{Affordable voltammetric sensor based on anodized disposable pencil graphite electrodes for sensitive determination of dopamine and uric acid in presence of high concentration of ascorbic acid}


http://dx.doi.org/10.5599/jese.783   263 

J. Electrochem. Sci. Eng. 10(3) (2020) 263-279; http://dx.doi.org/10.5599/jese.783  

 
Open Access: ISSN 1847-9286 

www.jESE-online.org 
Original scientific paper 

Affordable voltammetric sensor based on anodized disposable 
pencil graphite electrodes for sensitive determination of 
dopamine and uric acid in presence of high concentration of 
ascorbic acid 

Preethi Sankaranarayanan and Sangaranarayanan M. Venkateswaran 

Department of Chemistry, Indian Institute of Technology Madras, Chennai, Tamil Nadu - 600036, 
India 

Corresponding author: preethi92.us@gmail.com; Tel.: +919500955589 

Received: February 3, 2020; Revised: February 28, 2020; Accepted: March 2, 2020 
 

Abstract 
A simple, disposable and low - cost voltammetric sensor based on the anodized pencil 
graphite electrode (APGE) for the simultaneous determination of dopamine (DA) and uric 
acid (UA) is demonstrated. The physico-chemical properties of the pencil graphite electrode 
(PGE) before and after anodization were analyzed using FT-IR, FT-Raman, SEM and EIS 
characterization techniques. In comparison to PGE, APGE exhibited excellent 
electrochemical activity towards the simultaneous detection of DA and UA with peak-to-
peak separation of about 0.18 V even in the presence of high concentration (2 mM) of 
ascorbic acid (AA). The discrimination of APGE towards AA was rationalized through the 
absence of favorable surface interactions between oxygen rich functional groups on the 
surface of APGE and AA. Using DPV without any pre-concentration step and under 
optimized conditions, APGE displayed a linear range of 1 – 80 μM with an estimated limit of 
detection (LOD, 3σ/m) of 0.008 μM and 0.014 μM for DA and UA, respectively. Moreover, a 
higher sensitivity in comparison to other previously reported pretreated pencil graphite 
electrodes was observed for DA (34.32 μA/μM) and UA (12.33 μA/μM). The practical 
applicability of APGE was demonstrated through the estimation of DA in human blood 
serum and UA in urine samples. 

Keywords 
Anodization; pencil graphite electrode; dopamine; uric acid; ascorbic acid. 

 

Introduction 

Neurotransmitters are an important class of biomolecules that play a vital role in control and 

effective functioning of the central nervous, cardiovascular, renal and hormonal systems [1,2]. 

http://dx.doi.org/10.5599/jese.783
http://dx.doi.org/10.5599/jese.783
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Dopamine (DA) is one of the neurotransmitters in the family of catecholamines, which exists as organic 

cations in brain tissues and body fluids. Abnormal or low level of DA in the human body leads to many 

psycho-somatic disorders [3.4]. Like DA, uric acid (UA) is another class of biomolecules which forms in 

the body as one of the principal end-products of the purine metabolism. Several diseases such as Lysch 

– Nyhan syndrome, hyperuricaemia and gout are the consequences of abnormal levels of UA [5-10]. 

Therefore, accurate detection of DA and UA in body fluids like blood serum and urine is of great clinical 

importance for an effective point of care analysis.  

In the recent past, due to their fast processing time and cost effectiveness, electroanalytical 

techniques have been favored over other traditional analytical techniques for the detection of DA 

and UA [11-13]. However, electrochemical detection of these two compounds at conventional 

electrodes such as bare carbon electrode has the following difficulties [14-16]: 

1. DA and UA coexist with electrochemically active ascorbic acid (AA) in biological fluids, thereby, 

causing mutual interference during detection. 

2. DA and UA have similar oxidation potentials, thereby rendering their electrochemical detection 

relatively challenging task. 

3. The concentration levels of UA and AA in body fluids are significantly higher in comparison with 

DA. 

4. During electrochemical detection of these compounds, their oxidation products adsorb or elec-

tropolymerize on the electrode surfaces, thereby reducing their reproducibility and reusability. 

In order to overcome the above-mentioned drawbacks of bare carbon electrodes, many 

researchers have employed novel materials as chemical modifiers [17], including polymeric 

materials [18,19], ionic liquids [20], carbon nanotubes (CNTs) [20-23], nanoparticles (NPs) [24] and 

nanocomposites [25,26]. From this perspective, the simplest way in which a bare carbon electrode 

can be chemically modified is electrochemical pretreatment by applying high potential using either 

chronoamperometry (CA) or cyclic voltammetry (CV) technique. During the anodization process 

(application of high positive potential) of bare carbon electrode, oxygen rich groups such as -OH,  

-COOH, etc. [5,27-29], are formed on the electrode surface. Due to the polar nature of these oxygen 

rich groups, the anodized carbon electrodes exhibit affinity towards adsorption of polar molecules 

and also enhance the wettability of electrodes [5,27,30]. Furthermore, at neutral or physiological 

pH, DA and UA exist as positively charged while AA as negatively charged ions [31,32]. Therefore, 

these molecules can be selectively determined at anodized carbon electrodes because of the 

inherent polar nature.   

