, it was realized that the complex tasks of most post-translational modi?cations on proteins could only be ef?ciently carried out in mammalian cells. In the 1990s, we witnessed a rapid expansion of mammalian-cell-derived protein therapeutics, chie?y antibodies. In fact, it has been nearly a decade since the market value of mammalian-cell-derived protein therapeutics surpassed that of those produced from E. coli. A common characteristic of recent antibody products is the relatively large dose required for effective therapy, demanding larger quantities for the treatment of a given disease. This, coupled with the broadening repertoire of protein drugs, has rapidly expanded the quantity needed for clinical applications. The increasing demand for protein therapeutics has not been met exclusively by construction of new manufacturing plants and increasing total volume capacity. More - portantly the productivity of cell culture processes has been driven upward by an order of magnitude in the past decade.
  cell and gene therapy manufacturing process: Oversight and Review of Clinical Gene Transfer Protocols Institute of Medicine, Board on Health Sciences Policy, Committee on the Independent Review and Assessment of the Activities of the NIH Recombinant DNA Advisory Committee, 2014-03-27 Gene transfer research is a rapidly advancing field that involves the introduction of a genetic sequence into a human subject for research or diagnostic purposes. Clinical gene transfer trials are subject to regulation by the U.S. Food and Drug Administration (FDA) at the federal level and to oversight by institutional review boards (IRBs) and institutional biosafety committees (IBCs) at the local level before human subjects can be enrolled. In addition, at present all researchers and institutions funded by the National Institutes of Health (NIH) are required by NIH guidelines to submit human gene transfer protocols for advisory review by the NIH Recombinant DNA Advisory Committee (RAC). Some protocols are then selected for individual review and public discussion. Oversight and Review of Clinical Gene Transfer Protocols provides an assessment of the state of existing gene transfer science and the current regulatory and policy context under which research is investigated. This report assesses whether the current oversight of individual gene transfer protocols by the RAC continues to be necessary and offers recommendations concerning the criteria the NIH should employ to determine whether individual protocols should receive public review. The focus of this report is on the standards the RAC and NIH should use in exercising its oversight function. Oversight and Review of Clinical Gene Transfer Protocols will assist not only the RAC, but also research institutions and the general public with respect to utilizing and improving existing oversight processes.
  cell and gene therapy manufacturing process: Translational Regenerative Medicine Anthony Atala, Julie Allickson, 2014-12-01 Translational Regenerative Medicine is a reference book that outlines the life cycle for effective implementation of discoveries in the dynamic field of regenerative medicine. By addressing science, technology, development, regulatory, manufacturing, intellectual property, investment, financial, and clinical aspects of the field, this work takes a holistic look at the translation of science and disseminates knowledge for practical use of regenerative medicine tools, therapeutics, and diagnostics. Incorporating contributions from leaders in the fields of translational science across academia, industry, and government, this book establishes a more fluid transition for rapid translation of research to enhance human health and well-being. - Provides formulaic coverage of the landscape, process development, manufacturing, challenges, evaluation, and regulatory aspects of the most promising regenerative medicine clinical applications - Covers clinical aspects of regenerative medicine related to skin, cartilage, tendons, ligaments, joints, bone, fat, muscle, vascular system, hematopoietic /immune system, peripheral nerve, central nervous system, endocrine system, ophthalmic system, auditory system, oral system, respiratory system, cardiac system, renal system, hepatic system, gastrointestinal system, genitourinary system - Identifies effective, proven tools and metrics to identify and pursue clinical and commercial regenerative medicine
  cell and gene therapy manufacturing process: Advances In Pharmaceutical Cell Therapy: Principles Of Cell-based Biopharmaceuticals Christine Guenther, Andrea Josefine Hauser, Ralf Huss, 2015-09-23 This textbook is a comprehensive overview of the development of cell-based biopharmaceuticals. Beginning with the underlying biology of stem cell and cell-based products, it traces the long and complex journey from preclinical concept to initiation of a pivotal clinical trial and the potential business model behind it.The book also takes into consideration the different regulatory landscapes and their continuous evolution in Europe, North America and other parts of the world. The authors describe a path to manufacture a clinical grade therapeutic that passes all necessary quality measures as a robust and marketable product including an outlook on next generation products and innovative strategies.This reference book is a must-have guide for any professional already active in biopharmaceuticals and anyone interested in getting involved in a scientific, medical or business capacity.
  cell and gene therapy manufacturing process: New Bioprocessing Strategies: Development and Manufacturing of Recombinant Antibodies and Proteins Bob Kiss, Uwe Gottschalk, Michael Pohlscheidt, 2018-12-06 This book review series presents current trends in modern biotechnology. The aim is to cover all aspects of this interdisciplinary technology where knowledge, methods and expertise are required from chemistry, biochemistry, microbiology, genetics, chemical engineering and computer science. Volumes are organized topically and provide a comprehensive discussion of developments in the respective field over the past 3-5 years. The series also discusses new discoveries and applications. Special volumes are dedicated to selected topics which focus on new biotechnological products and new processes for their synthesis and purification. In general, special volumes are edited by well-known guest editors. The series editor and publisher will however always be pleased to receive suggestions and supplementary information. Manuscripts are accepted in English.
