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| clinical study startup process: The Prevention and Treatment of Missing Data in Clinical Trials National Research Council, Division of Behavioral and Social Sciences and Education, Committee on National Statistics, Panel on Handling Missing Data in Clinical Trials, 2010-12-21 Randomized clinical trials are the primary tool for evaluating new medical interventions. Randomization provides for a fair comparison between treatment and control groups, balancing out, on average, distributions of known and unknown factors among the participants. Unfortunately, these studies often lack a substantial percentage of data. This missing data reduces the benefit provided by the randomization and introduces potential biases in the comparison of the treatment groups. Missing data can arise for a variety of reasons, including the inability or unwillingness of participants to meet appointments for evaluation. And in some studies, some or all of data collection ceases when participants discontinue study treatment. Existing guidelines for the design and conduct of clinical trials, and the analysis of the resulting data, provide only limited advice on how to handle missing data. Thus, approaches to the analysis of data with an appreciable amount of missing values tend to be ad hoc and variable. The Prevention and Treatment of Missing Data in Clinical Trials concludes that a more principled approach to design and analysis in the presence of missing data is both needed and possible. Such an approach needs to focus on two critical elements: (1) careful design and conduct to limit the amount and impact of missing data and (2) analysis that makes full use of information on all randomized participants and is based on careful attention to the assumptions about the nature of the missing data underlying estimates of treatment effects. In addition to the highest priority recommendations, the book offers more detailed recommendations on the conduct of clinical trials and techniques for analysis of trial data. |
| clinical study startup process: Neuroscience Trials of the Future National Academies of Sciences, Engineering, and Medicine, Health and Medicine Division, Board on Health Sciences Policy, Forum on Neuroscience and Nervous System Disorders, 2016-11-07 On March 3-4, 2016, the National Academies of Sciences, Engineering, and Medicine's Forum on Neuroscience and Nervous System Disorders held a workshop in Washington, DC, bringing together key stakeholders to discuss opportunities for improving the integrity, efficiency, and validity of clinical trials for nervous system disorders. Participants in the workshop represented a range of diverse perspectives, including individuals not normally associated with traditional clinical trials. The purpose of this workshop was to generate discussion about not only what is feasible now, but what may be possible with the implementation of cutting-edge technologies in the future. |
| clinical study startup process: Practical Guide to Clinical Data Management Susanne Prokscha, 2011-10-26 The management of clinical data, from its collection during a trial to its extraction for analysis, has become a critical element in the steps to prepare a regulatory submission and to obtain approval to market a treatment. Groundbreaking on its initial publication nearly fourteen years ago, and evolving with the field in each iteration since then, |
| clinical study startup process: Transforming Clinical Research in the United States Institute of Medicine, Board on Health Sciences Policy, Forum on Drug Discovery, Development, and Translation, 2010-10-22 An ideal health care system relies on efficiently generating timely, accurate evidence to deliver on its promise of diminishing the divide between clinical practice and research. There are growing indications, however, that the current health care system and the clinical research that guides medical decisions in the United States falls far short of this vision. The process of generating medical evidence through clinical trials in the United States is expensive and lengthy, includes a number of regulatory hurdles, and is based on a limited infrastructure. The link between clinical research and medical progress is also frequently misunderstood or unsupported by both patients and providers. The focus of clinical research changes as diseases emerge and new treatments create cures for old conditions. As diseases evolve, the ultimate goal remains to speed new and improved medical treatments to patients throughout the world. To keep pace with rapidly changing health care demands, clinical research resources need to be organized and on hand to address the numerous health care questions that continually emerge. Improving the overall capacity of the clinical research enterprise will depend on ensuring that there is an adequate infrastructure in place to support the investigators who conduct research, the patients with real diseases who volunteer to participate in experimental research, and the institutions that organize and carry out the trials. To address these issues and better understand the current state of clinical research in the United States, the Institute of Medicine's (IOM) Forum on Drug Discovery, Development, and Translation held a 2-day workshop entitled Transforming Clinical Research in the United States. The workshop, summarized in this volume, laid the foundation for a broader initiative of the Forum addressing different aspects of clinical research. Future Forum plans include further examining regulatory, administrative, and structural barriers to the effective conduct of clinical research; developing a vision for a stable, continuously funded clinical research infrastructure in the United States; and considering strategies and collaborative activities to facilitate more robust public engagement in the clinical research enterprise. |
