Novel electroanalysis of hydroxyurea at glassy carbon and gold electrode surfaces


doi: 10.5599/jese.2014.0064  111 

J. Electrochem. Sci. Eng. 4(3) (2014) 111-121; doi: 10.5599/jese.2014.0064 

 
Open Access: ISSN 1847-9286 

www.jESE-online.org  

Original scientific paper 

Novel electroanalysis of hydroxyurea at glassy carbon and gold 
electrode surfaces 

Keerti M. Naik and Sharanappa T. Nandibewoor 

P. G. Department of Studies in Chemistry, Karnatak University, Dharwad 580 003, India 

Corresponding author: E-mail: stnandibewoor@yahoo.com, Tel.: +91 836 2770524; Fax: +91 836 2747884 

Received: July 27, 2014; Revised: September 15, 2014; Published: September 22. 2014 
 

Abstract 
A simple and a novel electroanalysis of hydroxyurea (HU) drug at glassy carbon and gold 
electrode was investigated for the first time using cyclic, linear sweep and differential 
pulse voltammetric techniques. The oxidation of HU was irreversible and exhibited a 
diffusion controlled process on both electrodes. The oxidation mechanism was proposed. 
The dependence of the current on pH, the concentration, nature of buffer, and scan rate 
was investigated to optimize the experimental conditions for the determination of HU. It 
was found that the optimum buffer pH was 7.0, a physiological pH. In the range of 0.01 
to 1.0 mM, the current measured by differential pulse voltammetry showed a linear 
relationship with HU concentration with limit of detection of 0.46 µM for glassy carbon 
electrode and 0.92 µM for gold electrode. In addition, reproducibility, precision and 
accuracy of the method were checked as well. The developed method was successfully 
applied to HU determination in pharmaceutical formulation and human biological fluids. 
The method finds its applications in quality control laboratories and pharmacokinetics. 

Keywords  
Hydroxyurea; voltammetry; glassy carbon electrode; gold electrode; electroanalysis; oxidation 

 

Introduction 

Synthesis, chemical analysis and testing of the drugs are important events in pharmaceutical 

laboratories. The many of the essential drugs has been reported by previous workers, which 

requires the development and validation of analytical methods for their analysis. The 

requirements of the quality of the drugs have increased tremendously due to the regulations led 

by regulatory departments like FDA and ICH. Conventional methods have some shortcomings like 

time consumption and the use of costly and hazardous chemicals. This in turn motivated the 

analysts to develop and establish newer and faster methods of analysis of the quality of the drug 

http://www.jese-online.org/
mailto:stnandibewoor@yahoo.com


J. Electrochem. Sci. Eng. 4(3) (2014) 111-121 ELECTROANALYSIS OF HYDROXYUREA AT GC AND Au ELECTRODE 

112  

substance and drug products. Hydroxyurea (HU), the simplest, 1-carbon organic antitumor agent, 

is a member of the substituted urea group and is chemically known as hydroxycarbamide [1]. In 

1981 it was reported to have antineoplastic activity against sarcoma [2]. Presently, the primary 

role of hydroxyurea (Scheme 1) in chemotherapy is the management of granulocytic leukemia and 

thrombocytosis. It has been used in combination with radiotherapy for carcinomas of the head 

and neck [3]. HU is used in the treatment of cancer [4], sickle cell anemia [5] and infection with the 

human immunodeficiency virus (HIV) [6]. HU is a potent, nonalkylating myelosuppressive agent 

that inhibits DNA synthesis [7].  

 
Scheme 1. Structural formula of hydroxyurea. 

Only a few analytical procedures have been reported for the determination of HU. Nuclear 

magnetic resonance spectroscopy [8], liquid chromatographic (LC) procedures have been 

recommended by the U.S. Pharmacopeia [9] and others [10-12] for determination of hydroxyurea 

in pharmaceutical formulations and biological fluids. Capillary gas chromatography (GC) with 

thermionic (N-P) specific detection has also been reported [13]. Main problems encountered in 

using such methods are either the need for derivatization or the need for time-consuming 

extraction procedures. 

