Bio-MEMS: Technologies and ApplicationsWanjun Wang, Steven A. Soper CRC Press, 15 déc. 2006 - 488 pages This book considers both the unique characteristics of biological samples and the challenges of microscale engineering. Divided into three main sections, it first examines fabrication technologies using non-silicon processes, which are suitable for the materials more commonly used in medical/biological analyses. These include UV lithography, LIGA, nanoimprinting, and hot embossing. Attention then shifts to microfluidic components and sensing technologies for sample preparation, delivery, and analysis in microchannels and microchambers. The final section outlines various applications and systems at the leading edge of Bio-MEMS technology in a variety of areas such as drug delivery and proteomics. |
Table des matières
| 1 | |
| 9 | |
| 11 | |
A Fabrication Process for HighAspectRatio Microstructures in Polymers Metals and Ceramics | 43 |
Chapter 4 Nanoimprinting Technology for Biological Applications | 93 |
Chapter 5 Hot Embossing for LabonaChip Applications | 117 |
Part II Microfluidic Devices and Components for BioMEMS | 141 |
Chapter 6 Micropump Applications in BioMEMS | 143 |
Part III Sensing Technologies for BioMEMS Applications | 263 |
Chapter 10 Coupling Electrochemical Detection with Microchip Capillary Electrophoresis | 265 |
Chapter 11 CultureBased Biochip for Rapid Detection of Environmental Mycobacteria | 299 |
Chapter 12 MEMS for Drug Delivery | 325 |
Chapter 13 Microchip Capillary Electrophoresis Systems for DNA Analysis | 349 |
Chapter 14 BioMEMS Devices for Proteomics | 363 |
Chapter 15 SingleCell and SingleMolecule Analyses Using Microfluidic Devices | 391 |
Chapter 16 Pharmaceutical Analysis Using BioMEMS | 443 |
Chapter 7 Micromixers | 177 |
Chapter 8 Microfabricated Devices for Smaple Ectraction Concentrations and Related Sample Processing Technologies | 213 |
Microflow Cytometry and Applications | 237 |
| 467 | |
Back cover | 479 |
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Expressions et termes fréquents
acid Anal analysis Analytical Chemistry applications array aspect ratio assays bio-MEMS biochip biological buffer capillary array capillary electrophoresis cell Chem chemical components cytometer detector developed electric field electrochemical detection electrodes electrokinetic electroplating etching exposure fabrication flow cytometer flow rate fluid fluidic fluorescence glass hot embossing IEEE injection integrated lab-on-a-chip layer LIGA light source mask materials membrane MEMS metal methods micro microchannel microchip microchip electrophoresis microdevices microdialysis Microelectromechanical Systems microfabricated microfluidic chip microfluidic devices micromachining micromixers microneedles microorganisms micropumps microstructures Microsystem miniaturized mixer mixing molecules nanoimprint lithography nickel on-chip optical paraffin particle pattern PDMS peptides photoresist plating PMMA polymer potential pressure protein proteomics pump reaction Reprinted with permission Reynolds number sample Schematic Sensors and Actuators separation sequencing shown in Figure sidewall silicon solution structures SU-8 resist substrate surface techniques temperature thermal thickness tion valve voltage wafer Wang x-ray lithography µm–thick