Portable and Wearable Sensing Systems
Techniques, Fabrication, and Biochemical Detection
1. Auflage April 2024
256 Seiten, Hardcover
150 Abbildungen (50 Farbabbildungen)
Handbuch/Nachschlagewerk
ISBN:
978-3-527-35183-1
Wiley-VCH, Weinheim
Kurzbeschreibung
Systematically introduces the development, the concept, principles, technology and applications of portable and wearable devices for biochemical detection.
Weitere Versionen
1. PORTABLE AND WEARABLE SENSING TECHNOLOGIES FOR BIOCHEMICAL DETECTION
1.1 Biochemical Detection: Increasing Demands and Challenges
1.2 Portable Sensing Technologies: Efficient Biochemical Analysis
1.3 From Portable to Wearable: Towards in situ Biosensing
1.4 Summary and outlook
2 PORTABLE ELECTROCHEMICAL SENSING SYSTEMS
2.1 Fundamentals of portable electrochemical sensing systems
2.2 Techniques of portable electrochemical measurement
2.3 Fabrication of portable electrochemical systems
2.4 Applications of portable electrochemical sensing systems
2.5 Summary and outlook
3 PORTABLE OPTICAL SENSING SYSTEMS
3.1 Fundamentals of portable optical sensing systems
3.2 Plasmonic sensing-based portable optical systems
3.3 Scattering sensing-based portable optical systems
3.4 Chemiluminescence sensing-based portable optical systems
3.5 Colorimetric sensing-based portable optical systems
3.6 Summary and outlook
4 PORTABLE OPTICAL-ELECTROCHEMICAL COUPLED SENSING SYSTEMS
4.1 Fundamentals of Optical-Electrochemical Coupled Sensing Systems
4.2 Optical-Electrochemical Coupled Sensing Techniques
4.3 Fabrication of optical-electrochemical coupled electrodes
4.4 Construction of portable optical-electrochemical coupled systems
4.5 Summary and outlook
5 SMARTPHONE-BASED PORTABLE SENSING SYSTEMS FOR POINT-OF-CARE DETECTIONS
5.1 Smartphone-based optical sensing system
5.2 Smartphone-based electrochemical system
5.3 Smartphone-based photoelectrochemical (PEC) system
5.4 Smartphone-based point-of-care detections
5.5 Summary and outlook
6 FLEXIBLE ELECTRONICS FOR WEARABLE SENSING SYSTEMS
6.1 Flexible electronics: definition and development
6.2 Advantages of flexible electronics in wearable sensing
6.3 Fabricating wearable sensing systems with flexible electronic technologies
6.4 Wearable sensing systems fabricated by using flexible electronic technologies
6.5 Summary and Outlook
7 WEARABLE SENSORS FOR IN SITU BIOFLUIDS ANALYSIS
7.1 Wearable Sensors for Sweat Analysis
7.2 Wearable Sensors for Saliva Analysis
7.3 Wearable Sensors for Interstitial fluid (ISF) analysis
7.4 Wearable Sensors for Tear Analysis
7.5 Summary and Outlook
8 WEARABLE SENSORS FOR IN SITU BREATH ANALYSIS
8.1 Wearable Breath Sensors for Physiological Monitoring
8.2 Wearable Breath Sensors for Volatile Markers Analysis
8.3 Wearable Breath Sensors for Virus Detection
8.4 Summary and Outlook
9 WEARABLE SENSORS FOR WOUND DIAGNOSIS AND CLOSE-LOOP THERAPEUTICS
9.1 Wearable Sensors for Wound Monitoring
9.2 Wearable Drug Delivery for Wound Treatment
9.3 Integrating Wearable Sensors with Wearable Therapy
9.4 Close-Loop Therapeutics with Wearable Devices
9.5 Summary and outlook
10 SELF-POWERED SENSORS FOR WEARABLE DETECTIONS
10.1 Biofuel-based sensors
10.2 Thermoelectric Nanogenerator-based sensors
10.3 Triboelectric Nanogenerator-based sensors
10.4 Piezoelectric Nanogenerator-based sensors
10.5 Summary and outlook
1.1 Biochemical Detection: Increasing Demands and Challenges
