000 -LEADER |
fixed length control field |
10442nam a22005173i 4500 |
001 - CONTROL NUMBER |
control field |
EBC5567655 |
003 - CONTROL NUMBER IDENTIFIER |
control field |
MiAaPQ |
005 - DATE AND TIME OF LATEST TRANSACTION |
control field |
20210105162942.0 |
007 - PHYSICAL DESCRIPTION FIXED FIELD--GENERAL INFORMATION |
fixed length control field |
cr cnu|||||||| |
008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION |
fixed length control field |
201228s2018 xx o ||||0 eng d |
020 ## - INTERNATIONAL STANDARD BOOK NUMBER |
International Standard Book Number |
9780128156391 |
Qualifying information |
(electronic bk.) |
|
Cancelled/invalid ISBN |
9780128153949 |
035 ## - SYSTEM CONTROL NUMBER |
System control number |
(MiAaPQ)EBC5567655 |
|
System control number |
(Au-PeEL)EBL5567655 |
|
System control number |
(OCoLC)1061130178 |
040 ## - CATALOGING SOURCE |
Original cataloging agency |
MiAaPQ |
Language of cataloging |
eng |
Description conventions |
rda |
-- |
pn |
Transcribing agency |
MiAaPQ |
Modifying agency |
MiAaPQ |
050 #4 - LIBRARY OF CONGRESS CALL NUMBER |
Classification number |
R857.E52 .G737 2019 |
082 0# - DEWEY DECIMAL CLASSIFICATION NUMBER |
Classification number |
681.2 |
100 1# - MAIN ENTRY--PERSONAL NAME |
Personal name |
Pandikumar, Alagarsamy. |
245 10 - TITLE STATEMENT |
Title |
Graphene-Based Electrochemical Sensors for Biomolecules. |
264 #1 - |
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San Diego : |
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Elsevier, |
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2018. |
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�2019. |
300 ## - PHYSICAL DESCRIPTION |
Extent |
1 online resource (366 pages) |
336 ## - |
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text |
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txt |
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rdacontent |
337 ## - |
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computer |
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c |
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rdamedia |
338 ## - |
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online resource |
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cr |
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rdacarrier |
490 1# - SERIES STATEMENT |
Series statement |
Micro and Nano Technologies Ser. |
505 0# - FORMATTED CONTENTS NOTE |
Formatted contents note |
Front Cover -- Graphene-Based Electrochemical Sensors for Biomolecules -- Copyright -- Contents -- Contributors -- Preface -- Acknowledgments -- Chapter 1: Graphene-Modified Electrochemical Sensors -- 1. Introduction -- 2. Electrochemical Sensors -- 3. Importance of Biomolecules -- 4. Graphene -- 4.1. Structure and Properties of Graphene -- 4.2. Synthesis of Graphene -- 4.2.1. Top-Down Methods -- 4.2.2. Bottom-Up Approach -- 5. Electrode Fabrications With Graphene -- 6. Electrochemical Determination of Neurotransmitters, Vitamins, and Amino Acids -- 7. Electrochemical Determination of Purine Derivatives -- 7.1. Electrochemical Determination of UA, XN, and HXN -- 7.2. Electrochemical Determination of DNA Purine Bases (A and G) -- 7.3. Electrochemical Determination of Purine Nucleotides and Nucleosides -- 7.4. Electrochemical Determination of CAF, TP, and AP -- 8. Conclusion and Future Prospects -- References -- Chapter 2: Functionalized Graphene Nanocomposites for Electrochemical Sensors -- 1. Introduction -- 1.1. Functionalized Graphene Nanocomposites -- 1.2. Electrochemical Detection of Biomolecules Using Functionalized Graphene Nanocomposites -- 2. Detection of Nitric Oxide -- 3. Detection of Glucose -- 4. Sensing of Cholesterol -- 5. Detection of Important Neurotransmitters -- 6. Concluding Remarks and Future Prospects -- References -- Chapter 3: Doped-Graphene Modified Electrochemical Sensors -- 1. Introduction -- 2. Heteroatom-Doped Graphene -- 2.1. Element Boron -- 2.2. Element Nitrogen -- 2.3. Element Phosphorus -- 2.4. Element Sulfur -- 3. Heteroatoms Doped Graphene for Electrochemical Sensor Applications -- 3.1. Electrochemical Detection of Hydrogen Peroxide -- 3.2. Electrochemical Detection of Dopamine -- 3.3. Electrochemical Detection of NADH -- 3.4. Electrochemical Detection of Glucose. |
