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Laboratory Methods in Dynamic Electroanalysis 1st edition by Teresa Fernández Abedul ISBN 0128159330 9780128159330

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ISBN 10: 0128159330
ISBN 13: 9780128159330
Author:  Teresa Fernández Abedul

Laboratory Methods in Dynamic Electroanalysis is a useful guide to introduce analytical chemists and scientists of related disciplines to the world of dynamic electroanalysis using simple and low-cost methods. The trend toward decentralization of analysis has made this fascinating field one of the fastest-growing branches of analytical chemistry. As electroanalytical devices have moved from conventional electrochemical cells (10-20 mL) to current cells (e.g. 5-50 mL) based on different materials such as paper or polymers that integrate thick- or thin-film electrodes, interesting strategies have emerged, such as the combination of microfluidic cells and biosensing or nanostructuration of electrodes.

This book provides detailed, easy procedures for dynamic electroanalysis and covers the main trends in electrochemical cells and electrodes, including microfluidic electrodes, electrochemical detection in microchip electrophoresis, nanostructuration of electrodes, development of bio (enzymatic, immuno, and DNA) assays, paper-based electrodes, interdigitated array electrodes, multiplexed analysis, and combination with optics. Different strategies and techniques (amperometric, voltammetric, and impedimetric) are presented in a didactic, practice-based way, and a bibliography provides readers with additional sources of information.

  • Provides easy-to-implement experiments using low-cost, simple equipment
  • Includes laboratory methodologies that utilize both conventional designs and the latest trends in dynamic electroanalysis
  • Goes beyond the fundamentals covered in other books, focusing instead on practical applications of electroanalysis

Laboratory Methods in Dynamic Electroanalysis 1st Table of contents:

Chapter 1. Dynamic electroanalysis: an overview

1.1. Dynamic electroanalysis

1.2. Additional notes

I. Dynamic electroanalytical techniques

Chapter 2. Determination of ascorbic acid in dietary supplements by cyclic voltammetry

2.1. Background

2.2. Electrochemical cell

2.3. Chemicals and supplies

2.4. Hazards

2.5. Experimental procedure

2.6. Lab report

2.7. Additional notes

2.8. Assessment and discussion questions

Chapter 3. Electrochemical behavior of the redox probe hexaammineruthenium(III) ([Ru(NH3)6]3+) using voltammetric techniques

3.1. Background

3.2. Electrochemical cell

3.3. Chemicals and supplies

3.4. Hazards

3.5. Experimental procedure

3.6. Lab report

3.7. Additional notes

3.8. Assessment and discussion questions

Chapter 4. Anodic stripping voltammetric determination of lead and cadmium with stencil-printed transparency electrodes

4.1. Background

4.2. Electrochemical cell design

4.3. Chemicals and supplies

4.4. Hazards

4.5. Experimental procedure

4.6. Lab report

4.7. Additional notes

4.8. Assessment and discussion questions

Chapter 5. Adsorptive stripping voltammetry of indigo blue in a flow system

5.1. Background

5.2. Chemicals and supplies

5.3. Hazards

5.4. Flow injection analysis electrochemical system

5.5. Experimental procedures

5.6. Lab report

5.7. Additional notes

5.8. Assessment and discussion questions

Chapter 6. Enhancing electrochemical performance by using redox cycling with interdigitated electrodes

6.1. Background

6.2. Chemicals and supplies

6.3. Hazards

6.4. Electrochemical system setup

6.5. Experimental procedure

6.6. Lab report

6.7. Additional notes

6.8. Assessment and discussion questions

Chapter 7. Amperometric detection of NADH using carbon-based electrodes

7.1. Background

7.2. Chemicals and supplies

7.3. Hazards

7.4. Experimental procedure

7.5. Lab report

7.6. Additional notes

7.7. Assessment and discussion questions

Chapter 8. Chronoamperometric determination of ascorbic acid on paper-based devices

8.1. Background

8.2. Electrochemical cell design

8.3. Chemicals and supplies

8.4. Hazards

8.5. Experimental procedure

8.6. Lab report

8.7. Additional notes

8.8. Assessment and discussion questions

Chapter 9. Electrochemical detection of melatonin in a flow injection analysis system

9.1. Background

9.2. Electrochemical thin-layer cell

9.3. Flow injection analysis system

9.4. Chemicals and supplies

9.5. Hazards

9.6. Experimental procedure

9.7. Lab report

9.8. Additional notes

9.9. Assessment and discussion questions

Chapter 10. Batch injection analysis for amperometric determination of ascorbic acid at ruthenium dioxide screen-printed electrodes