Among various carbon electrodes, pencil graphite electrodes (PGEs) have recently received 

widespread attention. Due to their sp2 hybridized carbon, PGEs exhibit good conductivity, adsorption 

properties, low background current, high sensitivity, and ease of preparation and surface modification 

[24,33-37]. Moreover, in comparison to glassy carbon electrodes (GCEs), PGEs offer easy renewability 

of the electrode surface, which plays an important role in subsequent analysis [24]. However, only few 

reports are available wherein pretreated PGEs have been utilized for the detection of DA and UA 

[11,38,39]. For example, Ozcan et al. have developed the electrochemically over-oxidized PGE 

modified by poly(pyrrole-3-carboxylic acid) for the detection of DA in blood serum samples, where 

chronoamperometry was employed for carrying out the anodization [38]. Further, Alipour et al. 

reported a pre-treated PGE for the simultaneous determination of DA and UA in biological samples 

wherein, cyclic voltammetry was employed to prepare anodized PGEs [11]. Though, these studies have 

reported good figures of merit, the analyses were preceded by a pre-concentration step and exhibited 

short linear range of calibration plots.  



P. Sankaranarayanan and M. Venkateswaran J. Electrochem. Sci. Eng. 10(3) (2020) 263-279 

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Hence, in the present study we have developed anodized disposable pencil graphite electrodes 

(APGEs) for the selective and sensitive determination of DA and UA in the presence of high 

concentration of AA without any pre-concentration step. PGEs were anodized using a simple 

chronoamperometric method and formed APGEs were subsequently analyzed using various 

material characterization techniques. The discriminating nature of APGE has been rationalized 

through the formation of oxygen containing groups on the electrode surface. 

Experimental  

Chemicals and reagents 

 K2HPO4 (Fisher Scientific, 99.5 %), KH2PO4 (SRL, 99.5 %), HCl (Merck, >35 %), NaOH (Aldrich, 

>97 %), K4[Fe(CN)6].3H2O (Merck, 99 %), K3[Fe(CN)6].3H2O (Merck, 99 %), KNO3 (Merck, >98 %), 

Ascorbic Acid (SRL, 99.7 %), Uric Acid (SRL, 99 %), D-Glucose (SRL, 99 %), Dopamine Hydrochloride 

(Alfa Aesar, 99 %), KCl (SRL, >99.5 %), NaCl (AR, ACS, ExiPlus, 99.9 %) and Na2SO4 (AR, ACS, ExiPlus, 

99.9 %) were of analytical grade and used as received. The phosphate buffer solution (PBS, 0.1 M) 

was freshly prepared using 1 M of K2HPO4 and 1 M of KH2PO4 with triple distilled water. Prior to 

analysis, 10 mL of 0.1 M PBS was purged with argon for 15 minutes to dissolved oxygen. The pH of 

0.1 M PBS was adjusted using either 5 M HCl or 5 M NaOH. Stock solutions of 0.02 M uric acid, 0.1 M 

ascorbic acid and 0.01 M dopamine were freshly prepared using 0.1 M PBS (pH 7.0).  

Electrochemical measurements 

Differential pulse voltammetry (DPV), chronoamperometry (CA), cyclic voltammetry (CV) and 

electrochemical impedance spectroscopy (EIS) were carried out using conventional three-electrode 

assembly in the CHI660A electrochemical workstation (CH instruments, USA). The pencil graphite 

leads (HB, 0.5 mm diameter, 60 mm height, Camlin), Pt gauze and saturated calomel electrode (SCE) 

were used as working, counter and reference electrodes, respectively.  

Anodization of PGE 

Prior to the anodization, PGEs were mechanically polished with a clean white paper (75 GSM grade) 

and washed thoroughly with water. An apparent surface area of 0.19 cm2 of PGE was exposed and the 

remaining area was covered using a scotch tape except a small portion exposed for connecting the 

leads. PGEs were anodized by CA and the experimental parameters such as anodization potential, time 

and supporting electrolyte were optimized for maximum sensing performance. As the first step, three 

different supporting electrolytes, namely 0.1 M PBS (pH 7.0), 0.1 M HCl (pH 1.1) and 0.1 M NaOH (pH 

13.0) were used for anodization of PGEs at 2.0 V for 120 s. Secondly, five different anodization 

potentials (1.6, 1.8, 2.0, 2.2 and 2.4 V) and time applied (60, 120, 180, 240 and 300 s) for anodization 

were examined in 0.1 M PBS (pH 7.0). PGE anodized at 2 V for 120 s in 0.1 M PBS (pH 7.0), was chosen 

as the optimized condition (vide infra) for anodization and the electrode hereafter will be referred as 

anodized PGE (APGE). These APGEs were then thoroughly washed with water, dried and subsequently 

used as working electrodes for further studies. 

