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| cell 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 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 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 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 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 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 therapy manufacturing process: Bioprocessing for Cell-Based Therapies Che J. Connon, 2017-02-06 With contributions from leading, international academics and industrial practitioners, Bioprocessing for Cell-Based Therapies explores the very latest techniques and guidelines in bioprocess production to meet safety, regulatory and ethical requirements, for the production of therapeutic cells, including stem cells. An authoritative, cutting-edge handbook on bioprocessing for the production of therapeutic cells with extensive illustrations in full colour throughout An authoritative, cutting-edge handbook on bioprocessing for the production of therapeutic cells with extensive illustrations in full colour throughout In depth discussion of the application of cell therapy including methods used in the delivery of cells to the patient Includes contributions from experts in both academia and industry, combining a practical approach with cutting edge research The only handbook currently available to provide a state of the art guide to Bioprocessing covering the complete range of cell-based therapies, from experts in academia and industry |
| cell therapy manufacturing process: Biopharmaceutical Processing Gunter Jagschies, Eva Lindskog, Karol Lacki, Parrish M. Galliher, 2018-01-18 Biopharmaceutical Processing: Development, Design, and Implementation of Manufacturing Processes covers bioprocessing from cell line development to bulk drug substances. The methods and strategies described are essential learning for every scientist, engineer or manager in the biopharmaceutical and vaccines industry. The integrity of the bioprocess ultimately determines the quality of the product in the biotherapeutics arena, and this book covers every stage including all technologies related to downstream purification and upstream processing fields. Economic considerations are included throughout, with recommendations for lowering costs and improving efficiencies. Designed for quick reference and easy accessibility of facts, calculations and guidelines, this book is an essential tool for industrial scientists and managers in the biopharmaceutical industry. - Offers a comprehensive, go-to reference for daily work decisions - Covers both upstream and downstream processes - Includes case studies that emphasize financial outcomes - Presents summaries, decision grids, graphs and overviews for quick reference |
| cell 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 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 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 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 therapy manufacturing process: Cellular Therapy Ellen M. Areman, Kathy Loper, 2009 |
| cell therapy manufacturing process: The European Blood and Marrow Transplantation Textbook for Nurses Michelle Kenyon, Aleksandra Babic, 2018-03-14 This book is open access under a CC BY 4.0 license. This textbook, endorsed by the European Society for Blood and Marrow Transplantation (EBMT), provides adult and paediatric nurses with a full and informative guide covering all aspects of transplant nursing, from basic principles to advanced concepts. It takes the reader on a journey through the history of transplant nursing, including essential and progressive elements to help nurses improve their knowledge and benefit the patient experience, as well as a comprehensive introduction to research and auditing methods. This new volume specifically intended for nurses, complements the ESH-EBMT reference title, a popular educational resource originally developed in 2003 for physicians to accompany an annual training course also serving as an educational tool in its own right. This title is designed to develop the knowledge of nurses in transplantation. It is the first book of its kind specifically targeted at nurses in this specialist field and acknowledges the valuable contribution that nursing makes in this area. This volume presents information that is essential for the education of nurses new to transplantation, while also offering a valuable resource for more experienced nurses who wish to update their knowledge. |
| cell 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 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 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 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 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 therapy manufacturing process: Quality Management and Accreditation in Hematopoietic Stem Cell Transplantation and Cellular Therapy Mahmoud Aljurf, John A. Snowden, Patrick Hayden, Kim H. Orchard, Eoin McGrath, 2021-02-19 This open access book provides a concise yet comprehensive overview on how to build a quality management program for hematopoietic stem cell transplantation (HSCT) and cellular therapy. The text reviews all the essential steps and elements necessary for establishing a quality management program and achieving accreditation in HSCT and cellular therapy. Specific areas of focus include document development and implementation, audits and validation, performance measurement, writing a quality management plan, the accreditation process, data management, and maintaining a quality management program. Written by experts in the field, Quality Management and Accreditation in Hematopoietic Stem Cell Transplantation and Cellular Therapy: A Practical Guide is a valuable resource for physicians, healthcare professionals, and laboratory staff involved in the creation and maintenance of a state-of-the-art HSCT and cellular therapy program. |
