Biochemists and biochemical engineers present interdisciplinary modeling strategies and theoretical tools that are used to understand the diverse phenomena associated with transport within biological media. The topics include modeling momentum and mass transport in cellular biological media from the molecular to the tissue scale, the transport of water and solute across endothelial barriers and tumor cell adhesion in microcirculation, blood flow through capillary networks, models of cerebrovascular perfusion, shear stress variation and plasma viscosity effect in microcirculation, mass transfer phenomena in electroportation, and modeling intracellular transport in neurons. Academic Press is an imprint of Elsevier. Annotation ©2013 Book News, Inc., Portland, OR (booknews.com)
Transport in Biological Media is a solid resource of mathematical models for researchers across a broad range of scientific and engineering problems such as the effects of drug delivery, chemotherapy, or insulin intake to interpret transport experiments in areas of cutting edge biological research. A wide range of emerging theoretical and experimental mathematical methodologies are offered by biological topic to appeal to individual researchers to assist them in solving problems in their specific area of research. Researchers in biology, biophysics, biomathematics, chemistry, engineers and clinical fields specific to transport modeling will find this resource indispensible.
- Provides detailed mathematical model development to interpret experiments and provides current modeling practices
- Provides a wide range of biological and clinical applications
- Includes physiological descriptions of models
Arvustused
"Transport in Biological Media. Edited by Sid M. Becker and Andrey V. Kuznetsov. Academic Press. Amsterdam (The Netherlands) and Boston (Massachusetts): Elsevier. $149.95. xiii 559 p.; ill.; index. ISBN: 978-0-12-415824-5. 2013." --The Quarterly Review of Biology,September 2014
"Biochemists and biochemical engineers present interdisciplinary modeling strategies and theoretical tools that are used to understand the diverse phenomena associated with transport within biological media." --Reference and Research Book News, August 2013
Muu info
Mathematical modeling at multiple scales for understanding and solving research problems in the transport of biological media
Chapter 1: Modeling momentum and mass transport in cellular biological
media: from the molecular to the tissue scale
Chapter 2:Thermal pain in tooth: heat transfer, thermomechanics, and ion
transport
Chapter 3: Drug Release in Biological Tissues
Chapter 4: Transport of Water and Solutes across Endothelial Barriers and
Tumor Cell Adhesion in the Microcirculation
Chapter 5: Carrier Mediated Transport through Biomembranes
Chapter 6: Blood flow through capillary networks
Chapter 7: Models of Cerebrovascular Perfusion
Chapter 8: Mechanobiology of the Arterial Wall
Chapter 9: Shear Stress Variation and Plasma Viscosity Effect in
Microcirculation
Chapter 10: Targeted Drug Delivery: Multifunctional Nanoparticles and Direct
Micro-drug Delivery to Tumors
Chapter 11: Electrotransport across Membranes in Biological Media:
Electrokinetic Theories and Applications in Drug Delivery
Chapter 12: Mass transfer phenomena in electroporation
Chapter 13: Modeling of cell electroporation and its measurable effects in
tissue
Chapter 14: Modeling Intracellular Transport in Neurons
Sid Becker is an Associate Professor in the Department of Mechanical Engineering at the University of Canterbury. He is an Alexander von Humboldt Fellow and is a recipient of the Royal Society of New Zealand Marsden Grant. He has held academic positions in Germany, the United States, and New Zealand. His research is primarily in computational and analytical modelling of heat and mass transfer processes in biological media. Dr. Becker is also the editor of the book Modeling of Microscale Transport in Biological Processes (2017) and co-editor of the books Heat Transfer and Fluid Flow in Biological Processes (2015), and Transport in Biological Media (2013). Dr. Kuznetsov is Professor at the Department of Mechanical & Aerospace Engineering at North Carolina State University. He holds a joint professorial position at the University of North Carolinas Biomedical Engineering Department. He is a Fellow of American Society of Mechanical Engineering, an Editorial Board Member of the Proceeding of the Royal Society A, and an Associate Editor of the Journal of Porous Media. He is a recipient of the prestigious Humboldt Research Award. In 2014, Dr. Kuznetsov was elected as a Member of the Scientific Council of the International Center of Heat and Mass Transfer. He has published more than 400 journal papers, 17 book chapters, 3 books, and 100 conference papers. His works have been cited over 12,000 times: he has an h-index of 51 and an i-10 index of over 220. While his most notable early contributions are in the development of the field of porous media, Prof. Kuznetsovs research interests in the general area of numerical modeling are extensive, including transport in living tissues, sub-cellular transport, mass transport in neurons and axons, bioheat transport, bioconvective sedimentation, fluid mechanics, flows in microgravity, and turbulence.