Spectroscopic, morphological and electrochemical characterizations 

Fourier transform infrared (FT-IR) and Fourier transform Raman (FT-Raman) spectroscopies were 

used to characterize the electrodes. FT-IR spectra were recorded with the help of KBr pellets in 

JASCO 4100 spectrometer. In order to make the pellets, 0.5 cm of PGE (bare/anodized) was broken 

and grinded along with KBr. Raman spectra were acquired using BRUKER RFS 27: Standalone FT-

Raman Spectrometer. The surface morphology (SEM) and electron dispersive analysis of X-rays 

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(EDX) of both electrodes were carried out using FEI Quanta FEG200 at an acceleration voltage of 20 

kV in high vacuum mode. Prior to the spectroscopic and morphological measurements, the 

electrodes were dried using a heat gun and stored in a vacuum desiccator for 48 hours to remove 

the moisture. 

The electrochemical characterizations of PGE and APGE were carried out in 0.1 M PBS (pH 7.0) 

solution containing 10 mM [Fe(CN)6]4-/3- (1:1) using CV and EIS. For CV, the potential was scanned from 

-0.2 to 0.6 V at different scan rates (5 to 50 mV/s). EIS measurements were carried out at 0.26 V in the 

frequency range of 104 to 10−1 Hz with the amplitude of 5 mV. The electrical equivalent circuit fittings 

were carried out using the default fitting software provided with the instrument. 

Simultaneous detection of DA & UA in the presence of high concentration of AA 

The simultaneous detection of DA and UA at APGE was carried out in 0.1 M PBS (pH 7.0) using DPV 

in the presence of 2 mM of AA. DPV experiments for sensing were carried out by scanning the potential 

from −0.2 to 0.6 V, while the other parameters such as increment voltage, amplitude, pulse width, 

pulse period and quiet time were kept constant at 0.004 V, 0.05 V, 0.05 s, 0.5 s and 2 s, respectively. 

The corresponding calibration plots were constructed after triplicate measurements.  

Real sample analysis 

For real sample analysis, the human blood serum and urine samples were obtained from the 

Apollo clinical laboratory, IIT-Madras, Chennai. Blood serum and urine samples were respectively 

diluted to 500 and 1000 times in 0.1 M PBS (pH 7.0) prior to the measurement. 

Results and discussion 

Spectroscopic characterization 

It is a well-established fact that anodization of carbon surface leads to the creation of surface 

defects due to the formation of oxygen rich functional groups such as -COOH, -OH, etc. [27,40]. As a 

result, sp2 hybridized lattices of graphite get distorted because of sp3 hybridized carbons of these 

functional groups. The changes such as formation of new functional groups and distortion of graphite 

lattice sites are effectively captured in FT-IR and FT-Raman spectroscopy, respectively. Infrared 

spectroscopy is an excellent tool for finding out the formation of new functional groups. FT-IR spectra 

for PGE before and after anodization process in 0.1 M PBS (pH 7.0) are given in Figure 1a. 

 
Figure 1. (a) FT-IR and (b) FT Raman spectra for PGE and APGE 



P. Sankaranarayanan and M. Venkateswaran J. Electrochem. Sci. Eng. 10(3) (2020) 263-279 

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It can be inferred from Figure 1a that oxygen rich functional groups have formed on PGE as a 

result of anodization. The characteristic peaks at 3144 cm-1 (O–H stretching from COOH), 1662 cm-1 

(C=C stretching), 1394 cm-1 (C=C bending) and 1088 cm-1 (C–O stretching from COOH) indicate the 

successful modification of PGE surface with these functional groups [41,42]. Furthermore, IR peak 

intensities of APGE are significantly higher than that of PGE. It can be inferred from Figure 1a that 

oxygen rich functional groups have formed on PGE as a result of anodization. The characteristic 

peaks at 3144 (O–H stretching from COOH), 1662 (C=C stretching), 1394 (C=C bending) & 1088 cm-1 

(C–O stretching from COOH) indicate the successful modification of PGE surface with these functi-

onal groups [41,42]. Also, IR peak intensities of APGE are significantly higher than that of PGE.  

In order to investigate the variations in the graphitic structures, Raman spectroscopy is the 

characterization tool of choice. Once the graphitic lattice is altered after anodization, they exhibit 

characteristic D and G vibrational bands at wavenumbers 1330 cm-1 for sp3 hybridized (disordered, 

tetragonal) and 1570 cm-1 for sp2 hybridized (ordered, hexagonal) carbons present in them. Further-

more, the ratio of intensities of D band to G band i.e., ID/IG provides a measure of the disorderliness 

present in the graphite lattice [43]. Moreover, greater ID/IG value is an indication of more disorder-

liness. In general, it has been reported that the oxygen rich functional groups such as quinone, phenol 

and alcohols are responsible for D band of oxygen containing graphitic materials [41,44-47]. Figure 1b 

depicts Raman spectra for PGE and APGE which show D and G bands at 1351 and 1569 cm-1, respecti-

vely. Moreover, ID/IG was observed to be 0.589 and 0.594 for PGE and APGE, respectively. Hence, it is 

evident from ID/IG ratios for PGE and APGE that, APGE exhibits more disorderliness due to anodization.  