| cell therapy manufacturing process: Stem Cells and the Future of Regenerative Medicine Institute of Medicine, Board on Neuroscience and Behavioral Health, National Research Council, Division on Earth and Life Studies, Board on Life Sciences, Committee on the Biological and Biomedical Applications of Stem Cell Research, 2002-01-25 Recent scientific breakthroughs, celebrity patient advocates, and conflicting religious beliefs have come together to bring the state of stem cell researchâ€specifically embryonic stem cell researchâ€into the political crosshairs. President Bush's watershed policy statement allows federal funding for embryonic stem cell research but only on a limited number of stem cell lines. Millions of Americans could be affected by the continuing political debate among policymakers and the public. Stem Cells and the Future of Regenerative Medicine provides a deeper exploration of the biological, ethical, and funding questions prompted by the therapeutic potential of undifferentiated human cells. In terms accessible to lay readers, the book summarizes what we know about adult and embryonic stem cells and discusses how to go about the transition from mouse studies to research that has therapeutic implications for people. Perhaps most important, Stem Cells and the Future of Regenerative Medicine also provides an overview of the moral and ethical problems that arise from the use of embryonic stem cells. This timely book compares the impact of public and private research funding and discusses approaches to appropriate research oversight. Based on the insights of leading scientists, ethicists, and other authorities, the book offers authoritative recommendations regarding the use of existing stem cell lines versus new lines in research, the important role of the federal government in this field of research, and other fundamental issues. |
| cell 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 therapy manufacturing process: Ask a Manager Alison Green, 2018-05-01 From the creator of the popular website Ask a Manager and New York’s work-advice columnist comes a witty, practical guide to 200 difficult professional conversations—featuring all-new advice! There’s a reason Alison Green has been called “the Dear Abby of the work world.” Ten years as a workplace-advice columnist have taught her that people avoid awkward conversations in the office because they simply don’t know what to say. Thankfully, Green does—and in this incredibly helpful book, she tackles the tough discussions you may need to have during your career. You’ll learn what to say when • coworkers push their work on you—then take credit for it • you accidentally trash-talk someone in an email then hit “reply all” • you’re being micromanaged—or not being managed at all • you catch a colleague in a lie • your boss seems unhappy with your work • your cubemate’s loud speakerphone is making you homicidal • you got drunk at the holiday party Praise for Ask a Manager “A must-read for anyone who works . . . [Alison Green’s] advice boils down to the idea that you should be professional (even when others are not) and that communicating in a straightforward manner with candor and kindness will get you far, no matter where you work.”—Booklist (starred review) “The author’s friendly, warm, no-nonsense writing is a pleasure to read, and her advice can be widely applied to relationships in all areas of readers’ lives. Ideal for anyone new to the job market or new to management, or anyone hoping to improve their work experience.”—Library Journal (starred review) “I am a huge fan of Alison Green’s Ask a Manager column. This book is even better. It teaches us how to deal with many of the most vexing big and little problems in our workplaces—and to do so with grace, confidence, and a sense of humor.”—Robert Sutton, Stanford professor and author of The No Asshole Rule and The Asshole Survival Guide “Ask a Manager is the ultimate playbook for navigating the traditional workforce in a diplomatic but firm way.”—Erin Lowry, author of Broke Millennial: Stop Scraping By and Get Your Financial Life Together |
| cell therapy manufacturing process: Monoclonal Antibody Production National Research Council, Institute for Laboratory Animal Research, Committee on Methods of Producing Monoclonal Antibodies, 1999-05-06 The American Anti-Vivisection Society (AAVS) petitioned the National Institutes of Health (NIH) on April 23, 1997, to prohibit the use of animals in the production of mAb. On September 18, 1997, NIH declined to prohibit the use of mice in mAb production, stating that the ascites method of mAb production is scientifically appropriate for some research projects and cannot be replaced. On March 26, 1998, AAVS submitted a second petition, stating that NIH failed to provide valid scientific reasons for not supporting a proposed ban. The office of the NIH director asked the National Research Council to conduct a study of methods of producing mAb. In response to that