Academic Press Microfluidics in Cell Biology Part C: Microfluidics for Cellular and Subcellular Analysis (Volume 148) (Methods in Cell Biology, Volume 148)

Product Description Microfluidics in Cell Biology Part C, Volume 148, a new release in the Methods in Cell Biology series, continues the legacy of this premier serial with quality chapters authored by leaders in the field. Unique to this updated volume are three sections on microfluidics in various multi-cellular models, including microfluidics in cell monolayers/spheroids, microfluidics in organ on chips, and microfluidics in model organisms. Specific chapters discuss collective migration in microtubes, leukocyte adhesion dynamics on endothelial monolayers under flow, constrained spheroid for perfusion culture, cells in droplet arrays, heart on chips, kidney on chips, liver on chips, and more. Contains contributions from experts in the field from across the world Covers a wide array of topics on both mitosis and meiosis Includes relevant, analysis based topics Review Continues the legacy of this premier serial authored by leaders in the field, with this volume focusing on microfluidics in multi-cellular models About the Author Matthieu Piel and his team develop microfabricated and microfluidic tools to quantitatively control the physical parameters of the cell’s environment and study how cells grow, divide and migrate. The team focused on how physical confinement, geometry and forces affect cell division and cell migration. The general aim of these studies is to draw a line between the physics of the active matter cells are made of and the behavior of cells in the complex environment of tissues, in the context of the immune response and tumor development. Dr. Fletcher and his team develops diagnostic technologies and studies mechanical regulation of membrane and cytoskeleton organization in the context of cell motility, signaling, and host-pathogen interactions. His lab specialize in development of optical microscopy, force microscopy, and microfluidic technologies to understand fundamental organizational principles through both in vitro reconstitution and live cell experiments. Recent work includes investigating the mechano-biochemistry of branched actin network assembly with force microscopy, studying membrane deformation by protein crowding and oligomerization with model membranes, and reconstituting spindle scaling in encapsulated cytoplasmic extracts. The long-term goal of his work is to understand and harness spatial organization for therapeutic applications in cancer and infectious diseases. Junsang Doh is an associate professor of Mechanical Engineering/Interdisciplinary Bioscience and Bioengineering (I-Bio) in POSTECH, South Korea. Prof. Doh’s group develops and utilizes engineering tools such as microfabrication/imaging/mechanics to study fundamental aspects of immune cell behaviors, including synapse-based cell-cell interactions and motility under complex microenvironments, in the context of cancer immunotherapy.