  cell and gene therapy manufacturing process: The Business of Healthcare Innovation Lawton Robert Burns, 2005-08-25 The Business of Healthcare Innovation is the first wide-ranging analysis of business trends in the manufacturing segment of the health care industry. In this leading edge volume, Professor Burns focuses on the key role of the 'producers' as the main source of innovation in health systems. Written by professors of the Wharton School and industry executives, this book provides a detailed overview of the pharmaceutical, biotechnology, genomics/proteomics, medical device and information technology sectors. It analyses the market structures of these sectors as well as the business models and corporate strategies of firms operating within them. Most importantly, the book describes the growing convergence between these sectors and the need for executives in one sector to increasingly draw upon trends in the others. It will be essential reading for students and researchers in the field of health management, and of great interest to strategy scholars, industry practitioners and management consultants.
  cell and gene therapy manufacturing process: Oncoimmunology Laurence Zitvogel, Guido Kroemer, 2017-12-13 In this book, leading experts in cancer immunotherapy join forces to provide a comprehensive guide that sets out the main principles of oncoimmunology and examines the latest advances and their implications for clinical practice, focusing in particular on drugs with FDA/EMA approvals and breakthrough status. The aim is to deliver a landmark educational tool that will serve as the definitive reference for MD and PhD students while also meeting the needs of established researchers and healthcare professionals. Immunotherapy-based approaches are now inducing long-lasting clinical responses across multiple histological types of neoplasia, in previously difficult-to-treat metastatic cancers. The future challenges for oncologists are to understand and exploit the cellular and molecular components of complex immune networks, to optimize combinatorial regimens, to avoid immune-related side effects, and to plan immunomonitoring studies for biomarker discovery. The editors hope that this book will guide future and established health professionals toward the effective application of cancer immunology and immunotherapy and contribute significantly to further progress in the field.
  cell and gene therapy manufacturing process: Molecular and Cellular Therapeutics David Whitehouse, Ralph Rapley, 2012-02-17 Molecular and Cellular Therapeutics aims to bring together key developments in the areas of molecular diagnostics, therapeutics and drug discovery. The book covers topics including diagnostics, therapeutics, model systems, clinical trials and drug discovery. The developing approaches to molecular and cellular therapies, diagnostics and drug discovery are presented in the context of the pathologies they are devised to treat.
  cell and gene therapy manufacturing process: Viral Vectors for Gene Therapy Otto-Wilhelm Merten, Mohamed Al-Rubeai, 2011-05-19 The huge potential for gene therapy to cure a wide range of diseases has led to high expectations and a great increase in research efforts in this area, particularly in the study of delivery via viral vectors, widely considered to be more efficient than DNA transfection. In Viral Vectors for Gene Therapy: Methods and Protocols, experts in the field present a collection of their knowledge and experience featuring methodologies that involve virus production, transferring protocols, and evaluating the efficacy of gene products. While thoroughly covering the most popular viral vector systems of adenovirus, retrovirus, and adeno-associated virus, this detailed volume also explores less common viral vector systems such as baculovirus, herpes virus, and measles virus, the growing interest in which is creating a considerable demand for large scale manufacturing and purification procedures. Written in the highly successful Methods in Molecular BiologyTM series format, many chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and vital tips on troubleshooting and avoiding known pitfalls. Comprehensive and practical, Viral Vectors for Gene Therapy: Methods and Protocols provides basic principles accessible to scientists from a wide variety of backgrounds for the development of gene therapy viral products that are safe and effective.
  cell and gene therapy manufacturing process: Stem Cell Bioengineering Biju Parekkadan, Martin L. Yarmush, 2009 In stem cell research there are several key methods that, once mastered, can be extremely powerful. These methods enable you to rigorously test hypotheses, compare results to gold standards, and may even spur improvements to existing protocols. This book describes numerous methods to derive, manipulate, target, and prepare stem cells for clinical use. The methods described here help you derive and test human embryonic stem cells, analyze bone marrow stem cell function in vitro and in vivo, image a stem cell transplant, cryopreserve stem cells and differentiate stem cells using microscale tec.
  cell and gene therapy manufacturing process: Stem Cells in Clinical Practice and Tissue Engineering Rakesh Sharma, 2018-05-02 Stem Cells in Clinical Practice and Tissue Engineering is a concise book on applied methods of stem cell differentiation and optimization using tissue engineering methods. These methods offer immediate use in clinical regenerative medicine. The present volume will serve the purpose of applied stem cell differentiation optimization methods in clinical research projects, as well as be useful to relatively experienced stem cell scientists and clinicians who might wish to develop their stem cell clinical centers or research labs further. Chapters are arranged in the order of basic concepts of stem cell differentiation, clinical applications of pluripotent stem cells in skin, cardiac, bone, dental, obesity centers, followed by tissue engineering, new materials used, and overall evaluation with their permitted legal status.