request, the Research Council appointed the Committee on Methods of Producing Monoclonal Antibodies, to act on behalf of the Institute for Laboratory Animal Research of the Commission on Life Sciences, to conduct the study. The 11 expert members of the committee had extensive experience in biomedical research, laboratory animal medicine, animal welfare, pain research, and patient advocacy (Appendix B). The committee was asked to determine whether there was a scientific necessity for the mouse ascites method; if so, whether the method caused pain or distress; and, if so, what could be done to minimize the pain or distress. The committee was also asked to comment on available in vitro methods; to suggest what acceptable scientific rationale, if any, there was for using the mouse ascites method; and to identify regulatory requirements for the continued use of the mouse ascites method. The committee held an open data-gathering meeting during which its members summarized data bearing on those questions. A 1-day workshop (Appendix A) was attended by 34 participants, 14 of whom made formal presentations. A second meeting was held to finalize the report. The present report was written on the basis of information in the literature and information presented at the meeting and the workshop. |
| cell therapy manufacturing process: Safety, Efficacy and Mechanisms of Action of Mesenchymal Stem Cell Therapies Guido Moll, Martin Johannes Hoogduijn, James A. Ankrum, 2020-07-24 |
| cell therapy manufacturing process: Stem Cell Therapies Adam C. Berger, Sarah H. Beachy, Board on Health Sciences Policy, Steve Olson, Board on Life Sciences, Division on Earth and Life Sciences, Institute of Medicine, National Academy of Sciences, 2014-06-18 Stem cells offer tremendous promise for advancing health and medicine. Whether being used to replace damaged cells and organs or else by supporting the body's intrinsic repair mechanisms, stem cells hold the potential to treat such debilitating conditions as Parkinson's disease, diabetes, and spinal cord injury. Clinical trials of stem cell treatments are under way in countries around the world, but the evidence base to support the medical use of stem cells remains limited. Despite this paucity of clinical evidence, consumer demand for treatments using stem cells has risen, driven in part by a lack of available treatment options for debilitating diseases as well as direct-to-consumer advertising and public portrayals of stem cell-based treatments. Clinics that offer stem cell therapies for a wide range of diseases and conditions have been established throughout the world, both in newly industrialized countries such as China, India, and Mexico and in developed countries such as the United States and various European nations. Though these therapies are often promoted as being established and effective, they generally have not received stringent regulatory oversight and have not been tested with rigorous trials designed to determine their safety and likely benefits. In the absence of substantiated claims, the potential for harm to patients - as well as to the field of stem cell research in general - may outweigh the potential benefits. To explore these issues, the Institute of Medicine, the National Academy of Sciences, and the International Society for Stem Cell Research held a workshop in November 2013. Stem Cell Therapies summarizes the workshop. Researchers, clinicians, patients, policy makers, and others from North America, Europe, and Asia met to examine the global pattern of treatments and products being offered, the range of patient experiences, and options to maximize the well-being of patients, either by protecting them from treatments that are dangerous or ineffective or by steering them toward treatments that are effective. This report discusses the current environment in which patients are receiving unregulated stem cell offerings, focusing on the treatments being offered and their risks and benefits. The report considers the evidence base for clinical application of stem cell technologies and ways to assure the quality of stem cell offerings. |
| cell therapy manufacturing process: Chimeric Antigen Receptor T Cells Kamilla Swiech, Kelen Cristina Ribeiro Malmegrim, Virgínia Picanço-Castro, 2020-11-24 This volume provides comprehensive methods from expert scientists working in the Chimeric Antigen Receptor T Cell (CAR-T Cell) field. Chapters guide readers through the state-of-art of CAR-T cell technology, CAR design and vector production, CAR-T cell generation and manufacturing, CAR-T cell characterization, and quality control. Written in the highly successful Methods in Molecular Biology series format, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Authoritative and cutting-edge, Chimeric Antigen Receptor T Cells: Development and Production aims to be useful in the production of CAR-T cells, especially for therapeutic purposes. |
| cell therapy manufacturing process: Stem Cells – From Hype to Real Hope Khawaja Husnain Haider, Salim Aziz, MD, 2018-12-17 This book is a compilation of the bench experience of leading experts from various research labs involved in the cutting edge area of research. The authors describe the use of stem cells both as part of the combinatorial therapeutic intervention approach and as tools (disease model) during drug development, highlighting the shift from a conventional symptomatic treatment strategy to addressing the root cause of the disease process. The book is a continuum of the previously published book entitled Stem Cells: from Drug to Drug Discovery which was published in 2017. |
