Lab-on-a-chip: techniques, circuits, and biomedical applications
Gespeichert in:
| 1. Verfasser: | |
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| Format: | Elektronisch E-Book |
| Sprache: | English |
| Veröffentlicht: |
Norwood, Mass.
Artech House
©2010
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| Schriftenreihe: | Artech House integrated microsystems series
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| Schlagworte: | |
| Online-Zugang: | FAW01 FAW02 Volltext |
| Beschreibung: | Includes bibliographical references and index 1. Introduction to Lab-on-a-Chip -- 1.1. History -- 1.2. Parts and Components of Lab-on-a-Chip -- 1.2.1. Electric and Magnetic Actuators -- 1.2.2. Electrical Sensors -- 1.2.3. Thermal Sensors -- 1.2.4. Optical Sensors -- 1.2.5. Microfluidic Chambers -- 1.3. Applications of Lab-on-a-Chip -- 1.4. Advantages and Disadvantages of Lab-on-a-Chip -- References -- 2. Cell Structure, Properties, and Models -- 2.1. Cell Structure -- 2.1.1. Prokaryotic Cells -- 2.1.2. Eukaryotic Cells -- 2.1.3. Cell Components -- 2.2. Electromechanics of Particles -- 2.2.1. Single-Layer Model -- 2.2.2. Double-Layer Model -- 2.3. Electrogenic Cells -- 2.3.1. Neurons -- 2.3.2. Gated Ion Channels -- 2.3.3. Action Potential -- References -- 3. Cell Manipulator Fields -- 3.1. Electric Field -- 3.1.1. Uniform Electric Field (Electrophoresis) -- 3.1.2. Nonuniform Electric Field (Dielectrophoresis) -- 3.2. Magnetic Field -- 3.2.1. Nonuniform Magnetic Field (Magnetophoresis) -- - 3.2.2. Magnetophoresis Force (MAP Force) -- References -- 4. Metal-Oxide Semiconductor (MOS) Technology Fundamentals -- 4.1. Semiconductor Properties -- 4.2. Intrinsic Semiconductors -- 4.3. Extrinsic Semiconductor -- 4.3.1. N-Type Doping -- 4.3.2. P-Type Doping -- 4.4. MOS Device Physics -- 4.5. MOS Characteristics -- 4.5.1. Modes of Operation -- 4.6. Complementary Metal-Oxide Semiconductor (CMOS) Device -- 4.6.1. Advantages of CMOS Technology -- References -- 5. Sensing Techniques for Lab-on-a-Chip -- 5.1. Optical Technique -- 5.2. Fluorescent Labeling Technique -- 5.3. Impedance Sensing Technique -- 5.4. Magnetic Field Sensing Technique -- 5.5. CMOS AC Electrokinetic Microparticle Analysis System -- 5.5.1. Bioanalysis Platform -- 5.5.2. Experimental Tests -- References -- 6. CMOS-Based Lab-on-a-Chip -- 6.1. PCB Lab-on-a-Chip for Micro-Organism Detection and Characterization -- 6.2. Actuation -- 6.3. Impedance Sensing -- - 6.4. CMOS Lab-on-a-Chip for Micro-Organism Detection and Manipulation -- 6.5. CMOS Lab-on-a-Chip for Neuronal Activity Detection -- 6.6. CMOS Lab-on-a-Chip for Cytometry Applications -- 6.7. Flip-Chip Integration -- References -- 7. CMOS Electric-Field-Based Lab-on-a-Chip for Cell Characterization and Detection -- 7.1. Design Flow -- 7.2. Actuation -- 7.3. Electrostatic Simulation -- 7.4. Sensing -- 7.5. The Electric Field Sensitive Field Effect Transistor (eFET) -- 7.6. The Differential Electric Field Sensitive Field Effect Transistor (DeFET) -- 7.7. DeFET Theory of Operation -- 7.8. Modeling the DeFET -- 7.8.1. A Simple DC Model -- 7.8.2. SPICE DC Equivalent Circuit -- 7.8.3. AC Equivalent Circuit -- 7.9. The Effect of the DeFET on the Applied Electric Field Profile -- References -- 8. Prototyping and Experimental Analysis -- 8.1. Testing the DeFET -- 8.1.1. The DC Response -- 8.1.2. The AC (Frequency) Response -- 8.1.3. Other Features of the DeFET -- 8.2. Noise Analysis -- - 8.2.1. Noise Sources -- 8.2.2. Noise Measurements -- 8.3. The Effect of Temperature and Light on DeFET Performance -- 8.4. Testing the Electric Field Imager -- 8.4.1. The