Features a unique hybrid approach (CMOS + Bio, CMOS + Microfluidics)
Applies CMOS outside of its traditional application areas and into fields such as biology
Provides a useful reference for the circuits, MEMS, and bioengineering communities
Features a unique hybrid approach (CMOS + Bio, CMOS + Microfluidics)
Applies CMOS outside of its traditional application areas and into fields such as biology
Provides a useful reference for the circuits, MEMS, and bioengineering communities
Includes supplementary material: sn.pub/extras
Lately, there has been a growing interest in exploiting the benefits of the ICs for areas outside of the traditional application spaces. One noteable area is found in biology Bioanalytical instruments have been miniaturized on ICs to study various biophenomena or to actuate biosystems. These biolab-on-IC systems utilize the IC to facilitate faster, repeatable, and standardized biological experiments at low cost with a small volume of biological sample. The research activities in this field are expected to enjoy substantial growth in the foreseeable future. BioCMOS Technologies reviews these exciting recent efforts in joining CMOS technology with biology.
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CMOS Biotechnology reviews the recent research and developments joining CMOS technology with biology. Written by leading researchers these chapters delve into four areas including:
- Microfluidics for electrical engineers
- CMOS Actuators
- CMOS Electrical Sensors
- CMOS Optical Sensors
Bioanalytical instruments have been miniaturized on ICs to study various biophenomena or to actuate biosystems. These bio-lab-on-IC systems utilize the IC to facilitate faster, repeatable, and standardized biological experiments at low cost with a small volume of biological sample. CMOS Biotechnology will interest electrical engineers, bioengineers, biophysicists as well as researchers in MEMS, bioMEMS, microelectronics, microfluidics, and circuits and systems.
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Today´s semiconductor integrated circuits can contain over 100 million transistors, operate at GHz speeds, process Gbyte data, and can be manufactured inexpensively. These advantages have allowed ICs to become one of the most significant enabling technologies of this time, lying at the heart of today's advanced computers, communication systems, and multimedia hardware.
Lately, there has been a growing interest in exploiting the benefits of the ICs for areas outside of the traditional application spaces. One notable area is found in biology Bioanalytical instruments have been miniaturized on ICs to study various biophenomena or to actuate biosystems. These biolab-on-IC systems utilize the IC to facilitate faster, repeatable, and standardized biological experiments at low cost with a small volume of biological sample. The research activities in this field are expected to enjoy substantial growth in the foreseeable future. BioCMOS Technologies reviews these exciting recent efforts in joining CMOS technology with biology.
Microfluidics for Electrical Engineers.- to Fluid Dynamics for Microfluidic Flows.- Micro- and Nanofluidics for Biological Separations.- CMOS/Microfluidic Hybrid Systems.- CMOS Actuators.- CMOS-based Magnetic Cell Manipulation System.- Applications of Dielectrophoresis-based Lab-on-a-chip Devices in Pharmaceutical Sciences and Biomedicine.- CMOS Electronic Microarrays in Diagnostics and Nanotechnology.- CMOS Electrical Sensors.- Integrated Microelectrode Arrays.- CMOS ICs for Brain Implantable Neural Recording Microsystems.- CMOS Optical Sensors.- Optofluidic Microscope – Fitting a Microscope onto a Sensor Chip.- CMOS Sensors for Optical Molecular Imaging.
Lately, there has been a growing interest in exploiting the benefits of the ICs for areas outside of the traditional application spaces. These biolab-on-IC systems utilize the IC to facilitate faster, repeatable, and standardized biological experiments at low cost with a small volume of biological sample.
CMOS Biotechnology reviews the recent research and developments joining CMOS technology with biology. Written by leading researchers these chapters delve into four areas including:
- Microfluidics for electrical engineers
- CMOS Actuators
- CMOS Electrical Sensors
- CMOS Optical Sensors
Bioanalytical instruments have been miniaturized on ICs to study various biophenomena or to actuate biosystems. These bio-lab-on-IC systems utilize the IC to facilitate faster, repeatable, and standardized biological experiments at low cost with a small volume of biological sample. CMOS Biotechnology will interest electrical engineers, bioengineers, biophysicists as well as researchers in MEMS, bioMEMS, microelectronics, microfluidics, and circuits and systems.
Microfluidics for Electrical Engineers.- to Fluid Dynamics for Microfluidic Flows.- Micro- and Nanofluidics for Biological Separations.- CMOS/Microfluidic Hybrid Systems.- CMOS Actuators.- CMOS-based Magnetic Cell Manipulation System.- Applications of Dielectrophoresis-based Lab-on-a-chip Devices in Pharmaceutical Sciences and Biomedicine.- CMOS Electronic Microarrays in Diagnostics and Nanotechnology.- CMOS Electrical Sensors.- Integrated Microelectrode Arrays.- CMOS ICs for Brain Implantable Neural Recording Microsystems.- CMOS Optical Sensors.- Optofluidic Microscope - Fitting a Microscope onto a Sensor Chip.- CMOS Sensors for Optical Molecular Imaging.
Today s semiconductor integrated circuits can contain over 100 million transistors, operate at GHz speeds, process Gbyte data, and can be manufactured inexpensively. These advantages have allowed ICs to become one of the most significant enabling technologies of this time, lying at the heart of today's advanced computers, communication systems, and multimedia hardware.
Lately, there has been a growing interest in exploiting the benefits of the ICs for areas outside of the traditional application spaces. One notable area is found in biology Bioanalytical instruments have been miniaturized on ICs to study various biophenomena or to actuate biosystems. These biolab-on-IC systems utilize the IC to facilitate faster, repeatable, and standardized biological experiments at low cost with a small volume of biological sample. The research activities in this field are expected to enjoy substantial growth in the foreseeable future. BioCMOS Technologies reviews these exciting recent efforts in joining CMOS technology with biology.
Inhaltsverzeichnis
Microfluidics for Electrical Engineers.- to Fluid Dynamics for Microfluidic Flows.- Micro- and Nanofluidics for Biological Separations.- CMOS/Microfluidic Hybrid Systems.- CMOS Actuators.- CMOS-based Magnetic Cell Manipulation System.- Applications of Dielectrophoresis-based Lab-on-a-chip Devices in Pharmaceutical Sciences and Biomedicine.- CMOS Electronic Microarrays in Diagnostics and Nanotechnology.- CMOS Electrical Sensors.- Integrated Microelectrode Arrays.- CMOS ICs for Brain Implantable Neural Recording Microsystems.- CMOS Optical Sensors.- Optofluidic Microscope ¿ Fitting a Microscope onto a Sensor Chip.- CMOS Sensors for Optical Molecular Imaging.
Klappentext
Lately, there has been a growing interest in exploiting the benefits of the ICs for areas outside of the traditional application spaces. One noteable area is found in biology Bioanalytical instruments have been miniaturized on ICs to study various biophenomena or to actuate biosystems. These biolab-on-IC systems utilize the IC to facilitate faster, repeatable, and standardized biological experiments at low cost with a small volume of biological sample. The research activities in this field are expected to enjoy substantial growth in the foreseeable future. BioCMOS Technologies reviews these exciting recent efforts in joining CMOS technology with biology.