| clinical study startup process: Virtual Clinical Trials National Academies of Sciences, Engineering, and Medicine, Health and Medicine Division, Board on Health Sciences Policy, Forum on Drug Discovery, Development, and Translation, 2019-11-16 Successful drug development relies on accurate and efficient clinical trials to deliver the best and most effective pharmaceuticals and clinical care to patients. However, the current model for clinical trials is outdated, inefficient and costly. Clinical trials are limited by small sample sizes that do not reflect variations among patients in the real world, financial burdens on participants, and slow processes, and these factors contribute to the disconnect between clinical research and clinical practice. On November 28-29, the National Academies of Sciences, Engineering, and Medicine convened a workshop to investigate the current clinical trials system and explore the potential benefits and challenges of implementing virtual clinical trials as an enhanced alternative for the future. This publication summarizes the presentations and discussions from the workshop. |
| clinical study startup process: Envisioning a Transformed Clinical Trials Enterprise in the United States Institute of Medicine, Board on Health Sciences Policy, Forum on Drug Discovery, Development, and Translation, 2012-09-13 There is growing recognition that the United States' clinical trials enterprise (CTE) faces great challenges. There is a gap between what is desired - where medical care is provided solely based on high quality evidence - and the reality - where there is limited capacity to generate timely and practical evidence for drug development and to support medical treatment decisions. With the need for transforming the CTE in the U.S. becoming more pressing, the IOM Forum on Drug Discovery, Development, and Translation held a two-day workshop in November 2011, bringing together leaders in research and health care. The workshop focused on how to transform the CTE and discussed a vision to make the enterprise more efficient, effective, and fully integrated into the health care system. Key issue areas addressed at the workshop included: the development of a robust clinical trials workforce, the alignment of cultural and financial incentives for clinical trials, and the creation of a sustainable infrastructure to support a transformed CTE. This document summarizes the workshop. |
| clinical study startup process: The Learning Healthcare System Institute of Medicine, Roundtable on Evidence-Based Medicine, 2007-06-01 As our nation enters a new era of medical science that offers the real prospect of personalized health care, we will be confronted by an increasingly complex array of health care options and decisions. The Learning Healthcare System considers how health care is structured to develop and to apply evidence-from health profession training and infrastructure development to advances in research methodology, patient engagement, payment schemes, and measurement-and highlights opportunities for the creation of a sustainable learning health care system that gets the right care to people when they need it and then captures the results for improvement. This book will be of primary interest to hospital and insurance industry administrators, health care providers, those who train and educate health workers, researchers, and policymakers. The Learning Healthcare System is the first in a series that will focus on issues important to improving the development and application of evidence in health care decision making. The Roundtable on Evidence-Based Medicine serves as a neutral venue for cooperative work among key stakeholders on several dimensions: to help transform the availability and use of the best evidence for the collaborative health care choices of each patient and provider; to drive the process of discovery as a natural outgrowth of patient care; and, ultimately, to ensure innovation, quality, safety, and value in health care. |
| clinical study startup process: Clinical Trials Handbook Shayne Cox Gad, 2009-06-17 Best practices for conducting effective and safe clinical trials Clinical trials are arguably the most important steps in proving drug effectiveness and safety for public use. They require intensive planning and organization and involve a wide range of disciplines: data management, biostatistics, pharmacology, toxicology, modeling and simulation, regulatory monitoring, ethics, and particular issues for given disease areas. Clinical Trials Handbook provides a comprehensive and thorough reference on the basics and practices of clinical trials. With contributions from a range of international authors, the book takes the reader through each trial phase, technique, and issue. Chapters cover every key aspect of preparing and conducting clinical trials, including: Interdisciplinary topics that have to be coordinated for a successful clinical trialData management (and adverse event reporting systems) Biostatistics, pharmacology, and toxicology Modeling and simulation Regulatory monitoring and ethics Particular issues for given disease areas-cardiology, oncology, cognitive, dementia, dermatology, neuroscience, and more With unique information on such current issues as adverse event reporting (AER) systems, adaptive trial designs, and crossover trial designs, Clinical Trials Handbook will be a ready reference for pharmaceutical scientists, statisticians, researchers, and the many other professionals involved in drug development. |
