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200 00$aPorous media $eapplications in biological systems and biotechnology /$feditor, Kambiz Vafai
210  1$aBoca Raton :$cTaylor & Francis,$d2011.
215   $a1 online resource (602 p.)
300   $aA CRC title.
311   $a1-322-61365-6 
311   $a1-4200-6541-6 
320   $aIncludes bibliographical references.
327   $aFront cover; Contents; Preface; Editor; Contributors; Chapter 1: A General Set of Bioheat Transfer EquationsBased on the Volume Averaging Theory; Chapter 2: Mathematical Models of Mass Transferin Tissue for Molecular Medicine with Reversible Electroporation; Chapter 3: Hydrodynamics in Porous Media with Applications to Tissue Engineering; Chapter 4: Biomedical Implications of the Porosity of Microbial Biofilms; Chapter 5: Influence of Biofilms on Porous Media Hydrodynamics; Chapter 6: Using Porous Media Theory to Determinethe Coil Volume Needed to Arrest Flow in Brain Aneurysms
327   $aChapter 7: Lagrangian Particle Methods for Biological SystemsChapter 8: Passive Mass Transport Processes in CellularMembranes and their Biophysical Implications; Chapter 9: Skin Electroporation: Modeling Perspectives; Chapter 10: Application of Porous Media Theories in Marine Biological Modeling; Chapter 11: The Transport of Insulin-Like Growth Factor through Cartilage; Chapter 12: Biotechnological and BiomedicalApplications of Magnetically Stabilized and Fluidized Beds; Chapter 13: In Situ Characterizations of Porous Mediafor Applications in Biofuel Cells: Issues and Challenges
327   $aChapter 14: Spatial Pattern Formation of MotileMicroorganisms: From GravitacticBioconvection to Protozoan Culture DynamicsBack cover
330   $aPresenting state-of-the-art research advancements, Porous Media: Applications in Biological Systems and Biotechnology explores innovative approaches to effectively apply existing porous media technologies to biomedical applications. In each peer-reviewed chapter, world-class scientists and engineers collaborate to address significant problems and discuss exciting research in biological systems.The book begins with discussions on bioheat transfer equations for blood flows and surrounding biological tissue, the concept of electroporation, hydrodynamic modeling o
606   $aBiomedical materials
606   $aBiotechnology$xMaterials
606   $aPorous materials$xFluid dynamics
606   $aPorous materials$xThermal properties
606   $aTissue engineering
606   $aBiofilms
608   $aElectronic books.
615  0$aBiomedical materials.
615  0$aBiotechnology$xMaterials.
615  0$aPorous materials$xFluid dynamics.
615  0$aPorous materials$xThermal properties.
615  0$aTissue engineering.
615  0$aBiofilms.
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200 10$aExperimental investigation of the dynamics of water rejection from a matrix type of hydrogen-oxygen fuel cell /$fby Paul R. Prokopius and Robert W. Easter
210  1$aWashington, D.C. :$cNational Aeronautics and Space Administration,$dDecember 1968.
215   $a1 online resource (ii, 21 pages) $cillustrations
225 1 $aNASA/TN ;$vD-4956
300   $a"December 1968."
320   $aIncludes bibliographical references (page 21).
606   $aFuel cells$2nasat
606   $aElectric power production from chemical action$xBy-products
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606   $aWater$2fast
615  7$aFuel cells.
615  0$aElectric power production from chemical action$xBy-products.
615  7$aFuel cells.
615  7$aWater.
700   $aProkopius$b Paul R.$01399370
702   $aEaster$b Robert W.
712 02$aUnited States.$bNational Aeronautics and Space Administration,
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