  cell and gene therapy manufacturing process: From Research to Reality The Expert Panel on the Approval and Use of Somatic Gene Therapies in Canada, 2020-11-05 From Research to Reality describes the stages involved in the approval and use of gene therapies in Canada, and examines challenges associated with regulatory oversight, manufacturing, access, and affordability, and identifies promising approaches to address them.
  cell and gene therapy manufacturing process: Phase Appropriate GMP for Biological Processes Trevor Deeks, 2018-04
  cell and gene therapy manufacturing process: Handbook of Cell and Gene Therapy Hazel Aranha, Humberto Vega-Mercado, 2023-03-17 This handbook provides an in-depth review of information across the developmental spectrum of gene and cell therapy products. From introductory information to state-of-the-art technologies and concepts, the book provides insights into upstream processes such as vector design and construction, purification, formulation and fill/finish, as well as delivery options. Planning steps for compliance with current good manufacturing practice (cGMP) to readiness for chemistry, manufacturing and controls (CMC) are also discussed. This book wraps up with examples of successes and pitfalls addressed by experts who have navigated the multiple challenges that are part of any innovative endeavor. Features Provides the most up-to-date information on the development of gene therapy, from the technology involved to gene correction and genome editing Discusses siRNA, mRNA, and plasmid manufacturing Describes the importance of supplier-sponsor synergies on the path to commercialization Written for a diverse audience with a large number of individuals in the core technologies and supportive practices It is intended as a one-stop resource for the availability of state-of-the-art information related to cell and gene therapy products for researchers, scientists, management and other academic and research institutions.
  cell and gene therapy manufacturing process: Perinatal Stem Cells Anthony Atala, Kyle J. Cetrulo, Rouzbeh R. Taghizadeh, Curtis L Cetrulo, Sean Murphy, 2018-06-14 Perinatal Stem Cells provides researchers and clinicians with a comprehensive description of the current clinical and pre-clinical applications of stem cells derived from perinatal sources, such as amniotic fluid, placenta and placental membranes, the umbilical cord and Wharton's jelly. It's compiled by leading experts in the field, offering readers detailed insights into sources of perinatal stem cells and their potential for disease treatment. Therapeutic applications of perinatal stem cells include the treatment of in utero and pregnancy related diseases, cardiac disease, liver disease, pulmonary disease, inflammatory diseases, for hematopoietic regeneration, and for neural protection after stroke or traumatic brain injury. In addition, the rapid advance in clinical translation and commercialization of perinatal stem cell therapies is highlighted in a section on Clinical and Industry Perspective which provides insight into the new opportunities and challenges involved in this novel and exciting industry. - Explores current clinical and pre-clinical application of stem cells derived from perinatal sources - Offers detailed insight into sources of perinatal stem cells and their potential for disease treatment - Discusses progress in the manufacturing, banking and clinical translation of perinatal stem cells - Edited by a world-renowned team to present a complete story of the development and promise of perinatal stem cells
  cell and gene therapy manufacturing process: Sustainable Design and Manufacturing 2016 Rossi Setchi, Robert J. Howlett, Ying Liu, Peter Theobald, 2016-04-02 This volumes consists of 59 peer-reviewed papers, presented at the International Conference on Sustainable Design and Manufacturing (SDM-16) held in Chania, Crete Greece in April 2016. Leading-edge research into sustainable design and manufacturing aims to enable the manufacturing industry to grow by adopting more advanced technologies, and at the same time improve its sustainability by reducing its environmental impact. SDM-16 covers a wide range of topics from sustainable product design and service innovation, sustainable process and technology for the manufacturing of sustainable products, sustainable manufacturing systems and enterprises, decision support for sustainability, and the study of societal impact of sustainability including research for circular economy. Application areas are wide and varied. The book will provide an excellent overview of the latest research and development in the area of Sustainable Design and Manufacturing.
  cell and gene therapy manufacturing process: Preclinical Safety Evaluation of Biopharmaceuticals Joy A. Cavagnaro, 2013-03-07 The goal is to provide a comprehensive reference book for the preclinicaldiscovery and development scientist whose responsibilities span target identification, lead candidate selection, pharmacokinetics, pharmacology, and toxicology, and for regulatory scientists whose responsibilities include the evaluation of novel therapies. —From the Afterword by Anthony D. Dayan Proper preclinical safety evaluation can improve the predictive value, lessen the time and cost of launching new biopharmaceuticals, and speed potentially lifesaving drugs to market. This guide covers topics ranging from lead candidate selection to establishing proof of concept and toxicity testing to the selection of the first human doses. With chapters contributed by experts in their specific areas, Preclinical Safety Evaluation of Biopharmaceuticals: A Science-Based Approach to Facilitating Clinical Trials: Includes an overview of biopharmaceuticals with information on regulation and methods of production Discusses the principles of ICH S6 and their implementation in the U.S., Europe, and Japan Covers current practices in preclinical development and includes a comparison of safety assessments for small molecules with those for biopharmaceuticals Addresses all aspects of the preclinical evaluation process, including: the selection of relevant species; safety/toxicity endpoints; specific considerations based upon class; and practical considerations in the design, implementation, and analysis of biopharmaceuticals Covers transitioning from preclinical development to clinical trials This is a hands-on, straightforward reference for professionals involved in preclinical drug development, including scientists, toxicologists, project managers, consultants, and regulatory personnel.