| clinical study startup process: Improving and Accelerating Therapeutic Development for Nervous System Disorders Institute of Medicine, Board on Health Sciences Policy, Forum on Neuroscience and Nervous System Disorders, 2014-02-06 Improving and Accelerating Therapeutic Development for Nervous System Disorders is the summary of a workshop convened by the IOM Forum on Neuroscience and Nervous System Disorders to examine opportunities to accelerate early phases of drug development for nervous system drug discovery. Workshop participants discussed challenges in neuroscience research for enabling faster entry of potential treatments into first-in-human trials, explored how new and emerging tools and technologies may improve the efficiency of research, and considered mechanisms to facilitate a more effective and efficient development pipeline. There are several challenges to the current drug development pipeline for nervous system disorders. The fundamental etiology and pathophysiology of many nervous system disorders are unknown and the brain is inaccessible to study, making it difficult to develop accurate models. Patient heterogeneity is high, disease pathology can occur years to decades before becoming clinically apparent, and diagnostic and treatment biomarkers are lacking. In addition, the lack of validated targets, limitations related to the predictive validity of animal models - the extent to which the model predicts clinical efficacy - and regulatory barriers can also impede translation and drug development for nervous system disorders. Improving and Accelerating Therapeutic Development for Nervous System Disorders identifies avenues for moving directly from cellular models to human trials, minimizing the need for animal models to test efficacy, and discusses the potential benefits and risks of such an approach. This report is a timely discussion of opportunities to improve early drug development with a focus toward preclinical trials. |
| clinical study startup process: Why Startups Fail Tom Eisenmann, 2021-03-30 If you want your startup to succeed, you need to understand why startups fail. “Whether you’re a first-time founder or looking to bring innovation into a corporate environment, Why Startups Fail is essential reading.”—Eric Ries, founder and CEO, LTSE, and New York Times bestselling author of The Lean Startup and The Startup Way Why do startups fail? That question caught Harvard Business School professor Tom Eisenmann by surprise when he realized he couldn’t answer it. So he launched a multiyear research project to find out. In Why Startups Fail, Eisenmann reveals his findings: six distinct patterns that account for the vast majority of startup failures. • Bad Bedfellows. Startup success is thought to rest largely on the founder’s talents and instincts. But the wrong team, investors, or partners can sink a venture just as quickly. • False Starts. In following the oft-cited advice to “fail fast” and to “launch before you’re ready,” founders risk wasting time and capital on the wrong solutions. • False Promises. Success with early adopters can be misleading and give founders unwarranted confidence to expand. • Speed Traps. Despite the pressure to “get big fast,” hypergrowth can spell disaster for even the most promising ventures. • Help Wanted. Rapidly scaling startups need lots of capital and talent, but they can make mistakes that leave them suddenly in short supply of both. • Cascading Miracles. Silicon Valley exhorts entrepreneurs to dream big. But the bigger the vision, the more things that can go wrong. Drawing on fascinating stories of ventures that failed to fulfill their early promise—from a home-furnishings retailer to a concierge dog-walking service, from a dating app to the inventor of a sophisticated social robot, from a fashion brand to a startup deploying a vast network of charging stations for electric vehicles—Eisenmann offers frameworks for detecting when a venture is vulnerable to these patterns, along with a wealth of strategies and tactics for avoiding them. A must-read for founders at any stage of their entrepreneurial journey, Why Startups Fail is not merely a guide to preventing failure but also a roadmap charting the path to startup success. |
| clinical study startup process: Registries for Evaluating Patient Outcomes Agency for Healthcare Research and Quality/AHRQ, 2014-04-01 This User’s Guide is intended to support the design, implementation, analysis, interpretation, and quality evaluation of registries created to increase understanding of patient outcomes. For the purposes of this guide, a patient registry is an organized system that uses observational study methods to collect uniform data (clinical and other) to evaluate specified outcomes for a population defined by a particular disease, condition, or exposure, and that serves one or more predetermined scientific, clinical, or policy purposes. A registry database is a file (or files) derived from the registry. Although registries can serve many purposes, this guide focuses on registries created for one or more of the following purposes: to describe the natural history of disease, to determine clinical effectiveness or cost-effectiveness of health care products and services, to measure or monitor safety and harm, and/or to measure quality of care. Registries are classified according to how their populations are defined. For example, product registries include patients who have been exposed to biopharmaceutical products or medical devices. Health services registries consist of patients who have had a common procedure, clinical encounter, or hospitalization. Disease or condition registries are defined by patients having the same diagnosis, such as cystic fibrosis or heart failure. The User’s Guide was created by researchers affiliated with AHRQ’s Effective Health Care Program, particularly those who participated in AHRQ’s DEcIDE (Developing Evidence to Inform Decisions About Effectiveness) program. Chapters were subject to multiple internal and external independent reviews. |
| clinical study startup process: Biodesign Stefanos Zenios, Josh Makower, Paul Yock, 2010 Recognize market opportunities, master the design process, and develop business acumen with this 'how-to' guide to medical technology innovation. Outlining a systematic, proven approach for innovation - identify, invent, implement - and integrating medical, engineering, and business challenges with real-world case studies, this book provides a practical guide for students and professionals. |