Electrochemical methods may offer certain advantages, such as easier sample preparation, 

being less time-consuming and offering detection limits and dynamic range comparable to other 

analytical methods [14,15]. These methods have proven useful for the development of very 

sensitive and selective methods for the determination of organic molecules including drugs. Redox 

properties of drugs can give insights into their metabolic fate or their in vivo redox processes or 

pharmaceutical activity [16]. 

Electrochemical methods, especially differential pulse voltammetry (DPV) make it possible to 

decrease the analysis time as compared to the time exhaustive chromatographic methods [17].
 

The advantages of DPV over other electroanalytical techniques are greater speed of analysis, lower 

consumption of electroactive species in relation to the other electroanalytical techniques, and 

fewer problems with blocking of the electrode surface.  

To the best of our knowledge, there is no report on the electroanalytical method for the 

determination of HU using glassy carbon (GCE) and gold (GE) electrodes until now. The aim of this 

study is to establish the suitable experimental conditions, to investigate the voltammetric behavior 

and oxidation mechanism of HU at GCE and GE by cyclic, linear sweep and differential pulse 

voltammetric methods for the direct determination of HU in real samples like pharmaceuticals and 

human biological fluids.  

Experimental 

Reagents and chemicals 

Hydroxyurea (HU) was obtained from Sigma Aldrich and used without further purification. A 

stock solution of HU (1.0 mM) was prepared in water and stored in a refrigerator at 4 
o
C. Standard 

working solutions were prepared by diluting the stock solution with the selected supporting 



K. M. NAIK et al. J. Electrochem. Sci. Eng. 4(3) (2014) 111-121 

: 10.5599/jese.2014.0064 113 

electrolyte. The phosphate buffers from pH 3.0 – 10.4 were prepared according to the method of 

Christian and Purdy [18]. The HU containing pharmaceutical product, HYDROX-L, was purchased 

from a local pharmacy. Other reagents used were of analytical grade. All solutions were prepared 

with millipore water. 

Instrumentation 

Electrochemical measurements were carried on a CHI 630D electrochemical analyzer (CH 

Instruments Inc., USA). The voltammetric measurements were obtained in a 10 ml single 

compartment three-electrode glass cell with Ag/AgCl as a reference electrode, a platinum wire as 

counter electrode and a 2-mm diameter glassy carbon electrode and gold electrode as working 

electrodes. All the potentials are given against the Ag/AgCl (3 M KCl). pH measurements were 

performed with Elico LI120 pH meter (Elico Ltd., India). All experiments were carried at an ambient 

temperature of 25 ± 0.1 
o
C. 

Analytical procedure 

Polishing of the glassy carbon electrode (GCE) and gold electrode (GE) was done on microcloths 

(Buehler) glued to flat mirrors. Al2O3 (0.3 μm) was used for polishing before each experiment. 

Before transferring the electrode to the solution, it was rinsed thoroughly with doubly distilled 

water. After this mechanical treatment, the GCE and GE were placed in 0.2 M phosphate buffer 

solution, and various voltammograms were recorded until a steady-state baseline voltammogram 

was obtained. 

The parameters for differential pulse voltammetry (DPV) were initial potential: 0.0 V; final 

potential: 1.2; increase potential: 0.004 V; amplitude: 0.05 V; frequency: 15 Hz; quiet time: 2 s; 

sensitivity: 1 × 10
-5

 A/V. 

Area of the electrodes 

The area of the electrode was obtained by the cyclic voltammetry method using 1.0 mM 

K3Fe(CN)6 as a probe at different scan rates. For a reversible process, the following Randles-Sevcik 

formula can be used [19]. 

Ipa = 0.4463(F
3
 / RT)

1/2
n

3/2
AD0

1/2
C0 υ

1/2
 (1) 

where Ipa refers to the anodic peak current, n is the number of electrons transferred, A is the 

surface area of the electrode, D0 is diffusion coefficient, υ is the scan rate, and C0 is the concen-

tration of K3Fe(CN)6. For 1.0 mM K3Fe(CN)6 in 0.1 M KCl electrolyte, T = 298K, R = 8.314 J K
-1

 mol
-1

, 

F = 96480 C mol
-1

, n = 1, D0 = 7.6×10
-6

 cm
2 

s
-1

, then from the slope of the plot of Ipa vs. υ
1/2

 relation, 

the electroactive area was calculated. In our experiment the slope was 2.46×10
-6

 μA (V s
-1

)
-1/ 2

 and 

2×10
-5 

μA (V s
-1

)
-1/ 2

 and the area of electrodes were calculated to be 0.033 cm
2 

and 0.0269 cm
2
 for 

GCE and GE. 