1.2 Portable Sensing Technologies: Efficient Biochemical Analysis
1.3 From Portable to Wearable: Towards in situ Biosensing
1.4 Summary and outlook
2 PORTABLE ELECTROCHEMICAL SENSING SYSTEMS
2.1 Fundamentals of portable electrochemical sensing systems
2.2 Techniques of portable electrochemical measurement
2.3 Fabrication of portable electrochemical systems
2.4 Applications of portable electrochemical sensing systems
2.5 Summary and outlook
3 PORTABLE OPTICAL SENSING SYSTEMS
3.1 Fundamentals of portable optical sensing systems
3.2 Plasmonic sensing-based portable optical systems
3.3 Scattering sensing-based portable optical systems
3.4 Chemiluminescence sensing-based portable optical systems
3.5 Colorimetric sensing-based portable optical systems
3.6 Summary and outlook
4 PORTABLE OPTICAL-ELECTROCHEMICAL COUPLED SENSING SYSTEMS
4.1 Fundamentals of Optical-Electrochemical Coupled Sensing Systems
4.2 Optical-Electrochemical Coupled Sensing Techniques
4.3 Fabrication of optical-electrochemical coupled electrodes
4.4 Construction of portable optical-electrochemical coupled systems
4.5 Summary and outlook
5 SMARTPHONE-BASED PORTABLE SENSING SYSTEMS FOR POINT-OF-CARE DETECTIONS
5.1 Smartphone-based optical sensing system
5.2 Smartphone-based electrochemical system
5.3 Smartphone-based photoelectrochemical (PEC) system
5.4 Smartphone-based point-of-care detections
5.5 Summary and outlook
6 FLEXIBLE ELECTRONICS FOR WEARABLE SENSING SYSTEMS
6.1 Flexible electronics: definition and development
6.2 Advantages of flexible electronics in wearable sensing
6.3 Fabricating wearable sensing systems with flexible electronic technologies
6.4 Wearable sensing systems fabricated by using flexible electronic technologies
6.5 Summary and Outlook
7 WEARABLE SENSORS FOR IN SITU BIOFLUIDS ANALYSIS
7.1 Wearable Sensors for Sweat Analysis
7.2 Wearable Sensors for Saliva Analysis
7.3 Wearable Sensors for Interstitial fluid (ISF) analysis
7.4 Wearable Sensors for Tear Analysis
7.5 Summary and Outlook
8 WEARABLE SENSORS FOR IN SITU BREATH ANALYSIS
8.1 Wearable Breath Sensors for Physiological Monitoring
8.2 Wearable Breath Sensors for Volatile Markers Analysis
8.3 Wearable Breath Sensors for Virus Detection
8.4 Summary and Outlook
9 WEARABLE SENSORS FOR WOUND DIAGNOSIS AND CLOSE-LOOP THERAPEUTICS
9.1 Wearable Sensors for Wound Monitoring
9.2 Wearable Drug Delivery for Wound Treatment
9.3 Integrating Wearable Sensors with Wearable Therapy
9.4 Close-Loop Therapeutics with Wearable Devices
9.5 Summary and outlook
10 SELF-POWERED SENSORS FOR WEARABLE DETECTIONS
10.1 Biofuel-based sensors
10.2 Thermoelectric Nanogenerator-based sensors
10.3 Triboelectric Nanogenerator-based sensors
10.4 Piezoelectric Nanogenerator-based sensors
10.5 Summary and outlook
Qingjun Liu is currently Professor in Biosensor National Special Laboratory, Director of Biomedical Engineering Institute of Zhejiang University, China. He was also a visiting scholar in Biomedical Engineering at the Hong Kong Polytechnic University and the Micro and Nanotechnology Laboratory at the University of Illinois at Urbana-Champaign. He is also a member of the Youth Committee of the China Biomedical Engineering Society and a director of the China Micron Nanotechnology Society. His interests mainly focus on biomedical sensing and detection research.