Morphological characterization 

The morphological variations of PGEs after anodization were analyzed using SEM technique. SEM 

images for PGE and APGE are shown in Figures 2a & 2b, respectively. It can be inferred from Figure 2 

that the roughness of the graphite surface has significantly increased after anodization. Furthermore, 

the formation of oxygen containing groups after anodization is further corroborated from the 

presence of oxygen elemental peak in EDX spectrum for APGE (Figure 2d) which is absent for PGE 

(Figure 2c).  

Electrochemical characterization 

Electrochemical behaviors of PGE and APGE were evaluated using the standard [Fe(CN)6]3-/4- redox 

couple and the cyclic voltammograms of both these electrodes are shown in Fig. 3a. Cyclic vol-

tammograms recorded at different scan rates for APGE are shown in Figure 3b. In comparison with 

the voltammetric response of PGE, the peak current of APGE was found to be higher thereby indicating 

an enhanced electron transfer after anodization. Moreover, the peak currents of both PGE and APGE 

were found to increase with the scan rate. The electrochemical active surface areas (ECASA) for PGE 

and APGE were calculated from ip vs. ν1/2 plots (Fig. 3c) using the Randles-Ševcik equation: 
5 3 2 1 2 1 2

p s2 69 10
/ / /i . n D AC =   (1) 

where ip is the peak current in A, n is the number of electrons in the redox process (here n=1), D is 

the diffusion coefficient of [Fe(CN)6]3-/4- (1.3210-6 cm2/s), Cs denotes the bulk concentration of 

[Fe(CN)6]3-/4- (10 mM, 1:1) and ν is the scan rate. The parameter A in equation (1) denotes ECASA 

that was found to be 0.36 cm2 and 1.32 cm2, respectively, for PGE and APGE. Furthermore, the 

roughness factors for PGE and APGE were determined using ECASA to geometrical surface area ratio 

which was estimated to be 1.78 and 6.48, respectively. This considerable increase in the roughness 

of APGE is in concordance with the observations in SEM micrographs (Figure 2b). 

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Figure 2. Scanning electron micrographs for (a) PGE and (b) APGE.  
The corresponding EDX spectra for (c) PGE and (d) APGE 

 
Figure 3. Cyclic voltammograms in 0.1 M PBS (pH 7.0) containing 10 mM (1:1) [Fe(CN)6]

3-/4-for (a) APGE and 
PGE at 5 mV/s, and (b) APGE at various scan rates ranging from 5 mV/s to  

50 mV/s. (c) Variation of ipa with ν
1/2 for APGE 

In order to understand the variation in the electron transfer kinetics of PGE before and after 

anodization, EIS was employed. Nyquist plots measured for PGE and APGE in 0.1 M PBS (pH 7.0) 

containing 10 mM (1:1) [Fe(CN)6]3-/4- at 0.26 V are shown in Figure 4a. The distinct semicircular shape 

in the Nyquist plot for APGE at higher to medium frequencies corresponds to the electron transfer 

limited process while the linear part extending to lower frequencies indicates the process limited by 

diffusion. Nyquist plot of PGE, however, exhibits a prominent semicircular shape without a 

contribution of linear part due to diffusion impedance. The Nyquist plots obtained were fitted using 

modified Randles electrical equivalent circuits shown in Figures 4b and 4c, respectively for PGE and 

APGE. The constant phase element (CPE) was chosen as double-layer capacitive element to account 

for various inhomogeneities arising from the nature of the electrode and its porosity [48]. Warburg 

element (W) denotes impedance due to diffusion, while Rs and Rct denote resistances due to the 

electrolyte solution and charge transfer at the electrode-electrolyte interface, respectively. 



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Frequency dependences of CPE impedance (ZCPE) and Warburg impedance (ZW) are defined as: 

dl

dl

CPE

1
( )

n
CPE j

Z
=  (2) 

0 5

(1 )
.

WZ j
W


−

= −  (3) 

 

 
Figure 4. (a) Nyquist plots for PGE and APGE measured in 0.1 M PBS (pH 7.0) containing 10 mM [Fe(CN)6]

4-/3- 
(1:1) at 0.26 V  in the frequency range of 104 to 10−1 Hz. Electrical equivalent circuits for (b) PGEand (c) APGE 

In equations (2) and (3), CPEdl, ndl and W are frequency independent impedance parameters, 

while j is imaginary number and ω is radial frequency of measurements. Impedance parameter 

values obtained by fitting electrical equivalent circuits to the Nyquist plots are given in Table 1. 