Response of the Imager Under Different Environments -- 8.4.2. Testing the Imager with Biocells -- 8.5. Packaging the Lab-on-a-Chip -- References -- 9. Readout Circuits for Lab-on-a-Chip -- 9.1. Current-Mode Circuits -- 9.2. Operational Floating Current Conveyor (OFCC) -- 9.2.1. A Simple Model -- 9.2.2. OFCC with Feedback -- 9.3. Current-Mode Instrumentation Amplifier -- 9.3.1. Current-Mode Instrumentation Amplifier (CMIA) Based on CCII -- 9.3.2. Current-Mode Instrumentation Amplifier Based on OFCC -- 9.4. Experimental and Simulation Results of the Proposed CMIA -- 9.4.1. The Differential Gain Measurements -- 9.4.2. Common-Mode Rejection Ratio Measurements -- 9.4.3. Other Features of the Proposed CMIA -- 9.4.4. Noise Results -- 9.5. Comparison Between Different CMIAs -- - 9.6. Testing the Readout Circuit with the Electric Field Based Lab-on-a-Chip -- References -- 10. Current-Mode Wheatstone Bridge for Lab-on-a-Chip Applications -- 10.1. Introduction -- 10.2. CMWB Based on Operational Floating Current Conveyor -- 10.3. A Linearization Technique Based on an Operational Floating Current Conveyor -- 10.4. Experimental and Simulation Results -- 10.4.1. The Differential Measurements -- 10.4.2. Common-Mode Measurements -- 10.5. Discussion -- References -- 11. Current-Mode Readout Circuits for the pH Sensor -- 11.1. Introduction -- 11.2. Differential ISFET-Based pH Sensor -- 11.2.1. ISFET-Based pH Sensor -- 11.2.2. Differential ISFET Sensor -- 11.3. pH Readout Circuit Based on an Operational Floating Current Conveyor -- 11.3.1. Simulation Results -- 11.4. pH Readout Circuit Using Only Two Operational Floating Current Conveyors -- 11.4.1. Simulation Results -- References |
| Beschreibung: | 1 Online-Ressource (xv, 220 p.) |
| ISBN: | 1596934182 1596934190 9781596934184 9781596934191 |
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| 264 | 1 | |a Norwood, Mass. |b Artech House |c ©2010 | |
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| 500 | |a Includes bibliographical references and index | ||
| 500 | |a 1. Introduction to Lab-on-a-Chip -- 1.1. History -- 1.2. Parts and Components of Lab-on-a-Chip -- 1.2.1. Electric and Magnetic Actuators -- 1.2.2. Electrical Sensors -- 1.2.3. Thermal Sensors -- 1.2.4. Optical Sensors -- 1.2.5. Microfluidic Chambers -- 1.3. Applications of Lab-on-a-Chip -- 1.4. Advantages and Disadvantages of Lab-on-a-Chip -- References -- 2. Cell Structure, Properties, and Models -- 2.1. Cell Structure -- 2.1.1. Prokaryotic Cells -- 2.1.2. Eukaryotic Cells -- 2.1.3. Cell Components -- 2.2. Electromechanics of Particles -- 2.2.1. Single-Layer Model -- 2.2.2. Double-Layer Model -- 2.3. Electrogenic Cells -- 2.3.1. Neurons -- 2.3.2. Gated Ion Channels -- 2.3.3. Action Potential -- References -- 3. Cell Manipulator Fields -- 3.1. Electric Field -- 3.1.1. Uniform Electric Field (Electrophoresis) -- 3.1.2. Nonuniform Electric Field (Dielectrophoresis) -- 3.2. Magnetic Field -- 3.2.1. Nonuniform Magnetic Field (Magnetophoresis) -- | ||
| 500 | |a - 3.2.2. Magnetophoresis Force (MAP Force) -- References -- 4. Metal-Oxide Semiconductor (MOS) Technology Fundamentals -- 4.1. Semiconductor Properties -- 4.2. Intrinsic Semiconductors -- 4.3. Extrinsic Semiconductor -- 4.3.1. N-Type Doping -- 4.3.2. P-Type Doping -- 4.4. MOS Device Physics -- 4.5. MOS Characteristics -- 4.5.1. Modes of Operation -- 4.6. Complementary Metal-Oxide Semiconductor (CMOS) Device -- 4.6.1. Advantages of CMOS Technology -- References -- 5. Sensing Techniques for Lab-on-a-Chip -- 5.1. Optical Technique -- 5.2. Fluorescent Labeling Technique -- 5.3. Impedance Sensing Technique -- 5.4. Magnetic Field Sensing Technique -- 5.5. CMOS AC Electrokinetic Microparticle Analysis System -- 5.5.1. Bioanalysis Platform -- 5.5.2. Experimental Tests -- References -- 6. CMOS-Based Lab-on-a-Chip -- 6.1. PCB Lab-on-a-Chip for Micro-Organism Detection and Characterization -- 6.2. Actuation -- 6.3. Impedance Sensing -- | ||