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Formatted contents note |
3.5. Electrochemical Detection of Ascorbic Acid -- 4. Conclusion and Future Outlooks -- References -- Chapter 4: Graphene-Metal Modified Electrochemical Sensors -- 1. Introduction -- 2. Synthesis of Graphene-Metal NP Hybrids -- 2.1. Direct Mixing Method -- 2.2. Electrodeposition Method -- 2.3. Photochemical Method -- 2.4. Substrate Enhance Electroless Deposition Method -- 2.5. Chemical Reduction Method -- 2.6. Microwave Assisted Synthesis Method -- 2.7. Electrolytic Deposition Method for Synthesis of Graphene-Metal NP Hybrids -- 3. Sensing Application of Graphene-Metal NP Hybrids -- 3.1. Dopamine/Uric Acid/Ascorbic Acid Sensor -- 3.2. Glucose Sensor -- 3.3. Hydrogen Peroxide Sensor -- 3.4. Immunological Sensor -- 3.5. Epinephrine and Norepinephrine Sensor -- 3.6. Levofloxacin Sensor -- 3.7. Ethanol Sensor -- 4. Conclusion -- References -- Further Reading -- Chapter 5: Graphene-Metal Oxide Nanocomposite Modified Electrochemical Sensors -- 1. Introduction -- 2. Electrochemical Detection of Biomolecules -- 2.1. Dopamine -- 2.2. Glucose -- 2.3. NADH and Cholesterol Sensing -- 2.3.1. Nicotinamide Adenine Dinucleotide Hydrogen -- 2.3.2. Cholesterol Detection -- 3. Conclusion and Future Perspectives -- References -- Chapter 6: Graphene-Metal Chalcogenide Modified Electrochemical Sensors -- 1. Introduction -- 2. Electrochemical Sensing of Biomolecules Using Graphene-Metal Chalcogenide Composites -- 3. Electrochemical Sensing of Biomolecules Based on Enzymatic and Nonenzymatic Approaches Using Graphene-Metal Chalcogeni ... -- 4. Conclusion and Future Prospects -- References -- Chapter 7: Graphene-Polymer Modified Electrochemical Sensors -- 1. Introduction -- 2. Polymers -- 2.1. Synthetic Polymers -- 2.1.1. Polypyrrole -- 2.1.2. Polyaniline -- 2.1.3. Poly(3,4-ethylenedioxythiophene) -- 2.1.4. Nafion -- 2.2. Natural Polymers -- 2.2.1. Chitosan. |
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Formatted contents note |
2.2.2. Cellulose -- 3. Graphene-Conductive Polymer Hybrid Materials for Development of Electrochemical Sensors -- 3.1. Graphene-Polypyrrole Hybrid Electrochemical Determination of Bioanalytes -- 3.2. Graphene-Polyaniline Hybrid Electrochemical Determination of Bioanalytes -- 3.3. Graphene-Poly(3,4-ethylenedioxythiophene) Hybrid Electrochemical Determination of Bioanalytes -- 3.4. Graphene-Nafion Hybrid Electrochemical Determination of Bioanalytes -- 4. Graphene-Biopolymer Hybrid Materials for Development of Electrochemical Sensors -- 4.1. Graphene-Chitosan Hybrid Electrochemical Determination of Bioanalytes -- 4.2. Graphene-Cellulose Hybrid Electrochemical Determination of Bioanalytes -- 5. Conclusion and Future Prospects -- References -- Chapter 8: Graphene-Carbon Nanotubes Modified Electrochemical Sensors -- 1. Introduction -- 2. Use of Nanomaterials in Sensors -- 3. Introduction to Graphene-Carbon Nanotube Composite Materials and Their Advantages -- 4. Electrochemical Sensor Application Fields of Graphene-Carbon Nanotube Composites -- 4.1. Biomolecule Sensors -- 4.2. Pharmaceutical Sensors -- 4.3. Food Sensors -- 5. Conclusions and Perspectives -- Acknowledgments -- References -- Chapter 9: Graphene-Carbon Nitride-Based Electrochemical Sensors for Biomolecules -- 1. Introduction -- 2. Synthesis of Materials -- 2.1. Preparation of Carbon Nitride Nanomaterials -- 2.2. Preparation of Graphene-Carbon Nitride-Based Nanocomposite Materials and Electrode Modification -- 3. Characterization of Materials -- 3.1. Brunauer-Emmett-Teller Surface Area and X-Ray Diffraction -- 3.2. UV-Visible and Fluorescence Spectroscopy -- 3.3. Fourier Transform Infrared Spectroscopy -- 3.4. Raman Spectroscopy -- 3.5. X-Ray Photoelectron Spectroscopy -- 3.6. Transmission Electron Microscopy -- 4. Electrochemical Behavior and Sensing Applications. |
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Formatted contents note |