Table 1. Summary of impedance parameter values obtained by fitting equivalent circuits in Figure 4b-c to 
Nyquist plots in Figure 4a 

Electrode Rs/ Ω CPEdl, µS s
n ndl W / S s

1/2 Rct / Ω ko / 10
−6 cm s−1 

PGE 11.92 11.64 0.854 -- 1113 6.64 

APGE 16.91 226.9 0.713 0.007 100.8 19.99 

From the charge transfer resistance (Rct) values, the standard heterogeneous rate constants (ko) 

were estimated using equation (4) and are provided in Table 1: 

o 2 2
ct s

RT
k

n F AR C
=  (4) 

It can be inferred from Table 1 that ko for APGE is 3 times higher than for PGE which in turn is 

responsible for its enhanced electrochemical activity (vide infra). 

Electrochemical behavior of APGE towards DA and UA 

In order to compare the performance of PGE and APGE towards DA and UA detection, 

voltammetric techniques were employed. The cyclic voltammetric responses of 10 µM DA (Figure 

5a) and 20 µM UA (Figure 5c) were recorded in 0.1 M PBS (pH 7.0) at the scan rate of 25 mV/s. It 

can be inferred from Figures 5a & 5c that quasi reversible behavior was observed for both DA & UA 

at APGE. On the other hand, at PGE, an irreversible cyclic voltammogram was observed for both 

species. Furthermore, the anodic peak at APGE for DA and UA was found to be centered at 0.15 V 

and 0.33 V, respectively. Also, the corresponding current responses at APGE for DA and UA were 12 

and 10 times higher than at PGE. 
 

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Figure 5. Cyclic voltammograms of (a) 10 µM of DA and (c) 20 µM of UA in 0.1 M PBS (pH 7.0) at PGE and 

APGE. Corresponding differential pulse voltammograms for (b) DA and (d) UA 

Since differential pulse voltammetry (DPV) is known to be more sensitive analytical technique than 

CV, DPV responses for DA (Fig. 5b) and UA (Fig. 5d) at APGE were compared with PGE. At APGE, the 

oxidation peak potential was observed at 0.11 V for DA and 0.31 V for UA. However, extremely weak 

DPV signals for DA and UA oxidation were observed at PGE. Unlike CVs shown in Figs. 5a & 5c, the 

oxidation peak currents in DPV for DA and UA at APGE were found 92 and 112 times higher than at 

PGE (Figs. 5b & 5d). The enhanced current response for DA and UA at APGEis attributed to its increased 

ECASAand the presence of non-covalent interactions (vide infra). Thus, it is evident from the above 

discussion that APGE can be effectively employed for the detection of DA and UA.  

Effect of pH  

The effect of pH of PBS on the detection of DA and UA was investigated using DPV in the pH range 

of 5.0 – 9.0 and the corresponding voltammograms are shown in Figures 6a & 6c. The anodic peak 

currents of both DA and UA increase, reach the maximum at pH 7.0, and for higher pH decrease 

subsequently. The increment in the peak currents from pH 5.0 to 7.0 is attributed to the proton 

transfer during the oxidation process. On the other hand, the decrease in the peak currents from 

pH 7.0 to 9.0 is due to the facile oxidation of hydroxyl groups and the instability of the oxidized form 

of DA and UA [49].  

Furthermore, the oxidation peak potentials (Ep) of DA and UA were found to be dependent on 

pH values as observed in Figures 6b & 6d. It can also be deduced from these figures that with every 



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unit increase of pH, the Ep shifts towards negative potential region. The linear regression equation 

for the dependence of Ep with pH agrees with the Nernst equation viz.  

Ep = Eo’-0.0591 pH (5) 

where E0’ is the formal potential. Since the slope values observed here for DA (-60.4 mV/pH) and UA 

(-58.6 mV/pH) are in close agreement with the theoretical slope value of equation (5), the same 

number of electrons and protons is involved in the oxidation process. The electrochemical oxidation 

of DA and UA taking place at APGE is illustrated in Scheme 1. Based on the highest current response, 

pH 7.0 has been chosen as the optimized pH for subsequent experiments. 
 

 
Figure 6. Differential pulse voltammograms of APGE at different pH values in 0.1 M PBS containing (a) 

10 µM of DA and (c) 20 µM of UA. Variations in Ep with change in pH for (b) DA and (d) UA 

 
Scheme 1. Schematic representation of electrochemical oxidation mechanism of DA and UA at APGE 

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Optimization of experimental parameters 

Prior to the simultaneous determination of DA and UA at APGE, various experimental parameters 
such as kind of supporting electrolyte, potential and time used for anodization were analyzed via 
DPV current responses of various APGEs in solutions containing 20 μM of either DA or UA. Before 
optimizing the anodization potential and time, the effects of supporting electrolytes were studied 
using 0.1 M PBS, 0.1 M NaOH and 0.1 M HCl while the applied potential and time were kept constant 
at 2 V and 120 s, respectively. The corresponding DPV responses are shown in Figure 7a for DA and 
Figure 7d for UA. Since the maximum current response was observed in 0.1 M PBS for both DA and 
UA, it was chosen as the supporting electrolyte in the subsequent studies. 