| cell therapy manufacturing process: Haploidentical Transplantation Stefan O. Ciurea, Rupert Handgretinger, 2018-05-03 In this book, world-renowned experts in the field express well-reasoned opinions on a range of issues and controversies relating to haploidentical transplantation with the aim of providing practicing hematologists with clinically relevant and readily applicable information. Among the areas covered are graft manipulation and methods to control T-cell alloreactivity, the nature of the ideal graft and donor, haploidentical transplantation in pediatric and adult patients with malignant and nonmalignant diseases, immunologic reconstitution following transplantation, complications, and the prevention and treatment of relapse post transplantation. Attention is drawn to the implications of high-impact clinical trials whenever such trials are available. The readily intelligible text is complemented by numerous helpful tables, algorithms, and figures. The book will provide practical support for hematologists and transplant physicians as they attempt to provide optimal care in this exciting but increasingly complex medical specialty. |
| cell therapy manufacturing process: Chimeric Antigen Receptor T-Cell Therapies for Cancer E-Book Daniel W. Lee, Nirali N. Shah, 2019-11-30 From patient referral to post-therapy management, Chimeric Antigen Receptor (CAR) T-Cell Therapies for Cancer: A Practical Guide presents a comprehensive view of CAR modified T-cells in a concise and practical format. Providing authoritative guidance on the implementation and management of CAR T-cell therapy from Drs. Daniel W. Lee and Nirali N. Shah, this clinical resource keeps you up to date on the latest developments in this rapidly evolving area. - Covers all clinical aspects, including patient referral, toxicities management, comorbidities, bridging therapy, post-CAR monitoring, and multidisciplinary approaches to supportive care. - Includes key topics on associated toxicities such as predictive biomarkers, infections, and multidisciplinary approaches to supportive care. - Presents current knowledge on FDA approved CAR T-cell products as well as developments on the horizon. - Editors and authors represent leading investigators in academia and worldwide pioneers of CAR therapy. |
| cell therapy manufacturing process: Encyclopedia of Biomedical Gerontology , 2019-11-20 Encyclopedia of Biomedical Gerontology, Three Volume Set presents a wide range of topics, ranging from what happens in the body during aging, the reasons and mechanisms relating to those age-related changes, and their clinical, psychological and social modulators and determinants. The book covers the biological and medical aspects of gerontology within the general framework of the biological basis of assessing age, biological mechanisms of aging, age-related changes in biological systems, human age-related diseases, the biomedical practicality and impracticality of interventions, and finally, the ethics of intervention. Provides a ‘one-stop’ resource to information written by world-leading scholars in the field of biomedical gerontology Fills a critical gap of information in a field that has seen significant progress in the last 10 years |
| cell therapy manufacturing process: Advances in Precision Medicine Oncology Hilal Arnouk, Bassam Abdul Rasool Hassan, 2021 Recent advances in precision medicine and immuno-oncology have led to highly specific and efficacious cancer therapies such as monoclonal antibodies and immune checkpoint inhibitors (ICIs). This book provides an up-to-date overview of advances in the field of immuno-oncology. Chapters cover such topics as ICIs and how they mount a robust immune response against cancer cells as well as the response of ICIs to treatment predictive biomarkers and their potential immune-related adverse events (irAEs). Additionally, the book includes a comprehensive review of the powerful FDA-approved therapeutic agent doxorubicin, highlighting the molecular mechanisms behind doxorubicin's drug resistance and critical side effects. |
| cell 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 therapy manufacturing process: Phase Appropriate GMP for Biological Processes Trevor Deeks, 2018-04 |
| cell therapy manufacturing process: Navigating the Manufacturing Process and Ensuring the Quality of Regenerative Medicine Therapies National Academies of Sciences, Engineering, and Medicine, Health and Medicine Division, Board on Health Sciences Policy, Forum on Regenerative Medicine, 2018-01-29 On June 26, 2017, the Forum on Regenerative Medicine hosted a public workshop in Washington, DC, titled Navigating the Manufacturing Process and Ensuring the Quality of Regenerative Medicine Therapies in order to examine and discuss the challenges, opportunities, and best practices associated with defining and measuring the quality of cell and tissue products and raw materials in the research and manufacturing of regenerative medicine therapies. The goal of the workshop was to learn from existing examples of the manufacturing of early-generation regenerative medicine products and to address how progress could be made in identifying and measuring critical quality attributes. The workshop also addressed the challenges of designing and adhering to standards as a way of helping those who are working to scale up processes and techniques from a research laboratory to the manufacturing environment. This publication summarizes the presentations and discussions from the workshop. |