  cell and gene therapy manufacturing process: Regulatory Toxicology Franz-Xaver Reichl, Michael Schwenk, 2014-03-27 This book will be written by experts for professionals, scientists and all those involved in toxicological data generation and decision-making. It is the updated and expanded version of a monograph published in German in 2004. Chemical safety is regulated on various levels including production, storage, transport, handling, disposal or labelling. This book deals comprehensively with the safety-ensuring methods and concepts employed by regulatory agencies, industry and academics. Toxicologists use experimental and scientific approaches for data collection, e.g. about chemical hazards, physicochemical features or toxicokinetics. The respective experimental methods are described in the book. Toxicologists also deal with much insecurity in the exposure and effect scenarios during risk assessment. To overcome these, they have different extrapolation methods and estimation procedures at their disposal. The book describes these methods in an accessible manner. Differing concepts from one regulation area to another are also covered. Reasons and consequences become evident when reading the book. Altogether, the book Regulatory Toxicology will serve as an excellent reference.
  cell and gene therapy manufacturing process: Current Strategies in Cancer Gene Therapy Wolfgang Walther, 2017-01-17 This book describes important developments and emerging trends in experimental and clinical cancer gene therapy. It reflects the tremendous advances made over recent years with respect to immunogenes, suicide genes and gene correction therapies, as well as in gene suppression and miRNA therapies. Many of the described strategies focus on the generation of more efficient and specific means of attack at known and novel cellular targets associated with tumor development and progression. The book also details parallel improvements in vector design, vector delivery, and therapeutic efficacy. It offers readers a stimulating, broad overview of advances in the field, linking experimental strategies to their clinical applications.
  cell and gene therapy manufacturing process: Routledge International Handbook of Rural Studies Mark Shucksmith, David L. Brown, 2016-05-20 Rural societies around the world are changing in fundamental ways, both at their own initiative and in response to external forces. The Routledge International Handbook of Rural Studies examines the organisation and transformation of rural society in more developed regions of the world, taking an interdisciplinary and problem-focused approach. Written by leading social scientists from many countries, it addresses emerging issues and challenges in innovative and provocative ways to inform future policy. This volume is organised around eight emerging social, economic and environmental challenges: Demographic change. Economic transformations. Food systems and land. Environment and resources. Changing configurations of gender and rural society. Social and economic equality. Social dynamics and institutional capacity. Power and governance. Cross-cutting these challenges are the growing interdependence of rural and urban; the rise in inequality within and between places; the impact of fiscal crisis on rural societies; neoliberalism, power and agency; and rural areas as potential sites of resistance. The Routledge International Handbook of Rural Studies is required reading for anyone concerned with the future of rural areas.
  cell and gene therapy manufacturing process: Gene Therapy Methods M. Ian Phillips, 2002-02-22 This volume in the prestigious Methods in Enzymology series discusses methods currently used in preclinical and clinical gene therapy. Subjects covered in this book, such as the use of adeno-associated virus delivery for treatment of Parkinson's disease, are topical and are presented in the methods-oriented style popularized by this series. Discusses methods currently used in preclinical and clinical gene therapy Covers the use of adeno-associated virus delivery for treatment of Parkinson's disease
  cell and gene therapy manufacturing process: Animal Cell Technology Manuel J.T. Carrondo, Bryan Griffiths, José L.P. Moreira, 2012-12-06 Animal cell technology has undergone a rapid transformation over the last decade from a research tool and highly specialised technology to a central resource for innovation in pharmaceutical research and development. These proceedings of the 14th Meeting of the European Society for Animal Cell Technology (Vilamoura, Portugal, May 1996) bring up to date the historical perspective of animal cell technology for the benefit of society, `From Vaccines to Genetic Medicine', and will charter this vital technology for the years to come. Strong contributions are grouped in the traditional ESACT areas of 'Cell and Physiology Engineering' dealing with cell state, including genetics, and its environment, and 'Animal Cell Process Engineering' covering integration of bioreaction with bioseparation coupled with on-line monitoring to improve protein production and consistency. Extensive coverage of metabolic engineering on synthesis, folding, assembly, transiting and secretion is dealt with in the session on 'Recombinant Proteins: Biosynthesis and Bioprocessing'. Two traditional but expanding areas of animal cell technology relevance are highlighted in the broad sessions of 'Animal Cells as Tools for Discovery and Testing' and 'Animal Cell Vaccines: Present and Future'. Two sessions finally cover the more recent domains of animal cell technology work - 'Tissue Engineering and Biomedical Devices' and 'Cells and Vectors for Genetic Medicine' - where one can foresee a very bright future.
Cell: Cell - Cell Press
Cell publishes findings of unusual significance in any area of experimental biology, including but not limited to cell biology, molecular biology, …