 
Figure 7. Differential pulse voltammograms for APGE prepared in (a,d) different supporting electrolytes, and 

(b,e) in 0.1 M PBS (pH 7.0) at different applied anodization potentials and  
(c,f) different anodization times. Solutions contained(a-c) 20 µM of DA and (d-f) 20 µM of UA. 

For optimizing the anodization potential, the time of anodization was kept constant at 120 s while 

the applied potential was varied from 1.6 V−2.4 V in 0.1 M PBS. The maximum current response was 

observed for APGE anodized at 2 V in the case of both DA (Figure 7b) and UA (Figure 7e). Furthermore, 

the anodization time was optimized by varying the time of anodization from 60 − 300 s, while keeping 

the anodization potential constant at 2 V. The maximum current response was observed for APGE 

anodized at 2 V for 120 s for both DA (Figure 7c) and UA (Figure 7f). DPV results depicted in Figure 7 

can be understood as follows: due to severe anodization in basic solution (0.1 M NaOH), more oxygen 

containing functional groups may form, thereby resulting in sluggish electron transfer. On the other 

hand, the extent of anodization is comparatively lower in acidic condition (0.1 M HCl) which results in 

poor current response for the oxidation of DA and UA. However, in neutral conditions optimal surface 

oxidation of graphite occurs which in turn is responsible for the maximum current response. At higher 

anodization potential or time, the graphite surface gets oxidized excessively. This leads to low current 

response for DA and UA. On the contrary, due to insufficient formation of oxygen containing functional 

groups at lower anodization potential or time, the current observed in voltammograms for DA and UA 

oxidation is poor. Thus, from the maximum current responses observed in Figures 7a-f, the optimized 

conditions for anodization potential, anodization time and supporting electrolyte were chosen as 2 V, 

120 s and 0.1 M PBS (pH 7.0), respectively. 



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Mechanistic investigation of DA and UA oxidation at APGE 

The effect of scan rate (ν) changes was investigated at APGE in 0.1 M PBS (pH 7.0) containing 

either 100 μM of DA (Figure 8a) or UA (Figure 9a) by varying scan rates from 5 to 500 mV/s. The 

logarithm of peak currents (log ipa) of DA and UA increases linearly with logarithm of scan rate (log ν) 

(Figures 8b & 9b) suggesting that the redox processes taking place at APGE may be adsorption or 

diffusion controlled [50]. Furthermore, an excellent linearity between log ipa and log ν with the slope 

value close to unity for DA (Figure 8b) and 0.5 for UA (Figure 9b) was observed. These slope values 

indicate that adsorption and diffusion-controlled electron transfer process is predominant for DA 

and UA, respectively. 

 

 
Figure 8.(a)Cyclic voltammograms of APGE electrodes containing 100 µM DA in 0.1 M PBS (pH 7.0) at scan 

rates ranging from 5 – 500 mV/s,(b) variation of log ipa with log ν, and variation of Ep-E
o’ with log ν 

 
Figure 9. (a) Cyclic voltammograms of APGE electrodes containing 100 µM UA in 0.1 M PBS (pH 7.0) at scan 

rates ranging from 5 – 500 mV/s, (b) variation of log ipa with log ν, and variation of Ep-E
o’ with log ν 

According to Laviron’s formalism [51,52], when ΔEp>(0.20/n) V, a linear plot of Ep(a,c)-Eº’ vs. log ν 

would be observed. Furthermore, from the intercepts of Ep(a,c)-Eo’ vs. log ν plots, the electron 

transfer coefficient (α) and the apparent surface electron transfer rate constant (ks) can be obtained 

using the following equations: 

a

c 1

 

 
=

−
 (6) 

a c
s

(1 )
= =

nF nF
k

RT RT

   −
 (7) 

In equations (6) and (7), νa and νc denote the intercepts for anodic and cathodic process, respect-

tively, n is the number of electrons involved in the redox process, while other symbols have their usual 

significance. Here, Eo’ corresponds to the formal potential or the mean value of the anodic and 

cathodic peak potentials obtained at 5 mV/s. The number of electrons (n) involved in the redox 

process was calculated to be 2.01 and 1.55 for DA and UA respectively, using equation (8) at 5 mV/s. 

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274  

p

0 059
Δ

.
E

n
=  (8) 

From Figures 8c & 9c, an excellent linearity between Ep(a,c)-Eo’ and log ν can be evidenced for DA 

and UA, respectively. The values calculated using equations (6-8) are summarized in Table 2. It can 

be deduced from Table 2 that ks for DA is higher than the value observed for poly(L-aspartic acid) 

modified GCE (1.13 s-1) [53]. On the other hand, ks for UA is greater than the value found for modified 

carbon nanotube paste electrode (1.17 s-1) [54]. 

