Health research and health care practice are radically transforming as governments invest more in large scale, national and international health projects with increasing levels of interdisciplinarity as populations age and as nations grow wealthier. This volume examines the structures and dynamics of scientific collaboration in health research and health care. Bringing together detailed research from the US, Canada, Europe and Japan, Collaboration Across Health Research and Medical Care sheds light on the features, environments and relationships that characterise collaboration in health care and research, exploring changing patterns of collaboration and examining the causes and consequences of team work in the health domain. With attention to the increasingly porous boundaries between health care and research, the book not only investigates research settings, but also considers the manner in which knowledge produced in laboratories and clinics is translated into day-to-day medical and care practice and health initiatives. It offers a rich examination of the political, technical and organisational facets of collaboration and the implications of changes in collaboration for every day treatment and practice, Collaboration Across Health Research and Medical Care will be of interest to scholars of sociology and science and technology studies, as well as those working in the field of health policy and research.
In recent years there has been a clear rise in scientific collaboration, as well as in studies on the subject. While most scholars examine disciplines traditionally known to be collaborative, such as physics and space research, this book focuses on biology. It investigates the growing collaboration in the life sciences, or the emergence of what is called 'big biology'. While the Human Genome Project is often presented as the first large-scale research project in biology, cooperation in the life sciences has a longer history. A comparison between centralised 'big physics' and 'big biology' reveals how the latter has a networked structure, which evolved in interaction with the integration of information and communication technologies. By concentrating on the construction of these networks, three contemporary large-scale research collaborations are analysed: the Census of Marine Life that aims to make an inventory of life in the oceans, the Silicon Cell initiative that wants to design a replica of a cell in a computer, and the VIRGO consortium, which investigates host-virus interaction to develop a new therapy against influenza. This book demonstrates how the process of making science bigger, or the 'supersizing of science', transforms the ways in which science is organised while it also changes the work of scientists involved. As such, this has both scholarly and professional implications for the next generation of scientists.
In recent years there has been a clear rise in scientific collaboration, as well as in studies on the subject. While most scholars examine disciplines traditionally known to be collaborative, such as physics and space research, this book focuses on biology. It investigates the growing collaboration in the life sciences, or the emergence of what is called 'big biology'. While the Human Genome Project is often presented as the first large-scale research project in biology, cooperation in the life sciences has a longer history. A comparison between centralised 'big physics' and 'big biology' reveals how the latter has a networked structure, which evolved in interaction with the integration of information and communication technologies. By concentrating on the construction of these networks, three contemporary large-scale research collaborations are analysed: the Census of Marine Life that aims to make an inventory of life in the oceans, the Silicon Cell initiative that wants to design a replica of a cell in a computer, and the VIRGO consortium, which investigates host-virus interaction to develop a new therapy against influenza. This book demonstrates how the process of making science bigger, or the 'supersizing of science', transforms the ways in which science is organised while it also changes the work of scientists involved. As such, this has both scholarly and professional implications for the next generation of scientists.
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