Cell (biology) - Wikipedia
The cell is the basic structural and functional unit of all forms of life. Every cell consists of cytoplasm enclosed within a membrane; many cells …

Cell | Definition, Types, Functions, Diagram, Division, …
Apr 25, 2025 · cell, in biology, the basic membrane-bound unit that contains the fundamental molecules of life and of which all living things are …

The cell: Types, functions, and organelles - Medical News To…
Dec 19, 2023 · A cell is the smallest living organism and the basic unit of life on earth. Together, trillions of cells make up the human body. Cells have …

Cell – Definition, Structure, Types, Functions, Examples
Apr 7, 2024 · A cell is the basic structural and functional unit of all living organisms, responsible for various life processes and …

Cell: Cell - Cell Press
Cell publishes findings of unusual significance in any area of experimental biology, including but not limited to cell biology, molecular biology, neuroscience, immunology, virology and …

Cell (biology) - Wikipedia
The cell is the basic structural and functional unit of all forms of life. Every cell consists of cytoplasm enclosed within a membrane; many cells contain organelles, each with a specific …

Cell | Definition, Types, Functions, Diagram, Division, Theory,
Apr 25, 2025 · cell, in biology, the basic membrane-bound unit that contains the fundamental molecules of life and of which all living things are composed. A single cell is often a complete …

The cell: Types, functions, and organelles - Medical News Today
Dec 19, 2023 · A cell is the smallest living organism and the basic unit of life on earth. Together, trillions of cells make up the human body. Cells have three parts: the membrane, the nucleus, …

Cell – Definition, Structure, Types, Functions, Examples
Apr 7, 2024 · A cell is the basic structural and functional unit of all living organisms, responsible for various life processes and containing essential biological

What Is a Cell? | Learn Science at Scitable - Nature
All cells evolved from a common ancestor and use the same kinds of carbon-based molecules. Learn how cell function depends on a diverse group of nucleic acids, proteins, lipids, and sugars.

What is a cell? - MedlinePlus
Feb 22, 2021 · Cells are the basic building blocks of all living things. The human body is composed of trillions of cells. They provide structure for the body, take in nutrients from food, …

Cell Definition - BYJU'S
Jan 14, 2018 · Cells are the structural, functional, and biological units of all living beings. A cell can replicate itself independently. Hence, they are known as the building blocks of life. Each …

Introduction to cells - Basic Biology
Aug 30, 2020 · A cell is the simplest unit of life and they are responsible for keeping an organism alive and functioning. This introduction to cells is the starting point for the area of biology that …

Overview of Cells - Visible Body
What are cells and what do they do? The nucleus of a eukaryotic cell contains its DNA. Cells are the microscopic units that make up humans and every other living organism. Some organisms …