Table 2. Summary of kinetic parameters for DA and UA at APGE estimated from Laviron’s theory  

Parameters DA UA 

α 0.58 0.60 

n 2.01 1.55 

ks/cm s
-1 4.87 3.69 

Selective determination of DA and UA at APGE in the presence of high concentration of ascorbic acid 

Since ascorbic acid (AA)ispresent at high concentration levelsin human body fluids, it is 

imperative to carefully evaluate the ability of APGE to selectively determine DA and UA in the 

presence of AA. Moreover, it is the prime objective of the current study. The comparison of 

differential pulse voltammograms of DA, UA and AA measured separately and at mixtures are shown 

in Figure 10. It is evident from Figure 10 that APGE doesn’t produce any signal for AA even if its 

concentration is high (2 mM). Thus, it is apparent from these voltammograms that APGE is able to 

detect DA and UA selectively without any interference from AA.  

 

 
Figure 10. Comparison of various differential pulse voltammograms at APGE in 0.1 M PBS (pH 7.0) and 

denoted concentrations of DA, UA and AA 

The discriminating ability of APGE towards DA, UA and AA can be understood in the following 

way [11,38,43]. The anodization process creates negative surface charge on APGE due to the 

formation of oxygen rich functional groups. It is well known that DA and UA exist in their protonated 

forms at neutral or physiological pH, while AA exists in deprotonated form. 



P. Sankaranarayanan and M. Venkateswaran J. Electrochem. Sci. Eng. 10(3) (2020) 263-279 

http://dx.doi.org/10.5599/jese.783   275 

Furthermore, during the positive potential scan the negatively charged oxygen rich groups on APGE 

surface favor the formation of hydrogen bonds with both DA and UA. Since, the voltammetric current 

response for DA oxidation is higher than that of UA (Figure 10), there may be another non-covalent 

interaction like π-π interaction in addition to the existing electrostatic and hydrogen bonding 

interactions between APGE and DA. On the other hand, the imperceptible voltammetric response 

observed for AA in Figure 10 is an indication of the absence of any such interactions between AA and 

APGE surface. The electrode mechanism described above is concisely summarized in Scheme 2. 

 

 
Scheme 2. Plausible mechanism for the selective detection of DA and UA in the presence of AA at APGE 

Simultaneous detection of DA and UA at APGE 

The main objective of this study was to evaluate the ability of APGE to simultaneously determine 

DA and UA in the presence of AA. In this regard, three differential pulse voltammetric experiments 

were carried out as follows: (i) 10 µM of DA and 2 mM of AA is kept constant while the concentration 

of UA is changed, (ii) 20 µM of UA and 2 mM AA is kept constant and the concentration of DA is 

varied, (iii) both DA and UA concentration is simultaneously altered in the presence of 2 mM AA. 

The corresponding differential pulse voltammograms are given in Figures 11a-c. It can be inferred 

from Figures 11a-c that with the increase in the concentration of DA and UA, the peak currents 

increase linearly. Furthermore, the linear calibration plots constructed from these DPV responses 

are given in Figures 11d-f. On close inspection of these calibration plots, it can be deduced that, in 

all three cases two linear ranges were observed in the concentration regions of 1-10 µM and 20-50 

µM, respectively. The linearity observed in Figures 11d-f indicates the excellent ability of APGE to 

simultaneously determine DA and UA even in the presence of high concentration of AA without any 

cross interference.  

The results obtained in the present study are compared in Table 3 with these obtained for other 

chemically modified carbon electrodes already reported in the literature for the simultaneous 

detection of DA and UA.  

 

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276  

 
Figure 11. DPVs obtained at APGE in 0.1 M PBS (pH 7.0) with different concentrations of (a) DA containing 

20 µM of UA and 2 mM of AA, (b) UA containing 10 µM of DA and 2 mM of AA, and (c) DA and UA 
containing 2 mM of AA. Concentrations varied in (a-c) were 1, 2.5, 5, 7.5, 10, 15, 20, 30, 50, 60 and 80 µM. 

Corresponding calibration plots for (a), (b), and (c) are given in (d), (e) and (f). 

Table 3. Comparison of the analytical performance of APGE for DA and UA determination with some 
previously reported modified electrodes  

Modified 
Electrode 

Pretreatment 
Method/ Conditions 

Pretreatment 
solution 

Pre-condi-
tioning 

Linear range, μM LOD, μM Sensitivity, μA/μM# 
Ref. 

DA UA DA UA DA UA 
CTAB-

PANI/AC/GCE 
- 

0.1 M PBS  
(pH 7.0) 

No 0.3 – 20 1 – 20 0.06 0.20 1.21 0.47 [12] 

GCE 
CV / 0 to 0.9 V  

at 30 mV/s 
0.5 M NaOH No 3.0–30 5.0–70 2.67 4.7 0.52 0.19 [56] 

GCE 
CV / 0.0 to +2.0 V  

at 100 mV/s 
0.1 M H

2
SO

4
 No 1.97–9.88 19.7–98.8 - - 3.16 0.83 [57] 

poly(EBT)/ 
GPE 

CV / -0.4 to 1.4 V  
at 100 mV/s 

0.05 M H2SO4 No 100 – 300 200 – 2000 - - - - [58] 

PPGE 
CV / 1.5 to 2.0 V  

at 100 mV/s 
0.1 M PBS  
(pH 5.0) 

Yes 0.15–15 0.3–150 0.033 0.12 0.18 0.02 [11] 