| clinical study startup process: Principles and Practice of Clinical Trials Steven Piantadosi, Curtis L. Meinert, 2022-07-19 This is a comprehensive major reference work for our SpringerReference program covering clinical trials. Although the core of the Work will focus on the design, analysis, and interpretation of scientific data from clinical trials, a broad spectrum of clinical trial application areas will be covered in detail. This is an important time to develop such a Work, as drug safety and efficacy emphasizes the Clinical Trials process. Because of an immense and growing international disease burden, pharmaceutical and biotechnology companies continue to develop new drugs. Clinical trials have also become extremely globalized in the past 15 years, with over 225,000 international trials ongoing at this point in time. Principles in Practice of Clinical Trials is truly an interdisciplinary that will be divided into the following areas: 1) Clinical Trials Basic Perspectives 2) Regulation and Oversight 3) Basic Trial Designs 4) Advanced Trial Designs 5) Analysis 6) Trial Publication 7) Topics Related Specific Populations and Legal Aspects of Clinical Trials The Work is designed to be comprised of 175 chapters and approximately 2500 pages. The Work will be oriented like many of our SpringerReference Handbooks, presenting detailed and comprehensive expository chapters on broad subjects. The Editors are major figures in the field of clinical trials, and both have written textbooks on the topic. There will also be a slate of 7-8 renowned associate editors that will edit individual sections of the Reference. |
| clinical study startup process: Evolution of Translational Omics Institute of Medicine, Board on Health Sciences Policy, Board on Health Care Services, Committee on the Review of Omics-Based Tests for Predicting Patient Outcomes in Clinical Trials, 2012-09-13 Technologies collectively called omics enable simultaneous measurement of an enormous number of biomolecules; for example, genomics investigates thousands of DNA sequences, and proteomics examines large numbers of proteins. Scientists are using these technologies to develop innovative tests to detect disease and to predict a patient's likelihood of responding to specific drugs. Following a recent case involving premature use of omics-based tests in cancer clinical trials at Duke University, the NCI requested that the IOM establish a committee to recommend ways to strengthen omics-based test development and evaluation. This report identifies best practices to enhance development, evaluation, and translation of omics-based tests while simultaneously reinforcing steps to ensure that these tests are appropriately assessed for scientific validity before they are used to guide patient treatment in clinical trials. |
| clinical study startup process: ECM Methods Tom Jenkins, Walter Köhler, John Shackleton, 2005 Beschrijving van de informatietechnologie waarmee alle digitale informatie binnen een onderneming effectief verwerkt wordt waardoor zo optimaal mogelijk van die informatie gebruik kan worden gemaakt. |
| clinical study startup process: Fundamentals of Clinical Trials Lawrence M. Friedman, Curt Furberg, David L. DeMets, 1998 This classic reference, now updated with the newest applications and results, addresses the fundamentals of such trials based on sound scientific methodology, statistical principles, and years of accumulated experience by the three authors. |
| clinical study startup process: Practical Guide to Clinical Data Management Susanne Prokscha, 2024-07-03 The management of clinical data, from its collection during a trial to its extraction for analysis, has become critical in preparing a regulatory submission and obtaining approval to market a treatment. Groundbreaking on its initial publication nearly 14 years ago, and evolving with the field in each iteration since then, this latest volume includes revisions to all chapters to reflect the recent updates to ICH E6, good clinical practices, electronic data capture, and interactive response technologies. Keeping the coverage practical, the author focuses on the most critical information that impacts clinical trial conduct, providing a full end-to-end overview for clinical data managers. Features: Provides an introduction and background information for the spectrum of clinical data management tasks. Outstanding text in the industry and has been used by the Society for Clinical Data Management in creating its certification exam. Explains the high-level flow of a clinical trial from creation of the protocol through study lock. Reflects electronic data capture and interactive response technologies. Discusses using the concept of three phases in the clinical data management of a study: study startup, study conduct, and study closeout, to write procedures and train staff. |
| clinical study startup process: Practical Guide to Clinical Data Management, Third Edition Susanne Prokscha, 2011-10-26 The management of clinical data, from its collection during a trial to its extraction for analysis, has become a critical element in the steps to prepare a regulatory submission and to obtain approval to market a treatment. Groundbreaking on its initial publication nearly fourteen years ago, and evolving with the field in each iteration since then, the third edition of Practical Guide to Clinical Data Management includes important updates to all chapters to reflect the current industry approach to using electronic data capture (EDC) for most studies. See what’s new in the Third Edition: A chapter on the clinical trial process that explains the high level flow of a clinical trial from creation of the protocol through the study lock and provides the context for the clinical data management activities that follow Reorganized content reflects an industry trend that divides training and standard operating procedures for clinical data management into the categories of study startup, study conduct, and study closeout Coverage of current industry and Food and Drug Administration (FDA) approaches and concerns The book provides a comprehensive overview of the tasks involved in clinical data management and the computer systems used to perform those tasks. It also details the context of regulations that guide how those systems are used and how those regulations are applied to their installation and maintenance. Keeping the coverage practical rather than academic, the author hones in on the most critical information that impacts clinical trial conduct, providing a full end-to-end overview or introduction for clinical data managers. |
