| 000 | 06322cam a2200373Ia 4500 | ||
|---|---|---|---|
| 001 | 7941136 | ||
| 003 | BD-DhUL | ||
| 005 | 20150117141003.0 | ||
| 008 | 100308s2010 maua b 001 0 eng d | ||
| 020 | _a1596934182 | ||
| 020 | _a9781596934184 | ||
| 024 | _a40018182495 | ||
| 035 | _a(OCoLC)ocn548660610 | ||
| 035 | _a(OCoLC)548660610 | ||
| 035 | _a(NNC)7941136 | ||
| 040 |
_aBTCTA _beng _cBTCTA _dYDXCP _dCDX _dCIT _dNhCcYBP _dOrLoB-B _dBD-DhUL |
||
| 050 | 1 | 4 |
_aTK7875 _b.G43 2010 |
| 082 | 0 | 4 |
_a621.381 _bGHL |
| 100 | 1 | _aGhallab, Yehya H. | |
| 245 | 1 | 0 |
_aLab-on-a-chip : _btechniques, circuits, and biomedical applications / _cYahya H. Ghallab, Wael Badawy |
| 260 |
_aNorwood, MA : _bArtech House, _cc2010. |
||
| 300 |
_axv, 220 p. : _bill. ; _c24 cm. |
||
| 490 | 1 | _aArtech House integrated microsystems series | |
| 504 | _aIncludes bibliographic references and index. | ||
| 505 | 0 | 0 |
_g1. _tIntroduction to Lab-on-a-Chip -- _g1.1. _tHistory -- _g1.2. _tParts and Components of Lab-on-a-Chip -- _g1.2.1. _tElectric and Magnetic Actuators -- _g1.2.2. _tElectrical Sensors -- _g1.2.3. _tThermal Sensors -- _g1.2.4. _tOptical Sensors -- _g1.2.5. _tMicrofluidic Chambers -- _g1.3. _tApplications of Lab-on-a-Chip -- _g1.4. _tAdvantages and Disadvantages of Lab-on-a-Chip -- _tReferences -- _g2. _tCell Structure, Properties, and Models -- _g2.1. _tCell Structure -- _g2.1.1. _tProkaryotic Cells -- _g2.1.2. _tEukaryotic Cells -- _g2.1.3. _tCell Components -- _g2.2. _tElectromechanics of Particles -- _g2.2.1. _tSingle-Layer Model -- _g2.2.2. _tDouble-Layer Model -- _g2.3. _tElectrogenic Cells -- _g2.3.1. _tNeurons -- _g2.3.2. _tGated Ion Channels -- _g2.3.3. _tAction Potential -- _tReferences -- _g3. _tCell Manipulator Fields -- _g3.1. _tElectric Field -- _g3.1.1. _tUniform Electric Field (Electrophoresis) -- _g3.1.2. _tNonuniform Electric Field (Dielectrophoresis) -- _g3.2. _tMagnetic Field -- _g3.2.1. _tNonuniform Magnetic Field (Magnetophoresis) -- _g3.2.2. _tMagnetophoresis Force (MAP Force) -- _tReferences -- _g4. _tMetal-Oxide Semiconductor (MOS) Technology Fundamentals -- _g4.1. _tSemiconductor Properties -- _g4.2. _tIntrinsic Semiconductors -- _g4.3. _tExtrinsic Semiconductor -- _g4.3.1. _tN-Type Doping -- _g4.3.2. _tP-Type Doping -- _g4.4. _tMOS Device Physics -- _g4.5. _tMOS Characteristics -- _g4.5.1. _tModes of Operation -- _g4.6. _tComplementary Metal-Oxide Semiconductor (CMOS) Device -- _g4.6.1. _tAdvantages of CMOS Technology -- _tReferences -- _g5. _tSensing Techniques for Lab-on-a-Chip -- _g5.1. _tOptical Technique -- _g5.2. _tFluorescent Labeling Technique -- _g5.3. _tImpedance Sensing Technique -- _g5.4. _tMagnetic Field Sensing Technique -- _g5.5. _tCMOS AC Electrokinetic Microparticle Analysis System -- _g5.5.1. _tBioanalysis Platform -- _g5.5.2. _tExperimental Tests -- _tReferences -- _g6. _tCMOS-Based Lab-on-a-Chip -- _g6.1. _tPCB Lab-on-a-Chip for Micro-Organism Detection and Characterization -- _g6.2. _tActuation -- _g6.3. _tImpedance Sensing -- _g6.4. _tCMOS Lab-on-a-Chip for Micro-Organism Detection and Manipulation -- _g6.5. _tCMOS Lab-on-a-Chip for Neuronal Activity Detection -- _g6.6. _tCMOS Lab-on-a-Chip for Cytometry Applications -- _g6.7. _tFlip-Chip Integration -- _tReferences -- _g7. _tCMOS Electric-Field-Based Lab-on-a-Chip for Cell Characterization and Detection -- _g7.1. _tDesign Flow -- _g7.2. _tActuation -- _g7.3. _tElectrostatic Simulation -- _g7.4. _tSensing -- _g7.5. _tThe Electric Field Sensitive Field Effect Transistor (eFET) -- _g7.6. _tThe Differential Electric Field Sensitive Field Effect Transistor (DeFET) -- _g7.7. _tDeFET Theory of Operation -- _g7.8. _tModeling the DeFET -- _g7.8.1. _tA Simple DC Model -- _g7.8.2. _tSPICE DC Equivalent Circuit -- _g7.8.3. _tAC Equivalent Circuit -- _g7.9. _tThe Effect of the DeFET on the Applied Electric Field Profile -- _tReferences -- _g8. _tPrototyping and Experimental Analysis -- _g8.1. _tTesting the DeFET -- _g8.1.1. _tThe DC Response -- _g8.1.2. _tThe AC (Frequency) Response -- _g8.1.3. _tOther Features of the DeFET -- _g8.2. _tNoise Analysis -- _g8.2.1. _tNoise Sources -- _g8.2.2. _tNoise Measurements -- _g8.3. _tThe Effect of Temperature and Light on DeFET Performance -- _g8.4. _tTesting the Electric Field Imager -- _g8.4.1. _tThe Response of the Imager Under Different Environments -- _g8.4.2. _tTesting the Imager with Biocells -- _g8.5. _tPackaging the Lab-on-a-Chip -- _tReferences -- _g9. _tReadout Circuits for Lab-on-a-Chip -- _g9.1. _tCurrent-Mode Circuits -- _g9.2. _tOperational Floating Current Conveyor (OFCC) -- _g9.2.1. _tA Simple Model -- _g9.2.2. _tOFCC with Feedback -- _g9.3. _tCurrent-Mode Instrumentation Amplifier -- _g9.3.1. _tCurrent-Mode Instrumentation Amplifier (CMIA) Based on CCII -- _g9.3.2. _tCurrent-Mode Instrumentation Amplifier Based on OFCC -- _g9.4. _tExperimental and Simulation Results of the Proposed CMIA -- _g9.4.1. _tThe Differential Gain Measurements -- _g9.4.2. _tCommon-Mode Rejection Ratio Measurements -- _g9.4.3. _tOther Features of the Proposed CMIA -- _g9.4.4. _tNoise Results -- _g9.5. _tComparison Between Different CMIAs -- _g9.6. _tTesting the Readout Circuit with the Electric Field Based Lab-on-a-Chip -- _tReferences -- _g10. _tCurrent-Mode Wheatstone Bridge for Lab-on-a-Chip Applications -- _g10.1. _tIntroduction -- _g10.2. _tCMWB Based on Operational Floating Current Conveyor -- _g10.3. _tA Linearization Technique Based on an Operational Floating Current Conveyor -- _g10.4. _tExperimental and Simulation Results -- _g10.4.1. _tThe Differential Measurements -- _g10.4.2. _tCommon-Mode Measurements -- _g10.5. _tDiscussion -- _tReferences -- _g11. _tCurrent-Mode Readout Circuits for the pH Sensor -- _g11.1. _tIntroduction -- _g11.2. _tDifferential ISFET-Based pH Sensor -- _g11.2.1. _tISFET-Based pH Sensor -- _g11.2.2. _tDifferential ISFET Sensor -- _g11.3. _tpH Readout Circuit Based on an Operational Floating Current Conveyor -- _g11.3.1. _tSimulation Results -- _g11.4. _tpH Readout Circuit Using Only Two Operational Floating Current Conveyors -- _g11.4.1. _tSimulation Results -- _tReferences. |
| 650 | 0 | _aMicroelectromechanical systems. | |
| 650 | 0 |
_aChemical laboratories _xElectronic equipment. |
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| 650 | 0 | _aBiomedical engineering. | |
| 700 | 1 | _aBadawy, Wael. | |
| 830 | 0 | _aArtech House integrated microsystems series. | |
| 900 |
_aAUTH _bTOC |
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