Carbon Nanomaterials Based Electrochemical Sensors/Biosensors for the Sensitive Detection of Pharmaceutical and Biological Compounds
"> Figure 1
<p>(<b>A</b>) FE-SEM images of the SWCNTs on the GCE surface. CV performance recorded at the SWCNT/GCE, in the absence (red solid line), and in the presence of (blue solid line) (<b>B</b>) 10 µM methylglyoxal, (<b>C</b>) 50 µM acetaminophen, and (<b>D</b>) 50 µM valacyclovir, in 0.1 M PBS (pH 7.4) at a scan rate of 20 mV/s. <a href="#sensors-15-22490-f001" class="html-fig">Figure 1</a>B reproduced with permission from [<a href="#B18-sensors-15-22490" class="html-bibr">18</a>]. Copyright 2013 Elsevier.</p> "> Figure 2
<p>Responses of the SWCNTs/GCE recorded in 0.1 M PBS (pH 7.4) (<b>A</b>) and (<b>B</b>) SWV responses of different methylglyoxal concentrations (0.1 µM to 100 µM) (<b>C</b>) DPV responses of acetaminophen (5 nM to 80 µM) and (<b>D</b>) DPV responses of valacyclovir (5–55 nM). <a href="#sensors-15-22490-f002" class="html-fig">Figure 2</a>A,B reproduced with permission from [<a href="#B18-sensors-15-22490" class="html-bibr">18</a>]. Copyright 2013 Elsevier. <a href="#sensors-15-22490-f002" class="html-fig">Figure 2</a>D reproduced with permission from [<a href="#B19-sensors-15-22490" class="html-bibr">19</a>]. Copyright 2013 Royal Society of Chemistry.</p> "> Figure 3
<p>(<b>A</b>) FE-SEM images of electrochemically reduced grapheme oxide (rGO) on the GCE surface; (<b>B</b>) CVs recorded at the rGO/GCE in the absence (red solid line), and presence of 50 µM acetaminophen (blue solid line) in 0.1 M PBS (pH 7.4) at a scan rate of 20 mV/s; (<b>C</b>) DPVs of the rGO/GCE recorded in 0.1 M PBS (pH 7.4) containing different acetaminophen concentrations (5 µM to 800 µM). <a href="#sensors-15-22490-f003" class="html-fig">Figure 3</a>A and 3B are reproduced with permission from [<a href="#B26-sensors-15-22490" class="html-bibr">26</a>]. Copyright 2015 Elsevier.</p> "> Figure 4
<p>(<b>A</b>) Amperometric responses recorded at rGO/GCE in 0.1 M PBS under various acetaminophen concentrations (5 nM–4 µM), E<sub>app</sub>: 0.5 V and (<b>B</b>) the calibration plot of current vs acetaminophen concentrations. All figures are reproduced with permission from [<a href="#B26-sensors-15-22490" class="html-bibr">26</a>]. Copyright 2015 Elsevier.</p> "> Figure 5
<p>(<b>A</b>) FE-SEM images of the AuNP-rGO on the GCE surface. (<b>B</b>) CVs recorded at the rGO/GCE (blue), and AuNPs-rGO/GCE (red) recorded in 1 mM NADH. (<b>C</b>) Amperometric i-t curve recorded at the Au-rGO/GCE in 0.1 M PBS under various NADH concentrations (50 nM–0.5 mM), Eapp: 0.55 V and (<b>D</b>) the calibration plot of current density <span class="html-italic">vs</span>. NADH concentration. All figures are reproduced with permission from [<a href="#B25-sensors-15-22490" class="html-bibr">25</a>]. Copyright 2015 Elsevier.</p> "> Figure 6
<p>(<b>A</b>) FE-SEM images of the SWCNTs-rGO nanocomposite on the GCE surface. CV performance recorded at the SWCNT-rGO nanocomposite/GCE in the absence (red solid line), and presence of (blue solid line) (<b>B</b>) 50 µM acetaminophen, (<b>C</b>) 50 µM valacyclovir in 0.1 M PBS (pH 7.4) at a scan rate of 20 mV/s. (<b>D</b>) DPVs of the SWCNT-rGO nanocompoposite/GCE recorded in 0.1 M PBS (pH 7.4) containing different acetaminophen concentrations (5 nM to 80 µM).</p> "> Figure 7