Sample preparation 

Two pieces of HU containing tablets were weighed and ground to a homogeneous fine powder 

in a mortar. A portion equivalent to a stock solution of a concentration of about 1.0 mM was 

accurately weighed and dissolved in water. The contents were sonicated for 20 min to affect 

complete dissolution. The excipient was separated by filtration and the residue was washed three 

times with water. The filtrate was diluted to 1.0 mM. Appropriate solutions were prepared by 

taking suitable aliquots from this stock solution and diluting them with the phosphate buffer 

solutions. Each solution was transferred to the voltammetric cell. The differential pulse 



J. Electrochem. Sci. Eng. 4(3) (2014) 111-121 ELECTROANALYSIS OF HYDROXYUREA AT GC AND Au ELECTRODE 

114  

voltammograms were subsequently recorded following the optimized conditions. The content of 

the drug in tablet was determined referring to the calibration graph or regression analysis. To 

study the accuracy of the proposed method and to check the interferences from excipients used in 

the dosage form, recovery experiments were carried out. The concentration of HU was calculated 

using standard addition method. 

Plasma sample preparation 

Human blood samples were collected in dry and evacuated tubes (which contained saline and 

sodium citrate solution) from a healthy volunteer. The samples were handled at room temperatu-

re and were centrifuged for 10 min at 1500 rpm for the separation of plasma within 1 h of collecti-

on. The samples were then transferred to polypropylene tubes and stored at 20 °C until analysis. 

The plasma samples, 0.2 mL, were deproteinized with 2 mL of methanol. After vortexing for 15 min, 

the mixture was then centrifuged for 15 min at 6000 rpm, and supernatants were collected. The 

supernatants were spiked with known amounts of HU. Appropriate volumes of this solution were 

added to phosphate buffer as supporting electrolyte and the voltammograms were then recorded. 

Results and discussion 

Cyclic voltammetric behavior of hydroxyurea 

The electrochemical behavior of HU at GCE and GE were studied using cyclic voltammetry (CV) at 

physiological pH = 7.0. The cyclic voltammograms obtained for 1.0 mM HU solution at a scan rate 

of 50 mV s
-1

 exhibit well-defined irreversible anodic peaks at 0.59, 0.78 and 0.91 V at glassy carbon 

electrode and 0.32, 0.84 and 1.13 V at gold electrode. The cathodic peak was appeared at 0.59 V 

corresponding to reduction of gold oxides [20]. The results are shown in Figure 1. However, no 

peak was observed in the reverse scan, suggesting that the oxidation process is an irreversible 

one. There are two possibilities, either the charge transfer kinetics are slow at surfaces of GCE and 

GE or products of the electron transfer were unstable and the reaction is accompanied by the fast 

chemical follow-up reaction resulting in electrochemically inactive products.  

 
Figure 1. Cyclic voltammograms obtained for 1.0 mM HU on glassy carbon electrode (GCE) and 
gold electrode (GE): (a) HU on GCE, (b) blank run of GCE, (c) HU on GE and (d) blank run of GE 

in pH 7.0, 0.2 M buffer at ν = 50 mV s
-1

.   

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

a 

c 

d b 

I 
/ 

µ
A

 

E / V vs. Ag/AgCl 



K. M. NAIK et al. J. Electrochem. Sci. Eng. 4(3) (2014) 111-121 

: 10.5599/jese.2014.0064 115 

Influence of pH 

The electrode reaction might be affected by pH of the medium. The electrooxidation of 

1.0 mM HU was studied over the pH range of 3.0 - 10.4 in phosphate buffer solution by cyclic 

voltammetry. A well-defined sharp oxidation peaks were appeared only in the pH range 7.0 - 10.4 

(Figures 2A and 2B). Below the pH 7.0, the oxidation peak was not observed; hence the pH study 

was restricted only in the range from 7.0 to 10.4. However, with the increase in the pH of the 

solution, the oxidation peak current decreased continuously from 7.0 - 10.4. A stability study 

showed that the HU was unstable in aqueous solutions even at 4 °C [13] since it degrades with the 

production of hydroxylamine. The peak potential (Ep) shifted towards less positive potentials with 

an increase in pH, suggesting the involvement of protons in the chemical process. From the plot of 

Ipa vs pH of GCE and GE it is clear that the peak height decreased with pH. Since the best sensitivity 

was achieved at pH 7.0, this pH was selected for further experiments. 
 