| cell therapy manufacturing process: Stem Cell Therapy: A Rising Tide: How Stem Cells Are Disrupting Medicine and Transforming Lives Neil H. Riordan, 2017-06-20 Stem cells are the repair cells of your body. When there aren't enough of them, or they aren't working properly, chronic diseases can manifest and persist. From industry leaders, sport stars, and Hollywood icons to thousands of everyday, ordinary people, stem cell therapy has helped when standard medicine failed. Many of them had lost hope. These are their stories. Neil H Riordan, author of MSC: Clinical Evidence Leading Medicine's Next Frontier, the definitive textbook on clinical stem cell therapy, brings you an easy-to-read book about how and why stem cells work, and why they're the wave of the future. |
| cell therapy manufacturing process: Bioreactor Systems for Tissue Engineering Cornelia Kasper, Martijn van Griensven, Ralf Pörtner, 2009-02-03 The editors of this special volume would first like to thank all authors for their excellent contributions. We would also like to thank Prof. Dr. Thomas Scheper, Dr. Marion Hertel and Ulrike Kreusel for providing the opportunity to compose this volume and Springer for organizational and technical support. Tissue engineering represents one of the major emerging fields in modern b- technology; it combines different subjects ranging from biological and material sciences to engineering and clinical disciplines. The aim of tissue engineering is the development of therapeutic approaches to substitute diseased organs or tissues or improve their function. Therefore, three dimensional biocompatible materials are seeded with cells and cultivated in suitable systems to generate functional tissues. Many different aspects play a role in the formation of 3D tissue structures. In the first place the source of the used cells is of the utmost importance. To prevent tissue rejection or immune response, preferentially autologous cells are now used. In particular, stem cells from different sources are gaining exceptional importance as they can be differentiated into different tissues by using special media and supplements. In the field of biomaterials, numerous scaffold materials already exist but new composites are also being developed based on polymeric, natural or xenogenic sources. Moreover, a very important issue in tissue en- neering is the formation of tissues under well defined, controlled and reprod- ible conditions. Therefore, a substantial number of new bioreactors have been developed. |
| cell therapy manufacturing process: Stem Cells and Regenerative Medicine Walter C. Low, Catherine M. Verfaillie, 2008 The commercialization of biotechnology has resulted in an intensive search for new biological resources for the purposes of increasing food productivity, medicinal applications, energy production, and various other applications. Although biotechnology has produced many benefits for humanity, the exploitation of the planet's natural resources has also resulted in some undesirable consequences such as diminished species biodiversity, climate change, environmental contamination, and intellectual property right and patent concerns.This book discusses the role of biological, ecological, environmental, ethical, and economic issues in the interaction between biotechnology and biodiversity, using different contexts. No other book has discussed all of these issues in a comprehensive manner. Of special interest is their impact when biotechnology is shared between developed and developing countries, and the lack of recognition of the rights of indigenous populations and traditional farmers in developing countries by large multinational corporations. |
| cell therapy manufacturing process: Usp38-Nf33 United States Pharmacopeial Convention, 2014-11-01 |
| cell therapy manufacturing process: Bioprocess Monitoring and Control Bernd Hitzmann, 2020-09-10 Process monitoring and control are fundamental to all processes; this holds especially for bioprocesses, due to their complex nature. Usually, bioprocesses deal with living cells, which have their own regulatory systems. It helps to adjust the cell to its environmental condition. This must not be the optimal condition that the cell needs to produce whatever is desired. Therefore, a close monitoring of the cell and its environment is essential to provide optimal conditions for production. Without measurement, no information of the current process state is obtained. In this book, methods and techniques are provided for the monitoring and control of bioprocesses. From new developments for sensors, the application of spectroscopy and modelling approaches, the estimation and observer implementation for ethanol production and the development and scale-up of various bioprocesses and their closed loop control information are presented. The processes discussed here are very diverse. The major applications are cultivation processes, where microorganisms were grown, but also an incubation process of bird's eggs, as well as an indoor climate control for humans, will be discussed. Altogether, in 12 chapters, nine original research papers and three reviews are presented. |
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 …
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 …