<p>(<b>A</b>) FE-SEM images of the carbon-buckypaper. (<b>B</b>) Ti/Au/BP/GOx-HRP electrode prior to (a) and following (b) injection of 10 mM glucose at a scan rate of 10 mV/s in PBS pH 7.4. Amperometric response and calibration curve of the Ti/Au/BP/GOx-HRP (i) and Ti/Au/BP (ii) electrodes upon the addition of 1 mM glucose (<b>C</b> and <b>D</b>). All figures are reproduced with permission from [<a href="#B28-sensors-15-22490" class="html-bibr">28</a>]. Copyright 2011 Elsevier.</p> "> Figure 8
<p>Schematic diagram of the preparation of the buckypaper-based electrochemical biosensor. (<b>a</b>) a titanium plate sputtered with a thin layer of gold; (<b>b</b>) gold interaction with chitosan; (<b>c</b>) attachment of buckypaper to the gold surface via chitosan; (<b>d</b>) activation of the buckypaper; (<b>e</b>) immobilization of enzymes; (<b>f</b>) the fabricated biosensor. All figures are reproduced with permission from [<a href="#B28-sensors-15-22490" class="html-bibr">28</a>]. Copyright 2011 Elsevier.</p> ">
Abstract
:1. Introduction
2. Experimental
2.1. Chemicals and Reagents
2.2. Fabrication of Electrochemical Sensors
2.3. Apparatus
3. Results and Discussion
3.1. Electrochemical Sensing of Methylglyoxal, Acetaminophen and Valacyclovir at SWCNTs
Carbon Based Nanomaterials | Analytes | Methods | Linear Range | Detection Limit | Reference |
---|---|---|---|---|---|
SWNT-Nafion-GOx | Glucose | Amperometry | 2 mM to 20 mM | - | 29 |
SWNT-GOx | Glucose | Amperometry | Up to 40 mM | - | 30 |
Pt-Nafion-SWCNTs-GOx | Glucose | Amperometry | 0.5 µM to 5 mM | 0.5 µM | 31 |
SWNT-mineral-oil paste | Lactate | Amperometry | Up to 7.0 mM | 0.3 mM | 32 |
Nafion-SWNT | Dopamine | DPV | 0.02 µM to 6.0 µM | 5.00 nM | 33 |
SWNT polymer composite | Dopamine | CV | 16 nM to 600 µM | 8 nM | 34 |
SWCNTs | Dopamine | DPV | 3 µM to 200 µM | 48 nM | 35 |
SWCNTs | Rutine | CV | 20 nM to 5 µM | 10 nM | 36 |
SWCNTs | Human serum albumin | CV | 0.075 nM to 7.5 nM | 75 pM | 37 |
SWCNTs | DNAs | DPV | 5 µM to 30 µM | 1.43 µM | 38 |
MWCNTs-Nafion | Epinephrine | CV and DPV | 0.06 mM to 0.24 mM | 0.02 mM | 39 |
MWNT nanocomposite | Epinephrine | LSV | 50 nM to 10 µM | 10 nM | 40 |
MWCNTs | Cholesterol | Amperometry | Up to 6.0 mM | 0.2 mM | 41 |
MWCNTs | Cholesterol | Amperometry | 100 mg/dL to 400 mg/dL | - | 42 |
MWCNTs | Methimazole | Amperometry | 0.074 µM to 63.5 µM | 0.056 µM | 43 |
MWCNTs-silver nanoparticles | Sumatriptan | CV | 80 nM to 100 µM | 40 nM | 44 |
MWCNTs | Paracetamol | ASV | 0.01 µM to 20 µM | 10 nM | 45 |
SWCNTs | Methylglyoxal | SWV | 0.1 µM to 100 µM | - | 18 |
SWCNTs | Valacyclovir | DPV | 5 nM to 55 nM | 1.8 nM | 19 |
SWCNTs | Acetaminophen | DPV | 5 nM to 80 µM | 4.3 nM | This work |
CuO-graphene | Glucose | Amperometry | 1 µM to 8 mM | 1 µM | 46 |
CuNPs/graphene | Glucose | Amperometry | 0.5 µM to 4.5 mM | 0.5 µM | 47 |
Graphene-ppy | Glucose | Amperometry | - | 3 µM | 48 |
Graphene-Pt | Ascorbic acid | DPV | 0.03 µM to 8.13 µM | 0.03 µM | 49 |