| 500 | |a - 6.4. CMOS Lab-on-a-Chip for Micro-Organism Detection and Manipulation -- 6.5. CMOS Lab-on-a-Chip for Neuronal Activity Detection -- 6.6. CMOS Lab-on-a-Chip for Cytometry Applications -- 6.7. Flip-Chip Integration -- References -- 7. CMOS Electric-Field-Based Lab-on-a-Chip for Cell Characterization and Detection -- 7.1. Design Flow -- 7.2. Actuation -- 7.3. Electrostatic Simulation -- 7.4. Sensing -- 7.5. The Electric Field Sensitive Field Effect Transistor (eFET) -- 7.6. The Differential Electric Field Sensitive Field Effect Transistor (DeFET) -- 7.7. DeFET Theory of Operation -- 7.8. Modeling the DeFET -- 7.8.1. A Simple DC Model -- 7.8.2. SPICE DC Equivalent Circuit -- 7.8.3. AC Equivalent Circuit -- 7.9. The Effect of the DeFET on the Applied Electric Field Profile -- References -- 8. Prototyping and Experimental Analysis -- 8.1. Testing the DeFET -- 8.1.1. The DC Response -- 8.1.2. The AC (Frequency) Response -- 8.1.3. Other Features of the DeFET -- 8.2. Noise Analysis -- | ||
| 500 | |a - 8.2.1. Noise Sources -- 8.2.2. Noise Measurements -- 8.3. The Effect of Temperature and Light on DeFET Performance -- 8.4. Testing the Electric Field Imager -- 8.4.1. The Response of the Imager Under Different Environments -- 8.4.2. Testing the Imager with Biocells -- 8.5. Packaging the Lab-on-a-Chip -- References -- 9. Readout Circuits for Lab-on-a-Chip -- 9.1. Current-Mode Circuits -- 9.2. Operational Floating Current Conveyor (OFCC) -- 9.2.1. A Simple Model -- 9.2.2. OFCC with Feedback -- 9.3. Current-Mode Instrumentation Amplifier -- 9.3.1. Current-Mode Instrumentation Amplifier (CMIA) Based on CCII -- 9.3.2. Current-Mode Instrumentation Amplifier Based on OFCC -- 9.4. Experimental and Simulation Results of the Proposed CMIA -- 9.4.1. The Differential Gain Measurements -- 9.4.2. Common-Mode Rejection Ratio Measurements -- 9.4.3. Other Features of the Proposed CMIA -- 9.4.4. Noise Results -- 9.5. Comparison Between Different CMIAs -- | ||
| 500 | |a - 9.6. Testing the Readout Circuit with the Electric Field Based Lab-on-a-Chip -- References -- 10. Current-Mode Wheatstone Bridge for Lab-on-a-Chip Applications -- 10.1. Introduction -- 10.2. CMWB Based on Operational Floating Current Conveyor -- 10.3. A Linearization Technique Based on an Operational Floating Current Conveyor -- 10.4. Experimental and Simulation Results -- 10.4.1. The Differential Measurements -- 10.4.2. Common-Mode Measurements -- 10.5. Discussion -- References -- 11. Current-Mode Readout Circuits for the pH Sensor -- 11.1. Introduction -- 11.2. Differential ISFET-Based pH Sensor -- 11.2.1. ISFET-Based pH Sensor -- 11.2.2. Differential ISFET Sensor -- 11.3. pH Readout Circuit Based on an Operational Floating Current Conveyor -- 11.3.1. Simulation Results -- 11.4. pH Readout Circuit Using Only Two Operational Floating Current Conveyors -- 11.4.1. Simulation Results -- References | ||
| 650 | 7 | |a TECHNOLOGY & ENGINEERING / Electronics / Microelectronics |2 bisacsh | |
| 650 | 7 | |a TECHNOLOGY & ENGINEERING / Electronics / Digital |2 bisacsh | |
| 650 | 4 | |a Microelectromechanical systems | |
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Datensatz im Suchindex
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| author | Ghallab, Yehya H. |