| clinical study startup process: Implementing a National Cancer Clinical Trials System for the 21st Century Institute of Medicine, Board on Health Care Services, National Cancer Policy Forum, 2011-09-19 Clinical trials enable scientific discoveries to advance patient care, in addition to informing and guiding subsequent research. The National Cancer Institute's (NCI's) Clinical Trials Cooperative Group Program works to advance patient care and research. The Cooperative Group Program has been instrumental in establishing the standards for cancer patient care and clinical research methods. Despite broad participation in the program, financial strain and procedural burdens limit the ability of the Cooperative Group Program to undertake medical practice-changing clinical research. Thus, the Institute of Medicine's (IOM's) National Cancer Policy Forum and the American Society of Clinical Oncology held a workshop on March 21, 2011 to follow up on the 2010 IOM report, A National Clinical Trials System for the 21st Century: Reinvigorating the NCI Cooperative Group Program, which made recommendations to strengthen the NCI Cooperative Group Program. In keeping with the established commitment to excellence Implementing a National Cancer Clinical Trials System for the 21st Century outlines how to improve the current system by incorporating innovative science and trial design into cancer clinical trials. It also examines the impact of increasing quality in regards to speed, efficiency, design, launch, and conduct, as well as improving prioritization, and incentivized participation. |
| clinical study startup process: Embedded Case Study Methods Roland W. Scholz, Olaf Tietje, 2002 In an embedded case study, the starting and end point is the comprehension of the case as a whole in its real-world context. This book bridges the gap between quantitative and qualitative approaches to complex problems when using this methodology. |
| clinical study startup process: Cutaneous T-Cell Lymphoma Herschel S. Zackheim, 2004-10-28 Cutaneous T-cell lymphoma (CTCL) is a general term for many lymphomas of the skin including mycosis Fungoides and Sezary syndrome. This book presents the state of the art in CTCL epidemiology, clinical features, pathology, immunochemistry, diagnostic molecular techniques, staging and prognosis, and treatment. Edited by one of the leading experts in |
| clinical study startup process: Risk Management and Assessment Jorge Rocha, Sandra Oliveira, César Capinha, 2020-10-14 Risk analysis, risk evaluation and risk management are the three core areas in the process known as 'Risk Assessment'. Risk assessment corresponds to the joint effort of identifying and analysing potential future events, and evaluating the acceptability of risk based on the risk analysis, while considering influencing factors. In short, risk assessment analyses what can go wrong, how likely it is to happen and, if it happens, what are the potential consequences. Since risk is a multi-disciplinary domain, this book gathers contributions covering a wide spectrum of topics with regard to their theoretical background and field of application. The work is organized in the three core areas of risk assessment. |
| clinical study startup process: The CRC's Guide to Coordinating Clinical Research Karen E. Woodin, 2004 This guidebook is filled with valuable information on the role and responsibilities of a clinical research coordinator (CRC) and explains the research process from the site and CRC perspective. Topics covered include: identifying the regulations governing clinical research; describing the drug development process; discussing good clinical practices and how to apply them in clinical trials and organizing a clinical practice. |
| clinical study startup process: Qualitative Research from Start to Finish, First Edition Robert K. Yin, 2011-09-26 This lively, practical text presents a fresh and comprehensive approach to doing qualitative research. The book offers a unique balance of theory and clear-cut choices for customizing every phase of a qualitative study. A scholarly mix of classic and contemporary studies from multiple disciplines provides compelling, field-based examples of the full range of qualitative approaches. Readers learn about adaptive ways of designing studies, collecting data, analyzing data, and reporting findings. Key aspects of the researcher's craft are addressed, such as fieldwork options, the five phases of data analysis (with and without using computer-based software), and how to incorporate the researcher's “declarative” and “reflective” selves into a final report. Ideal for graduate-level courses, the text includes:* Discussions of ethnography, grounded theory, phenomenology, feminist research, and other approaches.* Instructions for creating a study bank to get a new study started.* End-of-chapter exercises and a semester-long, field-based project.* Quick study boxes, research vignettes, sample studies, and a glossary.* Previews for sections within chapters, and chapter recaps.* Discussion of the place of qualitative research among other social science methods, including mixed methods research. |
| clinical study startup process: Enabling America Institute of Medicine, Committee on Assessing Rehabilitation Science and Engineering, 1997-11-24 The most recent high-profile advocate for Americans with disabilities, actor Christopher Reeve, has highlighted for the public the economic and social costs of disability and the importance of rehabilitation. Enabling America is a major analysis of the field of rehabilitation science and engineering. The book explains how to achieve recognition for this evolving field of study, how to set priorities, and how to improve the organization and administration of the numerous federal research programs in this area. The committee introduces the enabling-disability process model, which enhances the concepts of disability and rehabilitation, and reviews what is known and what research priorities are emerging in the areas of: Pathology and impairment, including differences between children and adults. Functional limitationsâ€in a person's ability to eat or walk, for example. Disability as the interaction between a person's pathologies, impairments, and functional limitations and the surrounding physical and social environments. This landmark volume will be of special interest to anyone involved in rehabilitation science and engineering: federal policymakers, rehabilitation practitioners and administrators, researchers, and advocates for persons with disabilities. |