Graphene | Norepinephrine | Amperometry | 0.04 µM to 100 µM | 0.84 nM | 50 |
Reduced GO | NADH | Amperometry | 10 µM to 600 µM | 0.33 µM | 51 |
Graphene-Au nanorod | NADH | Amperometry | 5 µM to 337 µM | 1.5 µM | 52 |
Au-TiO2/graphene | NADH | Amperometry | 10 µM to 240 µM | 0.2 µM | 53 |
Graphene-TiO2 | NADH | Amperometry | 10 nM to 2 mM | 3 × 10−9 M | 54 |
AuNPs-rGO | NADH | Amperometry | 50 nM to 500 µM | 1.13 nM | 25 |
Nitrogen doped Graphene | Uric acid | DPV | 0.1 µM to 20 µM | 0.045 µM | 55 |
Graphene | Uric acid | Amperometry | 0.19 µM to 49.68 µM | 0.132 µM | 56 |
Nafion-AgNPs-rGO | Uric acid | LSV | 10 µM to 800 µM | 8.2 µM | 57 |
Pt-rGO | Uric acid | DPV | 10 µM to 130 µM | 0.45 µM | 59 |
ERGO | Serotonin | DPV | 5 µM to 300 µM | 0.11 µM | 59 |
ERG/Ni2O3-NiO | acetaminophen | DPV | 0.04 µM to 100 µM | 0.02 µM | 60 |
Graphene-chitosan | Acetaminophen | DPV | 1 µM to 100 µM | 0.3 µM | 61 |
Graphene | Acetaminophen | SWV | 0.1 µM to 20 µM | 0.032 µM | 62 |
rGO | Acetaminophen | DPV | 5 nM to 800 µM | 2.13 nM | 26 |
SWCNTs-GNS | Acetaminophen | DPV | 0.05 µM to 64.5 µM | 0.038 µM | 63 |
MWCNT-graphene nanosheets | Acetaminophen | DPV | 0.8 µM to 110 µM | 0.1 µM | 64 |
MWCNT/GO | Acetaminophen | DPV | 0.5 µM to 400 µM | 47 nM | 65 |
SWCNTs-rGO | Acetaminophen | DPV | 5 nM to 80 µM | 1.4 nM | This work |
MWCNT/GO | Dopamine | DPV | 0.2 µM to 400 µM | 22 nM | 65 |
MWCNT/GONR | Dopamine | DPV | 0.15 µM to 12.15 µM | 0.08 µM | 66 |
Buckypaper-SWCNTs | Glucose | Amperometry | 0 mM to 10 mM | 0.022 mM | 70 |
Buckypaper-GOx-HRP | Glucose | Amperometry | Up to 9 mM | 0.01 mM | 28 |
3.2. Electrochemical Sensing of Acetaminophen and NADH at rGO and Au Nanoparticle-rGO Nanocomposites
3.3. Electrochemical Sensing of Acetaminophen and Valacyclovir at SWCNTs-rGO Nanocomposites
3.4. Electrochemical Sensing of Glucose at Buckypaper
3.5. Electrocatalytic Performance of SWCNTs, rGO and SWCNTs-rGO for Acetaminophen and Valacyclovir: Comparative Analysis
4. Conclusions
Acknowledgments
Author Contributions
Conflict of Interest
References
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Adhikari, B.-R.; Govindhan, M.; Chen, A. Carbon Nanomaterials Based Electrochemical Sensors/Biosensors for the Sensitive Detection of Pharmaceutical and Biological Compounds. Sensors 2015, 15, 22490-22508. https://doi.org/10.3390/s150922490
Adhikari B-R, Govindhan M, Chen A. Carbon Nanomaterials Based Electrochemical Sensors/Biosensors for the Sensitive Detection of Pharmaceutical and Biological Compounds. Sensors. 2015; 15(9):22490-22508. https://doi.org/10.3390/s150922490
Chicago/Turabian StyleAdhikari, Bal-Ram, Maduraiveeran Govindhan, and Aicheng Chen. 2015. "Carbon Nanomaterials Based Electrochemical Sensors/Biosensors for the Sensitive Detection of Pharmaceutical and Biological Compounds" Sensors 15, no. 9: 22490-22508. https://doi.org/10.3390/s150922490
APA StyleAdhikari, B. -R., Govindhan, M., & Chen, A. (2015). Carbon Nanomaterials Based Electrochemical Sensors/Biosensors for the Sensitive Detection of Pharmaceutical and Biological Compounds. Sensors, 15(9), 22490-22508. https://doi.org/10.3390/s150922490