Chemical, gas, and biosensors for internet of things and related applications / edited by Kohji Mitsubayashi, Osamu Niwa, Uko Ueno.

Format:

Book

Contributor:

Mitsubayashi, Kohji, editor.

Niwa, Osamu, editor.

Ueno, Uko, editor.

Language:

English

Subjects (All):

Internet of things.

Physical Description:

1 online resource (408 pages)

Place of Publication:

Amsterdam, Netherlands : Elsevier, [2019]

Summary:

"Chemical, Gas, and Biosensors for the Internet of Things and Related Applications brings together the fields of sensors and analytical chemistry, devices and machines, and network and information technology. This thorough resource enables researchers to effectively collaborate to advance this rapidly expanding, interdisciplinary area of study. As innovative developments in the Internet of Things (IoT) continue to open new possibilities for quality of life improvement, sensor technology must keep pace, Drs. Mitsubayashi, Niwa and Ueno have brought together the top minds in their respective fields to provide the latest information on the numerous uses of this technology. Topics covered include life-assist systems, network monitoring with portable environmental sensors, wireless livestock health monitoring, point-of-care health monitoring, organic electronics and bio-batteries, and more"-- Provided by publisher.

Contents:

Front Cover

Chemical, Gas, and Biosensors for Internet of Things and Related Applications

Copyright Page

Contents

List of Contributors

Preface

I. Sensors and Devices for Internet of Things Applications

1 Portable urine glucose sensor

1.1 Introduction

1.2 Significance of urine glucose measurement

1.3 Operating principle of urine glucose sensor and laminated structure

1.3.1 Principle of operation

1.3.2 Laminated structure of urine glucose sensor

1.4 Development of portable urine glucose meter

1.4.1 Composition of urine glucose meter

1.4.2 Performance evaluation of urine glucose meter

1.5 Clinical application of urine glucose meter

1.5.1 Relationship between the amount of boiled rice and urine glucose concentration in impaired glucose tolerance

1.5.2 Results of urine glucose monitoring on impaired glucose tolerance case

1.5.3 Results of a case of self-monitoring of urine glucose in diabetes

1.6 Conclusions

References

2 Design, application, and integration of paper-based sensors with the Internet of Things

2.1 Introduction

2.2 Bioapplications of paper-based analytical devices

2.3 Environmental analysis of paper-based analytical devices

2.4 Integration with smartphone devices

2.5 Conclusion

Author disclosure statement

3 Membrane-type Surface stress Sensor (MSS) for artificial olfactory system

3.1 Introduction

3.2 Membrane-type Surface stress Sensor (MSS)

3.3 Receptor materials

3.4 Machine learning

3.5 Applications

3.6 Internet of Things and MSS Alliance/Forum

3.7 Conclusion

4 Sensing technology based on olfactory receptors

4.1 Olfactory mechanisms in biological systems

4.1.1 Olfactory mechanisms in vertebrates

4.1.1.1 Anatomy of olfactory organs in mammals.

4.1.1.2 Odorant detection and signal transduction

4.1.1.3 Odorant receptors and odor coding in mammals

4.1.2 Olfactory mechanisms in insects

4.1.2.1 Anatomy of olfactory organs in insects

4.1.2.2 Odorant detection by olfactory sensilla

4.1.2.3 Odorant receptors and signal transduction

4.1.2.4 Odor coding by olfactory receptor neurons

4.2 Biosensing technologies based on odorant receptors

4.2.1 Mammalian odorant receptors

4.2.1.1 Cell-based expression systems

4.2.1.1.1 Bacterial cells

4.2.1.1.2 Yeast cells

4.2.1.1.3 Mammalian cultured cells

4.2.1.2 Other (noncell-based expression system) applications

4.2.2 Insect odorant receptors

4.2.2.1 Cell-based expression systems

4.2.2.2 Other (noncell expression system) applications

4.3 Summary

5 Advanced surface modification technologies for biosensors

5.1 Biosensors and biointerfaces

5.2 Binding platforms based on self-assembled monolayers

5.2.1 Organosulfur derivatives

5.2.2 Organosilicon derivatives

5.2.3 Catechol derivatives

5.3 Binding matrix based on polymeric hydrogels

5.3.1 Physicochemical sensing mechanisms

5.3.2 Biochemical sensing mechanisms

5.4 Coupling chemistries for immobilization of biorecognition elements

5.4.1 Physical immobilization

5.4.2 Amine chemistry

5.4.3 Thiol chemistry

5.4.4 Carboxyl chemistry

5.4.5 Epoxy chemistry

5.4.6 Click chemistry

5.4.7 α-Oxo semicarbazone chemistry

5.4.8 Bioaffinity conjugation

5.5 Antifouling materials

5.5.1 Poly(ethylene glycol) antifouling materials

5.5.2 Zwitterionic antifouling materials

5.6 Outlook

6 Development of portable immunoassay device for future Internet of Things applications

6.1 Introduction

6.2 Portable immunoassay system based on surface plasmon resonance for urinary immunoassay.

6.3 One-chip immunosensing fabricated with nanoimprinting technique

6.3.1 Fabrication of local plasmon resonance devices with various processes

6.3.2 Surface plasmon resonance biosensors fabricated by nanoimprint technique

6.4 Microfluidic biosensor with one-step optical detection