 A B 

 
Figure 2. Influence of pH on the shape of the peak in phosphate buffer solution at  

(a) 7.0, (b) 8.0, (c) 9.2 and (d) pH 10.4. For 1.0 mM HU on A - GCE, B - GE. 

Influence of scan rate 

Useful information involving electrochemical mechanism can be acquired from the relationship 

between peak current and scan rate. Therefore, the voltammetric behavior of HU at different scan 

rates from 10 to 50 mV s
-1

 was also studied using linear sweep voltammetry (Figures 3A and 3B). 

Scan rate studies were carried out to assess whether the processes on GCE and GE were under 

diffusion or adsorption-controlled.  

The plot of square root of scan rate with the peak current showed a linear relationship in the 

range of 10 to 50 mV s
-1

 which is of diffusion controlled process [21]. 

A plot of logarithm of anodic peak current vs. logarithm of scan rate gave a straight line with a 

slope of 0.424 and 0.516 (Figure 3C), which are close to the theoretical value of 0.5 for a purely 

diffusion-controlled process [22] which in turn confirms that the processes are diffusion controlled. 

The Ep of the oxidation peak was also dependent on scan rate. The peak potential shifted to 

more positive values on increasing the scan rate, which confirms the irreversibility of the oxidation 

process, and a linear relationship between peak potential and logarithm of scan rate (Figure 3D).  

For an irreversible electrode process, according to Laviron [23] Ep is defined by the following 

equation: 

'
p

2.303 2.303
log log

o
o RT RTk RTE E

nF nF nF


  
    (2) 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

a 

d 

a 

d 

I 
/ 

µ
A

 

E / V vs. Ag/AgCl 

 
 
 
 
 
 
 
 
 
 
 
 
 
 

 

 

 

a 

d 

a 

d 

I 
/ 

µ
A

 

E / V vs. Ag/AgCl 

 



J. Electrochem. Sci. Eng. 4(3) (2014) 111-121 ELECTROANALYSIS OF HYDROXYUREA AT GC AND Au ELECTRODE 

116  

 

 A B 

 

 C D 

 
Figure 3. Linear sweep voltammograms of 1.0 mM HU on  

A – GCE and B – GE, with different scan rates, a - e were 10, 20, 30, 40 and 50 mV s
-1

, respectively;  
C - Dependence of the logarithm of peak current Ip /10

-5
 A on log of scan rate (υ / V s

-1
); 1.0 mM HU on  

(A) GCE (log (Ip / µA) = 0.424 log (υ / V s
-1

) + 1.110; r = 0.9810) and  
(B) GE (log (Ip / µA) = 0.516 log (υ / V s

-1
) + 1.914; r = 0.9890);  

D - Relationship between peak potential Ep / V and logarithm of scan rate log (υ / V s
-1

); 1.0 mM HU on  
(A) GCE (Ep / V = 0.059 log (υ / V s

-1
) + 0.998; r = 0.9860) and  

(B) GE (Ep / V = 0.057 log (υ / V s
-1

) + 0.474; r = 0.9720). 

where α is the transfer coefficient, k
o
 is the standard heterogeneous rate constant of the reaction, 

n is the number of electrons transferred, υ is the scan rate, and E
o
 is the formal redox potential. 

Other symbols have their usual meanings. Thus, the value of αn can be easily calculated from the 

slope of Ep vs. log υ. In this system, the slope is 0.059 and 0.057 for GCE and GE, taking T = 298 K 

and substituting the values of R and F, αn was calculated. According to Bard and Faulkner [24] α 

can be given as 

p p/2

47.7
/ mV

E E
 


 (3) 

where Ep/2 is the potential where the current is at half the peak value. So, from this we obtained 

the value of α. Further, the number of electrons (n) transferred in the electrooxidation of HU was 

also calculated using linear sweep voltammetry. The value of k
o 

can be determined from the inter-

cept of the above plot if the value of E
o’

 is known. The value of E
o’

 in Equation (2) can be obtained 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

a 

e 

I 
/ 

µ
A

 