| author_facet | Ghallab, Yehya H. |
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| ctrlnum | (OCoLC)670429834 (DE-599)BVBBV043139012 |
| dewey-full | 621.381 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 621 - Applied physics |
| dewey-raw | 621.381 |
| dewey-search | 621.381 |
| dewey-sort | 3621.381 |
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| discipline | Elektrotechnik / Elektronik / Nachrichtentechnik |
| format | Electronic eBook |
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Prototyping and Experimental Analysis -- 8.1. Testing the DeFET -- 8.1.1. The DC Response -- 8.1.2. The AC (Frequency) Response -- 8.1.3. Other Features of the DeFET -- 8.2. Noise Analysis -- </subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a"> - 8.2.1. Noise Sources -- 8.2.2. Noise Measurements -- 8.3. The Effect of Temperature and Light on DeFET Performance -- 8.4. Testing the Electric Field Imager -- 8.4.1. The Response of the Imager Under Different Environments -- 8.4.2. Testing the Imager with Biocells -- 8.5. Packaging the Lab-on-a-Chip -- References -- 9. Readout Circuits for Lab-on-a-Chip -- 9.1. Current-Mode Circuits -- 9.2. Operational Floating Current Conveyor (OFCC) -- 9.2.1. A Simple Model -- 9.2.2. OFCC with Feedback -- 9.3. Current-Mode Instrumentation Amplifier -- 9.3.1. Current-Mode Instrumentation Amplifier (CMIA) Based on CCII -- 9.3.2. Current-Mode Instrumentation Amplifier Based on OFCC -- 9.4. Experimental and Simulation Results of the Proposed CMIA -- 9.4.1. The Differential Gain Measurements -- 9.4.2. Common-Mode Rejection Ratio Measurements -- 9.4.3. Other Features of the Proposed CMIA -- 9.4.4. Noise Results -- 9.5. Comparison Between Different CMIAs -- </subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a"> - 9.6. Testing the Readout Circuit with the Electric Field Based Lab-on-a-Chip -- References -- 10. Current-Mode Wheatstone Bridge for Lab-on-a-Chip Applications -- 10.1. Introduction -- 10.2. CMWB Based on Operational Floating Current Conveyor -- 10.3. A Linearization Technique Based on an Operational Floating Current Conveyor -- 10.4. Experimental and Simulation Results -- 10.4.1. The Differential Measurements -- 10.4.2. Common-Mode Measurements -- 10.5. Discussion -- References -- 11. Current-Mode Readout Circuits for the pH Sensor -- 11.1. Introduction -- 11.2. Differential ISFET-Based pH Sensor -- 11.2.1. ISFET-Based pH Sensor -- 11.2.2. Differential ISFET Sensor -- 11.3. pH Readout Circuit Based on an Operational Floating Current Conveyor -- 11.3.1. Simulation Results -- 11.4. pH Readout Circuit Using Only Two Operational Floating Current Conveyors -- 11.4.1. 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| id | DE-604.BV043139012 |
| illustrated | Not Illustrated |
| indexdate | 2024-07-10T07:18:38Z |
| institution | BVB |
| isbn | 1596934182 1596934190 9781596934184 9781596934191 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-028563203 |
| oclc_num | 670429834 |
| open_access_boolean | |
| owner | DE-1046 DE-1047 |
| owner_facet | DE-1046 DE-1047 |
| physical | 1 Online-Ressource (xv, 220 p.) |
| psigel | ZDB-4-EBA ZDB-4-EBA FAW_PDA_EBA |
| publishDate | 2010 |
| publishDateSearch | 2010 |
| publishDateSort | 2010 |
| publisher | Artech House |
| record_format | marc |
| series2 | Artech House integrated microsystems series |
