Miniature Fluidic Devices for Rapid Biological Detection

Focuses on rapid detection using miniaturized sensors

Describes the physical principles of nanoscale sensors, surface modifications, microfluids and reaction engineering, diffusion and kinetics

Covers fundamental aspects of surface-based biosensors and techniques for enhancing their detection sensitivity and speed

Focuses on rapid detection using miniaturized sensors Describes the physical principles of nanoscale sensors, surface modifications, microfluids and reaction engineering, diffusion and kinetics Covers fundamental aspects of surface-based biosensors and techniques for enhancing their detection sensitivity and speed

Auteur

Sang-Hyun Oh is a Sanford P. Bordeau Professor in the Department of Electrical and Computer Engineering at the University of Minnesota, Twin Cities. He received his PhD in Applied Physics from Stanford University. His research interests include nanotechnology, biosensors, nano-optics, and nanofabrication.

Carlos Escobedo is an Assistant Professor in the Department of Chemical Engineering at Queen's University. He received his PhD in Mechanical Engineering from the University of Victoria. His research interests include the development of (bio)sensing technology, and microfluidic platforms to advance knowledge in medicine and biology.

Alexandre G. Brolo is a Professor of Chemistry at the University of Victoria, Canada. He received his PhD in Physical Chemistry from the University of Waterloo, Canada. His current research interest includes surface spectroscopy, biosensors and metallic nanostructures.

Résumé
Focuses on rapid detection using miniaturized sensors

Describes the physical principles of nanoscale sensors, surface modifications, microfluids and reaction engineering, diffusion and kinetics

Covers fundamental aspects of surface-based biosensors and techniques for enhancing their detection sensitivity and speed

Contenu
Optical trapping of biomolecules.- Microfluidic detection for energy applications.- Nanoplasmonic biosensors.- Nanopores for molecules sensing.- Optofluidics.- SERS using papers.- Dielectrophoresis-enhanced nanoplasmonic sensors.- Molecular transport in nanoscale sensors.- Single cell analysis.- Multiplex microfluidic devices.- Optofluidics.- Neurochemical biosensing.- Lens-free on-chip biosensing.- Single-cell analysis.- Digital microfluidics.