6.4.1 Mechanism of graphene aptasensor

6.4.2 Multichannel linear array for multiple protein detection

6.4.3 Molecular design for enhanced sensitivity

6.5 Future trend

7 Sensitive and reusable surface acoustic wave immunosensor for monitoring of airborne mite allergens

7.1 Introduction

7.2 Surface acoustic wave immunosensor for repeated measurement of house dust mite allergens

7.3 Sensor characteristics and semicontinuous measurement of Der f 1

7.4 Sensitivity improvement via gold nanoparticles

7.5 Conclusion

8 Aptameric sensors utilizing its property as DNA

8.1 Introduction

8.2 Aptamer-immobilized electrochemical sensor

8.3 Detection using complementary chain formation

8.3.1 Strand displacement assay

8.3.2 Bound/Free separation using complementary chain formation

8.4 Aptamer sensor combined with enzymes

8.5 Utilizing structural change of aptamers to biosensor

8.6 Utilizing structural change of aptamers to biosensor

8.7 Development of highly sensitive sensors by amplifying DNA strands

8.8 Colorimetric detection using aptameric sensor and smart devices

8.9 Conclusion

9 Electrochemical sensing techniques using carbon electrodes prepared by electrolysis toward environmental Internet of Thin...

9.1 Introduction

9.1.1 Electrochemical monitoring support Internet of Things services

9.1.2 Carbon electrode surface activation

9.2 Chemical sensors using electrochemical activated carbon electrodes.

9.2.1 Electrochemical activated techniques for aminated electrode preparation

9.2.2 Electrochemical activated techniques for electrodeposited platinum particles on glassy carbon electrode modified with...

9.3 Electrocatalytic activity and analytical performance

9.4 Conclusion and future perspectives

Acknowledgments

10 Chemical sensors for environmental pollutant determination

10.1 Introduction

10.2 Definition of a chemical sensor

10.3 Classification of chemical sensors

10.3.1 Electrochemical sensors

10.3.1.1 Voltammetric sensors

10.3.1.2 Amperometric sensors

10.3.1.3 Electrochemical impedance spectroscopy sensors

10.3.1.4 Potentiometric sensors

10.3.2 Optical sensors

10.3.2.1 Fluorescence sensors

10.3.2.2 Surface plasmon resonance sensors

10.3.2.3 Infrared and Raman spectroscopy-based sensors

10.3.2.4 Colorimetric sensors

10.4 Conclusion

II. Flexible, Wearable, and Mobile Sensors and Related Technologies

11 Smart clothing with wearable bioelectrodes "hitoe"

11.1 Introduction

11.2 Functional material "hitoe"

11.2.1 Composite material of a conductive polymer and fibers

11.2.2 The development of hitoe smart clothing

11.3 Application examples

11.3.1 Medicine/rehabilitation

11.3.2 Sports

11.3.2.1 Heart rate measurement

11.3.2.2 Surface electromyography measurements

11.3.3 Worker health/safety management

11.4 State estimation based on heart rate variability and other data

11.4.1 Estimating posture information from accelerometer data

11.4.2 Estimating respiratory activity from electrocardiogram data

11.4.3 Estimating sleep states

11.5 Conclusion

12 Cavitas bio/chemical sensors for Internet of Things in healthcare

12.1 Introduction

12.2 Soft contact lens type bio/chemical sensors.

12.2.1 Tear fluid in conjunctiva sac

12.2.2 Flexible conductivity sensor for tear flow function

12.2.3 Soft contact lens type biosensors using biocompatible polymers

12.2.4 Transcutaneous gas sensor at eyelid conjunctiva

12.3 Mouthguard type biosensor for saliva biomonitoring

12.3.1 Salivary fluids in oral cavity

12.3.2 Wireless mouthguard sensor for salivary glucose

12.4 Conclusion

13 Point of care testing apparatus for immunosensing

13.1 Introduction

13.2 Immunochromatography assay

13.3 Immunochromatography assay for infectious diseases

13.4 Reliability of the examination kits

13.5 Signal amplification

13.6 Quantitative ICA by electrochemical detection systems

13.7 Rapid and Quantitative ICA based on dielectrophoresis

13.8 Conclusion

14 IoT sensors for smart livestock management

14.1 Introduction

14.2 Measurement site and fixing method

14.3 Size and weight

14.4 Power consumption

14.5 Frequency bands of radio wave

14.6 Applications of wearable biosensors for livestock

14.6.1 Chickens

14.6.2 Cattle

14.6.2.1 Automated milking system

14.6.2.2 Importance of wearable sensors

14.6.2.3 Pedometers

14.6.2.4 Ruminal sensors

14.6.2.5 Vaginal sensors

14.6.2.6 Implantable sensors

14.6.2.7 Wireless thermometers attached to skin surface

14.7 Conclusion

15 Compact disc-type biosensor devices and their applications

15.1 Introduction

15.2 CD-shaped microfluidic devices for cell isolation and single cell PCR

15.2.1 Single cell isolation

15.2.2 Single cell PCR of S. enterica

15.2.3 Discrimination of microbes

15.2.4 Single cell RT-PCR for Jurkat cells

15.3 CD-shaped microfluidic device for cell staining

15.4 CD-shaped microfluidic device for ELISA.

15.4.1 Detection of bioactive chemicals based on ELISA.

Notes:

Prose Award. Chemistry & Physics, 2020.

Description based on: online resource; title from pdf title page (Knovel, viewed June 1, 2020)

ISBN:

9780128154106

0128154101