5. Conclusions and Future Prospects -- References -- Chapter 10: Graphene-Clay-Based Hybrid Nanostructures for Electrochemical Sensors and Biosensors -- 1. Introduction -- 1.1. Electrochemical Sensors -- 1.2. Advantages of Electrochemical Sensors -- 1.3. Types of Carbon Nanomaterials -- 1.3.1. Carbon Nanotubes -- 1.3.2. Fullerene -- 1.3.3. Graphene -- 1.3.4. Reduced Graphene Oxide -- 1.3.5. Graphene Nanoribbons -- 1.4. Types of Clay Minerals -- 1.4.1. Layered Double Hydroxides -- 1.4.2. Montmorillonite -- 1.4.3. Sepiolite -- 1.4.4. Zeolites -- 1.5. Graphenes in Sensors -- 1.5.1. Graphene and Carbon Nanotubes Nanohybrid Sensors -- 1.5.2. Graphene and Metal Oxide Nanohybrid Sensors -- 1.5.3. Electrochemistry of Graphene -- 1.5.4. Electrochemistry of Clay Particles -- 1.5.5. Importance of Graphene and Clay Nanohybrid Electrodes for Sensor Applications -- 2. Graphene-Clay Nanohybrid Based Electrochemical Sensors -- 2.1. Types of Clay-Graphene Nanohybrid Synthesis -- 2.2. Graphene-Clay Hybrid-Based Electrochemical Sensors -- 2.3. Graphene-Clay Hybrid-Based Gas Sensors -- 2.4. Graphene-Clay Hybrid-Based Biological Sensors (Glucose/H2O2) -- 2.5. Other Graphene-Clay Hybrid-Based Biosensors -- 3. Conclusion and Future Trends -- References -- Further Reading -- Chapter 11: Graphene-Metal-Organic Framework-Modified Electrochemical Sensors -- 1. Introduction -- 2. Mechanism of Charge Transfer in Graphene-MOFs -- 3. Fabrication of Graphene-MOF -- 3.1. Electrophoretic Deposition -- 3.2. Hybrid Hydrothermal Synthesis -- 3.3. Sonochemical Synthesis -- 3.4. In Situ Crystallization Method -- 4. Graphene-MOFs as Electrochemical Sensors in Sensing Biomolecules -- 4.1. Graphene-MOF-Based Glucose Sensors -- 4.2. Graphene-MOF-Based Immunosensors -- 4.3. Graphene-MOF-Based Dopamine Biosensors -- 4.4. Other Graphene-MOF-Based Biomolecular Sensors. |
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Formatted contents note |
5. Conclusion and Future Perspectives -- References -- Chapter 12: Graphene Paper-Based Electrochemical Sensors for Biomolecules -- 1. Introduction -- 2. Fabrication of Graphene Paper Electrodes -- 2.1. Wet Chemical Process -- 2.2. Dry Chemical Process -- 2.3. Electrophoretic and Electrospray Deposition Process -- 2.4. Other Methods -- 3. Activation Strategies of Graphene Papers -- 3.1. Posttreatment Process -- 3.2. Metal Anchoring -- 3.3. Metal Oxide Modifications -- 3.4. Polymer Functionalization -- 3.5. Biomolecule Immobilization -- 3.6. Elemental Doping -- 4. Applications of Graphene Paper as Electrochemical Sensors for Biomolecules -- 4.1. Sensing of Glucose and Hydrogen Peroxide -- 4.2. Sensing of Microbes -- 4.3. Other Uses -- 5. Concluding Remarks and Future Perspectives -- Acknowledgments -- References -- Chapter 13: Graphene-Containing Microfluidic and Chip-Based Sensor Devices for Biomolecules -- 1. Introduction -- 2. Graphene and Derivatives -- 3. General Characteristics of Graphene -- 4. Microfluidic Integrated Biosensors and Sensors for Detection of Biomolecules -- 5. Conclusion and Future Prospects -- Acknowledgments -- References -- Index -- Back Cover. |
588 ## - |
-- |
Description based on publisher supplied metadata and other sources. |
590 ## - LOCAL NOTE (RLIN) |
Local note |
Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2020. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries. |
650 #0 - SUBJECT ADDED ENTRY--TOPICAL TERM |
Topical term or geographic name as entry element |
Electrochemical sensors.. |
|
Topical term or geographic name as entry element |
Graphene.. |
|
Topical term or geographic name as entry element |
Nanocomposites (Materials). |
655 #4 - INDEX TERM--GENRE/FORM |
Genre/form data or focus term |
Electronic books. |
700 1# - ADDED ENTRY--PERSONAL NAME |
Personal name |
Rameshkumar, Perumal. |
776 08 - ADDITIONAL PHYSICAL FORM ENTRY |
Display text |
Print version: |
Main entry heading |
Pandikumar, Alagarsamy |
Title |
Graphene-Based Electrochemical Sensors for Biomolecules |
Place, publisher, and date of publication |
San Diego : Elsevier,c2018 |
International Standard Book Number |
9780128153949 |
797 2# - LOCAL ADDED ENTRY--CORPORATE NAME (RLIN) |
Corporate name or jurisdiction name as entry element |
ProQuest (Firm) |
830 #0 - SERIES ADDED ENTRY--UNIFORM TITLE |
Uniform title |
Micro and Nano Technologies Ser. |
856 40 - ELECTRONIC LOCATION AND ACCESS |
Uniform Resource Identifier |
https://ebookcentral.proquest.com/lib/kliuc-ebooks/detail.action?docID=5567655 |
Public note |
Click to View |
942 ## - ADDED ENTRY ELEMENTS (KOHA) |
Source of classification or shelving scheme |
|
Koha item type |
E-book |