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Thoroughly revised to include the latest industry developments, the Second Edition presents a comprehensive overview of computer validation and verification principles and how to put them into practice. To provide the current best practice and guidance on identifying and implementing improvements for computer systems, the text extensively reviews regulations of pharmaceuticals, healthcare products, blood processing, medical devices, clinical systems, and biotechnology. Ensuring that organizations transition smoothly to the new system, this guide explains how to implement the new GMP paradigm while maintaining continuity with current practices. In addition, all 24 case studies from the previous edition have been revised to reflect the new system.
Pharmaceutical Computer Validation Introduction gives you a comprehensive introduction to computer systems validation as the computers come to life while the head of computer systems at a pharmaceutical company has to prepare for an FDA inspection. You will learn about regulations, the personnel responsible for computer validation, how to accomplish validation, examples of regulatory problems, and so on. It is also relevant for the medical device, food, and cosmetic industries. 86 pages in the guide include a handy printout of several relevant FDA documents. Those readers who wish to have an accompanying program with video and interactivity should also purchase the CD version.
Validation of computer systems is the process that assures the formal assessment and report of quality and performance measures for all the life-cycle stages of software and system development, its implementation, qualification and acceptance, operation, modification, requalification, maintenance and retirement (PICS CSV PI 011-3). It is a process that demonstrates the compliance of computer systems functional and non-functional requirements, data integrity, regulated company procedures and safety requirements, industry standards, and applicable regulatory authority’s requirements. Compliance is a state of being in adherence to application-related standards or conventions or regulations in laws and similar prescriptions. This book, which is relevant to the pharmaceutical and medical devices regulated operations, provides practical information to assist in the computer validation to production systems, while highlighting and efficiently integrating worldwide regulation into the subject. A practical approach is presented to increase efficiency and to ensure that the validation of computer systems is correctly achieved.
This handbook details methods for sustainable compliance with GxPs and 21 CFR Part 11 validation requirements regarding computerized systems in the pharmaceutical, biotechnology, and medical device industry. The handbook follows FDA guidelines and best industry practices in defining roles, responsib
Covering regulatory requirements stipulated by the FDA, this book delineates the organization, planning, verification, and documentation activities and procedural controls required for compliance with worldwide computer systems validation regulations. The author introduces supporting technologies such as encryption and digital signatures and places
All too often, the words "computer validation" strike terror into the hearts of those new to the process and may even cause those familiar with it to tremble. Validating Pharmaceutical Systems: Good Computer Practice in Life Science Manufacturing delineates GCP, GLP, and GMP regulatory requirements and provides guidance from seasoned practitioners on how to fulfill them. John Andrews and his team tackle the perceived complexities surrounding the validation of a wide variety of automated systems. Sprinkled with case studies and real-life examples, the book offers a step-by-step review of topics such as planning, design, auditing, risk management, and specification. The in-depth, by example coverage demystifies the challenges of manufacturing execution systems(MES), laboratory information management systems(LIMS), and network qualification. The first section examines the different levels of automated systems used throughout the drug development, manufacture, and delivery lifecycle, using the GAMP 4 lifecycle approach to their validation. The second section uncovers some real-life applications of GAMP 4 to different areas of the regulations such as GLP, GCP, GMP, and GDP. The book explores some of the latest thinking on computer validation and reflects changes that have occurred in the industry since the early days of validation. The contributors are a deliberate blend of those who have faced the problems of the 1990s and the Y2K controversies and those who have more recently arrived on the scene and made an impact on the perception of validation of automated systems across the field of GxP. They do more than show you how to do the right thing; they show you how to do the right thing in compliance with regulations.
Adopting a practical approach, the authors provide a detailed interpretation of the existing regulations (GMP, ICH), while also discussing the appropriate calculations, parameters and tests. The book thus allows readers to validate the analysis of pharmaceutical compounds while complying with both the regulations as well as the industry demands for robustness and cost effectiveness. Following an introduction to the basic parameters and tests in pharmaceutical validation, including specificity, linearity, range, precision, accuracy, detection and quantitation limits, the text focuses on a life-cycle approach to validation and the integration of validation into the whole analytical quality assurance system. The whole is rounded off with a look at future trends. With its first-hand knowledge of the industry as well as regulating bodies, this is an invaluable reference for analytical chemists, the pharmaceutical industry, pharmaceutists, QA officers, and public authorities.
GAMP 5 provides pragmatic and practical industry guidance to achieve compliant computerized systems fit for intended use in an efficient and effective manner. This technical document describes a flexible risk-based approach to compliant GxP regulated computerized systems, based on scalable specification and verification. It points to the future of computer systems compliance by centering on principles behind major industry developments such as PQLI; ICH Q8, Q9, Q10; and ASTM E2500. This revolutionary Guide addresses the entire lifecycle of an automated system and its applicability to a wide range of information systems, lab equipment, integrated manufacturing systems, and IT infrastructures. It contains new information on outsourcing, electronic batch recording, end user applications (such as spreadsheets and small database applications), and patch management.
Modern embedded systems require high performance, low cost and low power consumption. Such systems typically consist of a heterogeneous collection of processors, specialized memory subsystems, and partially programmable or fixed-function components. This heterogeneity, coupled with issues such as hardware/software partitioning, mapping, scheduling, etc., leads to a large number of design possibilities, making performance debugging and validation of such systems a difficult problem. Embedded systems are used to control safety critical applications such as flight control, automotive electronics and healthcare monitoring. Clearly, developing reliable software/systems for such applications is of utmost importance. This book describes a host of debugging and verification methods which can help to achieve this goal. - Covers the major abstraction levels of embedded systems design, starting from software analysis and micro-architectural modeling, to modeling of resource sharing and communication at the system level - Integrates formal techniques of validation for hardware/software with debugging and validation of embedded system design flows - Includes practical case studies to answer the questions: does a design meet its requirements, if not, then which parts of the system are responsible for the violation, and once they are identified, then how should the design be suitably modified?