| clinical study startup process: Usability Evaluation In Industry Patrick W. Jordan, B. Thomas, Ian Lyall McClelland, Bernard Weerdmeester, 1996-06-11 This book provides a variety of answers in its description and discussion of new, sometimes radical approaches to `usability evaluation', now an increasingly common business tool. It contains new thinking of the subject of usability evaluation in industry. Contributions come from those involved in the practice of industry-based usability evaluation as well as those involved in related research activity. The chapters are derived from and developed from presentations and discussions at the invited international seminar `Usability Evaluation in Industry', and give a leading edge overview of current usability practice in industry - identifying those issues of concern and approaches to tackling these. Key Features: * Provides a comprehensive overview of current practice * International examples * Contains practical examples of ergonomics at work and gives clear ideas of what does and doesn't work under industrial constraints |
| clinical study startup process: Designing Clinical Research Stephen B. Hulley, Steven R. Cummings, Warren S. Browner, Deborah G. Grady, Thomas B. Newman, 2011-11-30 Designing Clinical Research sets the standard for providing a practical guide to planning, tabulating, formulating, and implementing clinical research, with an easy-to-read, uncomplicated presentation. This edition incorporates current research methodology—including molecular and genetic clinical research—and offers an updated syllabus for conducting a clinical research workshop. Emphasis is on common sense as the main ingredient of good science. The book explains how to choose well-focused research questions and details the steps through all the elements of study design, data collection, quality assurance, and basic grant-writing. All chapters have been thoroughly revised, updated, and made more user-friendly. |
| clinical study startup process: ClinicalTrials Curtis L. Meinert, 2012-03-27 The classic, definitive guide to the design, conduct, and analysis of randomized clinical trials. |
| clinical study startup process: The Sourcebook for Clinical Research Natasha Martien, Jeff Nelligan, 2018-08-01 A single trial is complex, with numerous regulations, administrative processes, medical procedures, deadlines and specific protocol instructions to follow. And yet, there has existed no single-volume, comprehensive clinical research reference manual for investigators, medical institutions, and national and international research personnel to keep on the shelf as a ready reference to navigate through trial complexities and ensure compliance with U.S. Federal Regulations and ICH GCP until The Sourcebook for Clinical Research. An actionable, step-by-step guide through beginning to advanced topics in clinical research with forms, templates and checklists to download from a companion website, so that study teams will be compliant and will find all the necessary tools within this book. Additionally, the authors developed Display Posters for Adverse Events Plus Reporting and Medicare Coverage Analysis that can be purchased separately here: https://www.elsevier.com/books-and-journals/book-companion/9780128162422/order-display-posters. Moreover, The Sourcebook for Clinical Research contains clear information and guidance on the newest changes in the industry to keep seasoned investigators and staff current and compliant, in addition to providing detailed information regarding the most complex topics. This book serves as a quick, actionable, off-the-shelf resource to keep by your side at the medical clinic. - Makes vital trial conduct information easy to understand and instructs on how to practically apply current Federal regulations and Good Clinical Practice (ICH GCP) - Offers extensive guidance that is crucial for guaranteeing compliance to clinical research regulations during each step of the clinical research process - Provides up-to-date and extensive coverage of beginning to advanced topics, and, step-by-step actions to take during exceptional circumstances, including compassionate use, emergency use, human subjects protections for vulnerable populations, and federal audits - Furnishes a detailed clinical research Glossary, and a comprehensive Appendix containing ready-to-use forms, templates, and checklists for clinical trial personnel to download and begin using immediately. - Written for the fast-paced clinic environment with action steps and forms in the book to respond to a research subject's needs urgently and compliantly |
| clinical study startup process: Intelligent Drug Development Michael Tansey, 2014 Clinical research is heavily regulated and involves coordination of numerous pharmaceutical-related disciplines. Each individual trial involves contractual, regulatory, and ethics approval at each site and in each country. Clinical trials have become so complex and government requirements so stringent that researchers often approach trials too cautiously, convinced that the process is bound to be insurmountably complicated and riddled with roadblocks. A step back is needed, an objective examination of the drug development process as a whole, and recommendations made for streamlining the process at all stages. With Intelligent Drug Development, Michael Tansey systematically addresses the key elements that affect the quality, timeliness, and cost-effectiveness of the drug-development process, and identifies steps that can be adjusted and made more efficient. Tansey uses his own experiences conducting clinical trials to create a guide that provides flexible, adaptable ways of implementing the necessary processes of development. Moreover, the processes described in the book are not dependent either on a particular company structure or on any specific technology; thus, Tansey's approach can be implemented at any company, regardless of size. The book includes specific examples that illustrate some of the ways in which the principles can be applied, as well as suggestions for providing a better context in which the changes can be implemented. The protocols for drug development and clinical research have grown increasingly complex in recent years, making Intelligent Drug Development a needed examination of the pharmaceutical process. |