10.1. Background

10.2. Chemicals and supplies

10.3. Hazards

10.4. Experimental procedure

10.5. Lab report

10.6. Additional notes

10.7. Assessment and discussion questions

Chapter 11. Impedimetric aptasensor for determination of the antibiotic neomycin B

11.1. Background

11.2. Chemicals and supplies

11.3. Hazards

11.4. Experimental procedure

11.5. Lab report

11.6. Additional notes

11.7. Assessment and discussion questions

Chapter 12. Electrochemical impedance spectroscopy for characterization of electrode surfaces: carbon nanotubes on gold electrodes

12.1. Background

12.2. Electrochemical cell

12.3. Chemicals and supplies

12.4. Hazards

12.5. Electrochemical procedure

12.6. Lab report

12.7. Additional notes

12.8. Assessment and discussion questions

II. Electroanalysis and microfluidics

Chapter 13. Single- and dual-channel hybrid PDMS/glass microchip electrophoresis device with amperometric detection

13.1. Background

13.2. Chemicals and supplies

13.3. Microchip fabrication

13.4. Microchip designs

13.5. Electrochemical detector design

13.6. Hazards

13.7. Experimental procedure

13.8. Lab report

13.9. Additional notes

13.10. Assessment and discussion questions

Chapter 14. Analysis of uric acid and related compounds in urine samples by electrophoresis in microfluidic chips

14.1. Background

14.2. Electrophoresis system setup

14.3. Chemicals and supplies

14.4. Hazards

14.5. Experimental procedure

14.6. Lab report

14.7. Additional notes

14.8. Assessment and discussion questions

Chapter 15. Microchannel modifications in microchip reverse electrophoresis for ferrocene carboxylic acid determination

15.1. Background

15.2. Electrophoresis microchip

15.3. Chemicals and supplies

15.4. Hazards

15.5. Experimental procedure

15.6. Lab report

15.7. Additional notes

15.8. Assessment and discussion questions

Chapter 16. Integrated microfluidic electrochemical sensors to enhance automated flow analysis systems

16.1. Background

16.2. Flow injection analysis system setup

16.3. Chemicals and supplies

16.4. Hazards

16.5. Experimental procedure

16.6. Lab report

16.7. Additional notes

16.8. Assessment and discussion questions

III. Bioelectroanalysis

Chapter 17. Bienzymatic amperometric glucose biosensor

17.1. Background

17.2. Electrochemical setup

17.3. Chemicals and supplies

17.4. Hazards

17.5. Experimental procedure

17.6. Lab report

17.7. Additional notes

17.8. Assessment and discussion questions

Chapter 18. Determination of ethyl alcohol in beverages using an electrochemical enzymatic sensor

18.1. Background

18.2. Electrochemical setup

18.3. Chemicals and supplies

18.4. Hazards

18.5. Experimental procedure

18.6. Lab report

18.7. Additional notes

18.8. Assessment and discussion questions

Chapter 19. Enzymatic determination of ethanol on screen-printed cobalt phthalocyanine/carbon electrodes

19.1. Background

19.2. Electrochemical cell

19.3. Chemical and supplies

19.4. Hazards

19.5. Experimental procedure

19.6. Lab report

19.7. Additional notes

19.8. Assessment and discussion questions

Chapter 20. Immunoelectroanalytical assay based on the electrocatalytic effect of gold labels on silver electrodeposition

20.1. Background

20.2. Electrochemical cells

20.3. Chemicals and supplies

20.4. Hazards

20.5. Experimental procedures

20.6. Lab report

20.7. Additional notes

20.8. Assessment and discussion questions

Chapter 21. Genosensor on gold films with enzymatic electrochemical detection of a SARS virus sequence

21.1. Background

21.2. Electrochemical cell

21.3. Chemicals and supplies

21.4. Hazards

21.5. Experimental procedures

21.6. Lab report

21.7. Additional notes

21.8. Assessment and discussion questions

Chapter 22. Aptamer-based magnetoassay for gluten determination

22.1. Background

22.2. Chemical and supplies

22.3. Hazards

22.4. Experimental procedure

22.5. Lab report

22.6. Additional notes

22.7. Assessment and discussion questions

IV. Nanomaterials and electroanalysis

Chapter 23. Determination of lead with electrodes nanostructured with gold nanoparticles