SGPGE CA / 3 V for 150 s 2 M NaOH Yes 0.15 – 45 - 0.0082 - 20.81 - [59] 
p(P3CA) / 

EOPGE 
CA / +1.8 V  

for 60 s 
0.1 M PBS  
(pH 7.4) 

Yes 0.01 – 7.5 - 0.0025 - 29.50 - [38] 

ETPGE 
CV / -0.3 to 2.0 V  

at 50 mV/s 
0.1 M H3PO4 Yes 0.01-5 - 0.0031 - 17.19 - [39] 

APGE 
CA / + 2.0 V  

for 120 s 
0.1 M PBS  
(pH 7.0) 

No 1 – 80 1 – 80 0.008 0.014 34.32* 12.33* 
This 

Work 
CTAB-PANI/AC/GCE – Cetyl trimethylammonium bromide – polyaniline / Activated charcoal / Glassy carbon electrode; GCE - Glassy carbon electrode; 
poly(EBT)/GPE – poly(Eriochrome black T) / Graphite pencil electrode; PPGE - Pretreated pencil graphite electrode; SGPGE – Surface-Graphenization Pencil 
Graphite Electrode; p(P3CA) / EOPGE – poly(pyrrole-3-carboxylic acid) / Electrochemically over-oxidized pencil graphite electrode; ETPGE – Elec-
trochemically treated pencil graphite electrode; # - Slope of the calibration plot; * - From the slope of the calibration plot in the low concentration range. 
 

It can be inferred from Table 3 that APGE exhibits higher sensitivity without any preconditioning 

of the electrode in comparison to other pretreated PGEs and GCEs. By comparing the results of other 

pretreated electrodes in Table 3, it is obvious that the electrodes anodized using chrono-

amperometry displayed better sensitivity than electrodes modified with CV. This may be attributed 

to more effective oxidation of carbon surface at constant potential than during a potential sweep. 

LOD values were calculated using 3σ/m. Here, σ is the standard deviation of the mean value for ten 

DPVs of the blank solution determined according to IUPAC regulations [55] and m denotes the slope 

estimated from the regression equation of the corresponding calibration plot. 



P. Sankaranarayanan and M. Venkateswaran J. Electrochem. Sci. Eng. 10(3) (2020) 263-279 

http://dx.doi.org/10.5599/jese.783   277 

Repeatability, reproducibility and stability 

In order to access the applicability of any electrochemical sensor, repeatability, reproducibility 

and stability are important figures of merit apart from sensitivity and selectivity of modified 

electrodes. The repeatability of APGE was determined from 10 consecutive DPV responses in 0.1 M 

PBS (pH 7.0) containing 50 μM DA and UA. The relative standard deviation (RSD) of 4.78 % for DA 

and 5.29 % for UA, is an indication of excellent repeatability of the modified electrode. For 

reproducibility study, differential pulse voltammograms of five identically prepared APGEs were 

obtained in 0.1 M PBS (pH 7.0) containing 50 μM DA and UA. An excellent reproducibility in the 

electrode preparation was apparent from RSD of 6.62 and 8.37 % respectively for DA and UA. The 

stability of APGE was determined from DPV response for 50 μM DA and UA in 0.1 M PBS (pH 7.0) 

after one month of storage at room temperature. The long-term stability of APGE was evident from 

the very minor decrement in the oxidation current response for DA (2.85 %) and UA (3.32 %). 

Real sample analysis 

The standard spike and recovery analysis were employed for the determination of DA in blood 

serum and UA in human urine samples using DPV. The recovery results are given in Table 4 and it 

can be seen that APGE was able to determine DA and UA with a satisfactory recovery in the range 

of 98-100 %. Thus, APGE can be utilized for real-time detection of DA and UA. 

Table 4. Results for spike and recovery analysis of DA and UA in blood serum and  
human urine samples using APGE 

Sample Analyte 
Amount, µM 

Recovery, % 
Added Found 

Blood Serum DA 

30 29.81 99.36 

50 50.32 100.60 
70 69.24 98.91 

Human Urine UA 

0 0.15 - 
30 30.13 100.40 

50 50.11 100.20 
70 70.08 100.11 

Conclusions 

 The suitability of a disposable electrochemical sensor for DA and UA using electrochemically 
anodized pencil graphite electrode (APGE) was successfully demonstrated. APGE was found to 
simultaneously distinguish between DA and UA even in the presence of 2mM of AA, thereby 
indicating its exceptional selectivity. Moreover, the proposed APGE sensor exhibited excellent 
analytical performance with satisfactory results. Unlike previously reported results on pretreated 
pencil graphite electrodes, the proposed APGE displayed higher sensitivity with low limits of 
detection without any preconditioning potential. From the good recovery results observed for DA 
in human blood serum and UA in urine samples, the potential application of APGE in point of care 
analysis was established. However, there is still a scope for improving the sensor performance 
through further chemical modifications. 

Acknowledgements: The authors thank the reviewers for their valuable comments and suggestions 

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