E / V vs. Ag/AgCl 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

a 

e 

I 
/ 

µ
A

 

E / V vs. Ag/AgCl 

 

log (υ / V s
-1

) 

Lo
g

 (
I p

 /
 1

0
-5

A
) 

B 

A 

0.0

0.5

1.0

1.5

2.0

2.5

-3 -2 -1 0

 

log (υ / V s
-1

) 

E
p
 /

 V
 

 

 A 

B 

0.0

0.2

0.4

0.6

0.8

1.0

1.2

-3 -2 -1 0



K. M. NAIK et al. J. Electrochem. Sci. Eng. 4(3) (2014) 111-121 

: 10.5599/jese.2014.0064 117 

from the intercept of Ep versus υ curve by extrapolating to the vertical axis at υ = 0 [24]. All the 

values of αn, α, n, E
o’

and k
o
 obtained from linear sweep voltammetry are tabulated in Table 1. 

Table 1. The calculated values of αn, α, n, E
o’

and k
o
 for the electro-oxidation of HU  

by linear sweep voltammetry (LSV) at GCE and GE 

Parameters Linear sweep voltammetry 

 Glassy carbon electrode Gold electrode 

αn 1.0024 1.0375 

α  0.5690 0.5860 

n 1.76 1.78 

E
o’

 / V 0.8740 0.3520 

k
o
 / min

-1
 4.910 × 10

3
 5.530 × 10

3
 

Calibration curve and detection limit 

To develop a rapid and sensitive voltammetric method for the determination of HU, differential 

pulse voltammetric method was adopted as the peaks obtained are better defined at lower 

concentration of HU than those obtained by cyclic voltammetry. According to the obtained results, 

it was possible to apply this technique to the quantitative determination of HU. The phosphate 

buffer solution of pH = 7.0 was selected as the supporting electrolyte for the quantification of HU 

as it gave a maximum peak current at pH = 7.0 for both GCE and GE. Differential pulse 

voltammograms obtained with increasing amounts of HU showed that the peak current increased 

with increasing concentration, as shown in Figures 4A and 4B. The concentration of HU was varied 

from 0.01 to 1.0 mM. Figure 4C shows that the graph of anodic peak current vs. concentration of 

HU shows two linear relationships in the range 0.01 to 0.08 and 0.2 to 1.0 mM.  

Above 1.0 mM, deviation from linearity was obtained which might be due to the adsorption of 

HU or its oxidation products on the electrode surface. The decrease of sensitivity (slope) in the 

second linear range is likely to the kinetic limitations [25]. Related statistical data of the calibration 

curves were obtained from the six different determinations. The detection limits (LOD) and 

quantification (LOQ) in the lower range regions were given in Table 2.  

Table 2. The Values of LOD and LOQ for HU at GCE and GE by using differential pulse voltammetric method 

 Glassy carbon electrode (GCE) Gold electrode (GE) 

Linearity range, mM 0.01 to 1.0 0.01 to 1.0 

Number of data points 06 06 

Limit of detection (LOD), µM 0.46 0.92 

Limit of quantification (LOQ), µM 1.54 3.08 

Repeatability – RSD,  % 1.14 2.02 

Reproducibility – RSD, % 1.46 2.48 
 

During the actual analysis, the analytical response was checked through the peak potential and 

its height. No change in peak potential was observed within an hour, while its height changed 

about ±1 % for five different quantitative determinations. This proposed method was better as 

compared with other reported methods [11,26].  



J. Electrochem. Sci. Eng. 4(3) (2014) 111-121 ELECTROANALYSIS OF HYDROXYUREA AT GC AND Au ELECTRODE 

118  

To ascertain the repeatability of the analysis, six measurements of 1.0 mM HU solution were 

carried out using GCE and GE at intervals of 30 min. The RSD value of peak current was found to be 

1.14 % and 2.02 % respectively, which indicated that the methods had good repeatability. As to 

the reproducibility between days, it was similar to that of within day repeatability if the 

temperature was kept almost unchanged. 