| spelling | Ghallab, Yehya H. Verfasser aut Lab-on-a-chip techniques, circuits, and biomedical applications Yahya H. Ghallab, Wael Badawy Norwood, Mass. Artech House ©2010 1 Online-Ressource (xv, 220 p.) txt rdacontent c rdamedia cr rdacarrier Artech House integrated microsystems series Includes bibliographical references and index 1. Introduction to Lab-on-a-Chip -- 1.1. History -- 1.2. Parts and Components of Lab-on-a-Chip -- 1.2.1. Electric and Magnetic Actuators -- 1.2.2. Electrical Sensors -- 1.2.3. Thermal Sensors -- 1.2.4. Optical Sensors -- 1.2.5. Microfluidic Chambers -- 1.3. Applications of Lab-on-a-Chip -- 1.4. Advantages and Disadvantages of Lab-on-a-Chip -- References -- 2. Cell Structure, Properties, and Models -- 2.1. Cell Structure -- 2.1.1. Prokaryotic Cells -- 2.1.2. Eukaryotic Cells -- 2.1.3. Cell Components -- 2.2. Electromechanics of Particles -- 2.2.1. Single-Layer Model -- 2.2.2. Double-Layer Model -- 2.3. Electrogenic Cells -- 2.3.1. Neurons -- 2.3.2. Gated Ion Channels -- 2.3.3. Action Potential -- References -- 3. Cell Manipulator Fields -- 3.1. Electric Field -- 3.1.1. Uniform Electric Field (Electrophoresis) -- 3.1.2. Nonuniform Electric Field (Dielectrophoresis) -- 3.2. Magnetic Field -- 3.2.1. Nonuniform Magnetic Field (Magnetophoresis) -- - 3.2.2. Magnetophoresis Force (MAP Force) -- References -- 4. Metal-Oxide Semiconductor (MOS) Technology Fundamentals -- 4.1. Semiconductor Properties -- 4.2. Intrinsic Semiconductors -- 4.3. Extrinsic Semiconductor -- 4.3.1. N-Type Doping -- 4.3.2. P-Type Doping -- 4.4. MOS Device Physics -- 4.5. MOS Characteristics -- 4.5.1. Modes of Operation -- 4.6. Complementary Metal-Oxide Semiconductor (CMOS) Device -- 4.6.1. Advantages of CMOS Technology -- References -- 5. Sensing Techniques for Lab-on-a-Chip -- 5.1. Optical Technique -- 5.2. Fluorescent Labeling Technique -- 5.3. Impedance Sensing Technique -- 5.4. Magnetic Field Sensing Technique -- 5.5. CMOS AC Electrokinetic Microparticle Analysis System -- 5.5.1. Bioanalysis Platform -- 5.5.2. Experimental Tests -- References -- 6. CMOS-Based Lab-on-a-Chip -- 6.1. PCB Lab-on-a-Chip for Micro-Organism Detection and Characterization -- 6.2. Actuation -- 6.3. Impedance Sensing -- - 6.4. CMOS Lab-on-a-Chip for Micro-Organism Detection and Manipulation -- 6.5. CMOS Lab-on-a-Chip for Neuronal Activity Detection -- 6.6. CMOS Lab-on-a-Chip for Cytometry Applications -- 6.7. Flip-Chip Integration -- References -- 7. CMOS Electric-Field-Based Lab-on-a-Chip for Cell Characterization and Detection -- 7.1. Design Flow -- 7.2. Actuation -- 7.3. Electrostatic Simulation -- 7.4. Sensing -- 7.5. The Electric Field Sensitive Field Effect Transistor (eFET) -- 7.6. The Differential Electric Field Sensitive Field Effect Transistor (DeFET) -- 7.7. DeFET Theory of Operation -- 7.8. Modeling the DeFET -- 7.8.1. A Simple DC Model -- 7.8.2. SPICE DC Equivalent Circuit -- 7.8.3. AC Equivalent Circuit -- 7.9. The Effect of the DeFET on the Applied Electric Field Profile -- References -- 8. Prototyping and Experimental Analysis -- 8.1. Testing the DeFET -- 8.1.1. The DC Response -- 8.1.2. The AC (Frequency) Response -- 8.1.3. Other Features of the DeFET -- 8.2. Noise Analysis -- - 8.2.1. Noise Sources -- 8.2.2. Noise Measurements -- 8.3. The Effect of Temperature and Light on DeFET Performance -- 8.4. Testing the Electric Field Imager -- 8.4.1. The Response of the Imager Under Different Environments -- 8.4.2. Testing the Imager with Biocells -- 8.5. Packaging the Lab-on-a-Chip -- References -- 9. Readout Circuits for Lab-on-a-Chip -- 9.1. Current-Mode Circuits -- 9.2. Operational Floating Current Conveyor (OFCC) -- 9.2.1. A Simple Model -- 9.2.2. OFCC with Feedback -- 9.3. Current-Mode Instrumentation Amplifier -- 9.3.1. Current-Mode Instrumentation Amplifier (CMIA) Based on CCII -- 9.3.2. Current-Mode