| clinical study startup process: A National Cancer Clinical Trials System for the 21st Century Institute of Medicine, Board on Health Care Services, Committee on Cancer Clinical Trials and the NCI Cooperative Group Program, 2010-08-08 The National Cancer Institute's (NCI) Clinical Trials Cooperative Group Program has played a key role in developing new and improved cancer therapies. However, the program is falling short of its potential, and the IOM recommends changes that aim to transform the Cooperative Group Program into a dynamic system that efficiently responds to emerging scientific knowledge; involves broad cooperation of stakeholders; and leverages evolving technologies to provide high-quality, practice-changing research. |
| clinical study startup process: Writing and Managing SOPs for GCP Susanne Prokscha, 2015-07-29 This book discusses managing SOPs for GCP from conception to retirement. It recommends approaches that have a direct impact on improving SOP and regulatory compliance. Throughout the text, the book provides a user's point of view to keep topics focused on the practical aspects of SOPs and SOP management. |
| clinical study startup process: ECM Technology Tom Jenkins, Hartmut Schaper, 2005 « Enterprise Content Management (ECM) describes a critical new segment in Information Technology. ECM is about the management of words-words that make up more than 90 percent of information in organizations today. Businesses are turning to ECM as the next major software productivity tool to effectively manage the explosion of digital content. This book discusses unlocking digital content. It focuses on the quality controls and productivity enhancements realized when secure Internet technology is used to deploy an ECM solution. The book considers current and future trends in ECM including corporate governance and regulatory compliance. A must-read for executives interested in managing content to achieve compliance, improve productivity, and foster innovation and future growth. »-- |
| clinical study startup process: ECM Solutions Bill Forquer, Peter Jelinski, Tom Jenkins, 2005 |
| clinical study startup process: Digital Startups in Transition Economies Agnieszka Skala, 2018-11-11 This book responds to the growing demand for a scientific approach to the concept of startups, which are a manifestation of the digital revolution and an innovation-driven economy. With a focus on digital enterprises, the author presents empirical research carried out over 4 years in collaboration with the Startup Poland Foundation, and provides a developed universal definition of a startup. This book highlights the necessity of a clear definition, in order for startups to be treated as a permanent economic phenomenon, rather than a temporary whim. Addressing the crucial need for an effective startup management methodology and more education on this form of entrepreneurship, Digital Startups in Transition Economies offers guidance for those researching entrepreneurship and innovation, as well as entrepreneurs, public institutions, startup accelerators and technology transfer centres. |
| clinical study startup process: Clinical Research Law and Compliance Handbook John E. Steiner, 2006 Law/Ethics |
| clinical study startup process: Digital Infrastructure for the Learning Health System Institute of Medicine, Roundtable on Value and Science-Driven Health Care, 2011-10-21 Like many other industries, health care is increasingly turning to digital information and the use of electronic resources. The Institute of Medicine's Roundtable on Value & Science-Driven Health Care hosted three workshops to explore current efforts and opportunities to accelerate progress in improving health and health care with information technology systems. |
| clinical study startup process: Innovation in Clinical Trial Methodologies Peter Schueler, 2020-11-20 Innovation in Clinical Trial Methodologies: Lessons Learned during the Corona Pandemic presents a selection of updated chapters from Re-Engineering Clinical Trials that feature innovative options and methods in clinical trials. The Coronavirus pandemic is an accelerator for digitalization in many industries, including clinical trials. This book considers best practices, alternative study concepts requiring fewer patients, studies with less patient interaction, the design of virtualized protocols, and moving from data to decisions. This book will be helpful to pharmacologists, physicians and clinical researchers involved in the process of clinical development and clinical trial design. Considers multiple digital and virtual strategies Explores best practices, including the use of reduced patient involvement Brings together expert, trusted information to increase the efficiency and effectiveness of clinical trials |
| clinical study startup process: New Approaches to Drug Development Pierre Jollès, 1989 |
| clinical study startup process: Social Science Research Anol Bhattacherjee, 2012-04-01 This book is designed to introduce doctoral and graduate students to the process of conducting scientific research in the social sciences, business, education, public health, and related disciplines. It is a one-stop, comprehensive, and compact source for foundational concepts in behavioral research, and can serve as a stand-alone text or as a supplement to research readings in any doctoral seminar or research methods class. This book is currently used as a research text at universities on six continents and will shortly be available in nine different languages. |
ClinicalTrials.gov
Study record managers: refer to the Data Element Definitions if submitting registration or results information.
