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200 10$aMicro/Nanofluidic and Lab-on-a-Chip Devices for Biomedical Applications
210   $aBasel$cMDPI - Multidisciplinary Digital Publishing Institute$d2022
215   $a1 electronic resource (232 p.)
311   $a3-0365-6100-5 
330   $aRecently, microfluidic, nanofluidic and lab-on-a-chip devices have gained particular attention in biomedical applications. Due to their advantages, such as miniaturization, versatility, ease of use, cost-effectiveness, and the potential to replace animal models for drug development and testing, these devices hold tremendous potential to revolutionize the research of more effective treatments for several diseases that threaten human life. With integrated biosensors, these devices allow the development and design of micro- and nanoparticles to be studied in detail, modelling human physiology, investigating the molecular and cellular mechanisms underlying disease formation and progression, and gaining insights into the performance and long-term effects of responsive drug delivery nanocarriers. This Special Issue gathered research papers, and review articles focusing on novel microfluidic, nanofluidic and lab-on-a-chip devices for biomedical applications, addressing all steps related to fabrication, biosensor integration and development, characterization, numerical simulations and validation of the devices, optimization and, the translation of these devices from research labs to industry settings.
606   $aMedicine$2bicssc
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610   $aimmunoassay
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610   $asmall intestine
610   $aex vivo
610   $ahistology
610   $aembedded resin
610   $asectioning
610   $apeptide biosensor
610   $alab-on-a-chip
610   $alabel-free detection
610   $apeptide aptamers
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610   $atroponin T
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610   $apaper microfluidics
610   $asweat
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610   $ahydrogels
610   $alactate
610   $aosmotic pumping
610   $aevaporation
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610   $awicking
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610   $amicrofluidics
610   $acell trap
610   $aRBC
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610   $aorgan-on-chip
610   $aliver-on-chip
610   $aliver disease
610   $amulti-level microfluidic device
610   $alive cell imaging
610   $along-term microscopy imaging
610   $afocus drifting
610   $aimmersion oil viscosity
610   $abacterial population dynamics
610   $asingle-cell studies
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610   $aadditive manufacturing
610   $apoly-(ethylene glycol)-diacrylate
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610   $aCOVID-19
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610   $aPCR
610   $aSARS-CoV-2
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200 00$aWater-Worked Bedload : $eHydrodynamic and Mass Transport /$fPawe? M. Rowi?ski, Subhasish Dey
210   $cMDPI - Multidisciplinary Digital Publishing Institute$d2019
210  1$aBasel, Switzerland :$cMDPI,$d2019.
215   $a1 electronic resource (152 p.)
311 08$a9783039213016 
311 08$a3039213016 
330   $aThe state-of-the-art in water-worked bed hydraulics can only be examined through a careful exploration of the experimental (both laboratory and field) results via theoretical development. This book is primarily focused on the research aspects that involve a comprehensive knowledge of sediment dynamics in turbulent flows, as the most up-to-date research findings in the field are presented. It begins with two reviews on bedload transport and water-work bed experimental studies. The sediment dynamics is then analyzed from a classical perspective by applying the mean bed shear approach and additionally incorporating a statistical description for the role of turbulence. The work finally examines the local scour problems at hydraulic structures and results from field studies. It is intended as a course guide for field professionals, keeping up with modern technological developments. Therefore, as a simple prerequisite, readers should have a basic knowledge of hydraulics to an undergraduate level.
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610   $alocal bed shear stress
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610   $alogarithmic law of the wall
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610   $aThree Gorges Reservoir
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610   $aMountain River
610   $aaquatic plant biomechanics
610   $avon Ka?rma?n parameter ?
610   $abed shear stress
610   $ariver morphology
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610   $aturbulent kinetic energy
610   $ascour
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