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[259]-273) and index. 327 $aIntroduction -- Formation -- Magnitude -- Organization -- Technology and interdependence -- Trust, conflict, and performance -- Conclusion. 330 $aHow technology and bureaucracy shape collaborative scientific research projects: an empirical study of multiorganizational collaboration in the physical sciences. Collaboration among organizations is rapidly becoming common in scientific research as globalization and new communication technologies make it possible for researchers from different locations and institutions to work together on common projects. These scientific and technological collaborations are part of a general trend toward more fluid, flexible, and temporary organizational arrangements, but they have received very limited scholarly attention. Structures of Scientific Collaboration is the first study to examine multi-organizational collaboration systematically, drawing on a database of 53 collaborations documented for the Center for History of Physics of the American Institute of Physics. By integrating quantitative sociological analyses with detailed case histories, Shrum, Genuth, and Chompalov pioneer a new and truly interdisciplinary method for the study of science and technology. Scientists undertake multi-organizational collaborations because individual institutions often lack sufficient resources--including the latest technology--to achieve a given research objective. The authors find that collaborative research depends on both technology and bureaucracy; scientists claim to abhor bureaucracy, but most collaborations use it constructively to achieve their goals. The book analyzes the structural elements of collaboration (among them formation, size and duration, organization, technological practices, and participant experiences) and the relationships among them. The authors find that trust, though viewed as positive, is not necessarily associated with successful projects; indeed, the formal structures of bureaucracy reduce the need for high levels of trust--and make possible the independence so valued by participating scientists. 410 0$aInside technology. 606 $aResearch$xInternational cooperation 606 $aPhysics$xResearch$xInternational cooperation 606 $aIntellectual cooperation 606 $aAcademic-industrial collaboration 610 $aSCIENCE, TECHNOLOGY & SOCIETY/General 610 $aPHYSICAL SCIENCES/General 615 0$aResearch$xInternational cooperation. 615 0$aPhysics$xResearch$xInternational cooperation. 615 0$aIntellectual cooperation. 615 0$aAcademic-industrial collaboration. 676 $a530.072/4 700 $aShrum$b Wesley$f1953-$01566330 701 $aGenuth$b Joel$01566331 701 $aChompalov$b Ivan$01566332 801 0$bOCoLC-P 801 1$bOCoLC-P 906 $aBOOK 912 $a9910778151303321 996 $aStructures of scientific collaboration$93836762 997 $aUNINA LEADER 04037nam 22006735 450 001 9910409699603321 005 20251113174634.0 010 $a3-030-36588-3 024 7 $a10.1007/978-3-030-36588-2 035 $a(CKB)4100000011034439 035 $a(DE-He213)978-3-030-36588-2 035 $a(MiAaPQ)EBC6175319 035 $a(PPN)243764111 035 $a(MiAaPQ)EBC6175384 035 $a(EXLCZ)994100000011034439 100 $a20200413d2020 u| 0 101 0 $aeng 135 $aurnn#008mamaa 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aBiomaterials- and Microfluidics-Based Tissue Engineered 3D Models /$fedited by J. Miguel Oliveira, Rui L. Reis 205 $a1st ed. 2020. 210 1$aCham :$cSpringer International Publishing :$cImprint: Springer,$d2020. 215 $a1 online resource (VII, 175 p. 42 illus., 40 illus. in color.) 225 1 $aAdvances in Experimental Medicine and Biology,$x2214-8019 ;$v1230 300 $aIncludes index. 311 08$a3-030-36587-5 327 $aMicrofluidic devices and three dimensional-printing strategies for in vitro models of bone -- Microfluidics for Processing of biomaterials -- Organ-on-a-chip -- Body-on-a-chip: Current challenges -- Biomaterials and microfluidics for liver models -- Microfluidics for CNS research -- Biomaterials and microfluidics for angiogenesis research -- Biomaterials and microfluidics for drug discovery and development -- Microfluidics for diagnostics -- Nanoparticles and Microfluidic devices in cancer research. 330 $aThis contributed volume reviews the latest advances on relevant 3D tissue engineered in vitro models of disease making use of biomaterials and microfluidics. The main focus of this book is on advanced biomaterials and microfluidics technologies that have been used in in vitro mimetic 3D models of human diseases and show great promise in revolutionizing personalized medicine. Readers will discover important topics involving biomaterials and microfluidics design, advanced processing techniques, and development and validation of organ- and body-on-a-chip models for bone, liver, and cancer research. An in depth discussion of microfabrication methods for microfluidics development is also provided. This work is edited by two truly multidisciplinary scientists and includes important contributions from well-known experts in their fields. The work is written for both early stage and experienced researchers, and well-established scientists enrolled in the fields of biomaterials, microfluidics, and tissue engineering, and is especially suited to those who wish to become acquainted with the principles and latest developments of in vitro models of diseases, such as professionals working in pharma, medicine, and engineering. 410 0$aAdvances in Experimental Medicine and Biology,$x2214-8019 ;$v1230 606 $aMedicine$xResearch 606 $aBiology$xResearch 606 $aRegenerative medicine 606 $aBiomedical engineering 606 $aBiomaterials 606 $aBiomedical Research 606 $aRegenerative Medicine and Tissue Engineering 606 $aBiomedical Engineering and Bioengineering 606 $aBiomaterials 615 0$aMedicine$xResearch. 615 0$aBiology$xResearch. 615 0$aRegenerative medicine. 615 0$aBiomedical engineering. 615 0$aBiomaterials. 615 14$aBiomedical Research. 615 24$aRegenerative Medicine and Tissue Engineering. 615 24$aBiomedical Engineering and Bioengineering. 615 24$aBiomaterials. 676 $a610.28 702 $aOliveira$b J. 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