CLINICAL Definition & Meaning - Merriam-Webster
The meaning of CLINICAL is of, relating to, or conducted in or as if in a clinic. How to use clinical in a sentence.
CLINICAL | English meaning - Cambridge Dictionary
CLINICAL definition: 1. used to refer to medical work or teaching that relates to the examination and treatment of ill…. Learn more.
CLINICAL definition and meaning | Collins English Dictionary
Clinical means involving or relating to the direct medical treatment or testing of patients.
Clinical Definition & Meaning | Britannica Dictionary
CLINICAL meaning: 1 : relating to or based on work done with real patients of or relating to the medical treatment that is given to patients in hospitals, clinics, etc.; 2 : requiring treatment as a …
CLINICAL | meaning - Cambridge Learner's Dictionary
CLINICAL definition: 1. relating to medical treatment and tests: 2. only considering facts and not influenced by…. Learn more.
Clinical - definition of clinical by The Free Dictionary
1. pertaining to a clinic. 2. concerned with or based on actual observation and treatment of disease in patients rather than experimentation or theory. 3. dispassionately analytic; …
Clinical - Definition, Meaning & Synonyms | Vocabulary.com
Something that's clinical is based on or connected to the study of patients. Clinical medications have actually been used by real people, not just studied theoretically.
Clinical Definition & Meaning - YourDictionary
Clinical definition: Of, relating to, or connected with a clinic.
Equity Medical | Clinical Research In New York And Kentucky
We pioneer dermatological advancements, collaborating on innovative treatments through research and clinical trials in urban New York City and rural Southern Kentucky.
ClinicalTrials.gov
Study record managers: refer to the Data Element Definitions if submitting registration or results information.
CLINICAL Definition & Meaning - Merriam-Webster
The meaning of CLINICAL is of, relating to, or conducted in or as if in a clinic. How to use clinical in a sentence.
CLINICAL | English meaning - Cambridge Dictionary
CLINICAL definition: 1. used to refer to medical work or teaching that relates to the examination and treatment of ill…. Learn more.
CLINICAL definition and meaning | Collins English Dictionary
Clinical means involving or relating to the direct medical treatment or testing of patients.
Clinical Definition & Meaning | Britannica Dictionary
CLINICAL meaning: 1 : relating to or based on work done with real patients of or relating to the medical treatment that is given to patients in hospitals, clinics, etc.; 2 : requiring treatment as a …
CLINICAL | meaning - Cambridge Learner's Dictionary
CLINICAL definition: 1. relating to medical treatment and tests: 2. only considering facts and not influenced by…. Learn more.
Clinical - definition of clinical by The Free Dictionary
1. pertaining to a clinic. 2. concerned with or based on actual observation and treatment of disease in patients rather than experimentation or theory. 3. dispassionately analytic; …
Clinical - Definition, Meaning & Synonyms | Vocabulary.com
Something that's clinical is based on or connected to the study of patients. Clinical medications have actually been used by real people, not just studied theoretically.
Clinical Definition & Meaning - YourDictionary
Clinical definition: Of, relating to, or connected with a clinic.
Equity Medical | Clinical Research In New York And Kentucky
We pioneer dermatological advancements, collaborating on innovative treatments through research and clinical trials in urban New York City and rural Southern Kentucky.