23.1. Background

23.2. Electrochemical cell

23.3. Chemicals and supplies

23.4. Hazards

23.5. Experimental procedure

23.6. Lab report

23.7. Additional notes

23.8. Assessment and discussion questions

Chapter 24. Electrochemical behavior of the dye methylene blue on screen-printed gold electrodes modified with carbon nanotubes

24.1. Background

24.2. Screen-printed gold electrodes

24.3. Chemicals and supplies

24.4. Hazards

24.5. Experimental procedure

24.6. Lab report

24.7. Additional notes

24.8. Assessment and discussion questions

V. Low-cost electroanalysis

Chapter 25. Determination of glucose with an enzymatic paper-based sensor

25.1. Background

25.2. Electrochemical cell design

25.3. Chemical and supplies

25.4. Hazards

25.5. Experimental procedure

25.6. Lab report

25.7. Additional notes

25.8. Assessment and discussion questions

Chapter 26. Determination of arsenic (III) in wines with nanostructured paper-based electrodes

26.1. Background

26.2. Chemicals and supplies

26.3. Hazards

26.4. Experimental procedure

26.5. Lab report

26.6. Additional notes

26.7. Assessment and discussion questions

Chapter 27. Pin-based electrochemical sensor

27.1. Background

27.2. Electrochemical cell design

27.3. Chemicals and supplies

27.4. Hazards

27.5. Experimental procedure

27.6. Lab report

27.7. Additional notes

27.8. Assessment and discussion questions

Chapter 28. Flow injection electroanalysis with pins

28.1. Background

28.2. Flow injection analysis and electrochemical cell design

28.3. Chemical and supplies

28.4. Hazards

28.5. Experimental procedure

28.6. Lab report

28.7. Additional notes

28.8. Assessment and discussion questions

Chapter 29. Staple-based paper electrochemical platform for quantitative analysis

29.1. Background

29.2. Electrochemical setup

29.3. Chemicals and supplies

29.4. Hazards

29.5. Experimental procedure

29.6. Lab report

29.7. Additional notes

29.8. Assessment and discussion questions

VI. Multiplexed electroanalysis

Chapter 30. Simultaneous measurements with a multiplexed platform containing eight electrochemical cells

30.1. Background

30.2. Electrochemical platform

30.3. Chemical and supplies

30.4. Hazards

30.5. Experimental procedure

30.6. Lab report

30.7. Additional notes

30.8. Assessment and discussion questions

Chapter 31. Simultaneous detection of bacteria causing community-acquired pneumonia by genosensing

31.1. Background

31.2. Electrochemical cell design

31.3. Chemicals and supplies

31.4. Hazards

31.5. Experimental procedure

31.6. Lab report

31.7. Additional notes

31.8. Assessment and discussion questions

VII. Spectroelectrochemical techniques

Chapter 32. Electrochemiluminescence of tris (1,10-phenanthroline) ruthenium(II) complex with multipulsed amperometric detection

32.1. Background

32.2. Chemicals and supplies

32.3. Hazards

32.4. Experimental procedure

32.5. Lab report

32.6. Additional notes

32.7. Assessment and discussion questions

Chapter 33. Detection of hydrogen peroxide by flow injection analysis based on electrochemiluminescence resonance energy transfer donor–acceptor strategy

33.1. Background

33.2. Chemicals and supplies

33.3. Hazards

33.4. Experimental procedure

33.5. Lab report

33.6. Additional notes

33.7. Assessment and discussion questions

Chapter 34. Determination of tris(bipyridine)ruthenium(II) based on electrochemical surface-enhanced raman scattering

34.1. Background

34.3. Chemicals and supplies

34.4. Hazards

34.5. Experimental procedure

34.6. Lab report

34.7. Additional notes

34.8. Assessment and discussion questions

VIII. General considerations

Chapter 35. Design of experiments at electroanalysis. Application to the optimization of nanostructured electrodes for sensor development

35.1. Background

35.2. Electrochemical cell

35.3. Chemicals and supplies

35.4. Hazards

35.5. Experimental procedure

35.6. Lab report

35.7. Additional notes

35.8. Assessment and discussion questions

Chapter 36. Bibliographic resources in electroanalysis

36.1. Books and monographs

36.2. Journals

36.3. Web resources

Index

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Tags: Teresa Fernández Abedul, Laboratory Methods, Dynamic Electroanalysis