Instrumentation Amplifier Based on OFCC -- 9.4. Experimental and Simulation Results of the Proposed CMIA -- 9.4.1. The Differential Gain Measurements -- 9.4.2. Common-Mode Rejection Ratio Measurements -- 9.4.3. Other Features of the Proposed CMIA -- 9.4.4. Noise Results -- 9.5. Comparison Between Different CMIAs -- - 9.6. Testing the Readout Circuit with the Electric Field Based Lab-on-a-Chip -- References -- 10. Current-Mode Wheatstone Bridge for Lab-on-a-Chip Applications -- 10.1. Introduction -- 10.2. CMWB Based on Operational Floating Current Conveyor -- 10.3. A Linearization Technique Based on an Operational Floating Current Conveyor -- 10.4. Experimental and Simulation Results -- 10.4.1. The Differential Measurements -- 10.4.2. Common-Mode Measurements -- 10.5. Discussion -- References -- 11. Current-Mode Readout Circuits for the pH Sensor -- 11.1. Introduction -- 11.2. Differential ISFET-Based pH Sensor -- 11.2.1. ISFET-Based pH Sensor -- 11.2.2. Differential ISFET Sensor -- 11.3. pH Readout Circuit Based on an Operational Floating Current Conveyor -- 11.3.1. Simulation Results -- 11.4. pH Readout Circuit Using Only Two Operational Floating Current Conveyors -- 11.4.1. Simulation Results -- References TECHNOLOGY & ENGINEERING / Electronics / Microelectronics bisacsh TECHNOLOGY & ENGINEERING / Electronics / Digital bisacsh Microelectromechanical systems Chemical laboratories Electronic equipment Biomedical engineering Lab on a Chip (DE-588)7610677-9 gnd rswk-swf Lab on a Chip (DE-588)7610677-9 s 1\p DE-604 Badawy, Wael Sonstige oth http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=339512 Aggregator Volltext 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk |
| spellingShingle | Ghallab, Yehya H. Lab-on-a-chip techniques, circuits, and biomedical applications TECHNOLOGY & ENGINEERING / Electronics / Microelectronics bisacsh TECHNOLOGY & ENGINEERING / Electronics / Digital bisacsh Microelectromechanical systems Chemical laboratories Electronic equipment Biomedical engineering Lab on a Chip (DE-588)7610677-9 gnd |
| subject_GND | (DE-588)7610677-9 |
| title | Lab-on-a-chip techniques, circuits, and biomedical applications |
| title_auth | Lab-on-a-chip techniques, circuits, and biomedical applications |
| title_exact_search | Lab-on-a-chip techniques, circuits, and biomedical applications |
| title_full | Lab-on-a-chip techniques, circuits, and biomedical applications Yahya H. Ghallab, Wael Badawy |
| title_fullStr | Lab-on-a-chip techniques, circuits, and biomedical applications Yahya H. Ghallab, Wael Badawy |
| title_full_unstemmed | Lab-on-a-chip techniques, circuits, and biomedical applications Yahya H. Ghallab, Wael Badawy |
| title_short | Lab-on-a-chip |
| title_sort | lab on a chip techniques circuits and biomedical applications |
| title_sub | techniques, circuits, and biomedical applications |
| topic | TECHNOLOGY & ENGINEERING / Electronics / Microelectronics bisacsh TECHNOLOGY & ENGINEERING / Electronics / Digital bisacsh Microelectromechanical systems Chemical laboratories Electronic equipment Biomedical engineering Lab on a Chip (DE-588)7610677-9 gnd |
| topic_facet | TECHNOLOGY & ENGINEERING / Electronics / Microelectronics TECHNOLOGY & ENGINEERING / Electronics / Digital Microelectromechanical systems Chemical laboratories Electronic equipment Biomedical engineering Lab on a Chip |
| url | http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=339512 |
| work_keys_str_mv | AT ghallabyehyah labonachiptechniquescircuitsandbiomedicalapplications AT badawywael labonachiptechniquescircuitsandbiomedicalapplications |