 A B 

 
C 

 
Figure 4. Differential pulse voltammograms of A – GCE and B - GE in HU solution at different concentrations: 

(a) 0.01, (b) 0.02, (c) 0.04, (d) 0.06, (e) 0.08, (f) 0.2 (g) 0.3, (h) 0.4, (i) 0.6, (j) 0.8 and (k) 1.0 mM  
C - Plot of peak current I / μA against the concentration of HU [HU] / mM 

(A) GCE (Ip / μA = 40.30 C / mM + 3.0870; r = 0.9880; Ip / μA = 7.625 C / mM + 6.7590; r = 0.9910) and  
(B) GE (Ip / μA = 28.87 C / mM + 1.5370; r = 0.9970; Ip / μA = 5.473 C / mM + 3.1490; r = 0.9870). 

Effect of excipients 

For the possible analytical application of the proposed method, the effect of some common 

excipients used in pharmaceutical preparations was examined. The tolerance limit was defined as 

the maximum concentration of the interfering substance that caused an error less than ±5 % for 

determination of HU. Under the optimum experimental conditions, the effects of potential excipi-

ents on the voltammetric response of 1.0 mM HU as a standard were evaluated. The experimental 

results showed that hundred-fold excess of citric acid, dextrose, glucose, gum acacia, lactose, 

starch, and sucrose did not interfere with the voltammetric signal of HU. Thus, the procedures 

were able to assay HU in the presence of excipients, and hence it can be considered specific. 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

a 

k 

I 
/ 

µ
A

 

E / V vs. Ag/AgCl 

 

 

 

 

 

 

 

 

 

 
 

 

 

 

 

  

 

 

 

a 

k 

I 
/ 

µ
A

 

E / V vs. Ag/AgCl 

0

2

4

6

8

10

12

14

16

18

0.0 0.5 1.0 1.5

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

[HU] / mM 

I 
/ 

µ
A

 

A 

B 



K. M. NAIK et al. J. Electrochem. Sci. Eng. 4(3) (2014) 111-121 

: 10.5599/jese.2014.0064 119 

Determination of HU in pharmaceutical preparations and recovery test 

The proposed method was validated for the determination of HU in pharmaceutical 

preparations in tablets as a real sample by applying DPV using the standard addition method. The 

procedure for the tablet analysis was followed as described in sample preparation section. The 

results are in good agreement with the content marked in the label (Table 3). Recovery studies 

were carried out after the addition of known amounts of the drug to various pre-analyzed 

formulations of HU. The recovery in the sample was found to be 98.83 % with RSD of 1.37 %. 

Table 3. Determination of HU in pharmaceutical formulation samples using  
differential pulse voltammetric method 

 Labeled claim 500.0, mg Added 20.0 mg 

GCE GE GCE GE 

Amount found, mg
a
 499.2 492.5 19.5 19.2 

Recovery, % 98.83 98.50 97.78 96.11 

RSD, % 1.37 1.87 3.51 3.54 

Bias, % -1.16 -1.50 -2.22 -3.88 
 a

 average of six determinations. 

Detection of HU in spiked human plasma samples 

The applicability of the DPV to the determination of HU in spiked human plasma sample was 

investigated. The recoveries from human plasma were measured by spiking drug free plasma with 

known amounts of HU. The plasma samples were prepared as described in plasma sample 

preparation section. A quantitative analysis can be carried out by adding the standard solution of 

HU into the detect system of plasma sample. The calibration graph was used for the determination 

of spiked HU in plasma samples. The detection results obtained for four plasma samples are listed 

in Table 4.  

Table 4. Determination of HU in spiked human plasma samples using  
differential pulse voltammetric method 

Human 
plasma 
sample  

Amount of 
spiked HU, 

10-4 M 

Amount of detected HU*, 
10-4 M 

Recovery, % RSD, % Bias, % 

GCE GE GCE GE GCE GE GCE GE 

1  0.3 0.3002 0.2998 100.1 99.95 2.92 3.12 0.067 -0.067 

2  0.7 0.6863 0.6797 98.05 97.10 2.67 2.25 -1.96 -2.90 

3  3.0 3.0407 3.0074 101.4 100.2 2.37 0.48 1.36 0.25 

4  7.0 6.9620 6.9820 99.45 99.74 1.79 0.96 -0.54 -0.26 

* average of six determinations 

Detection of HU in urine samples 

The developed differential pulse voltammetric method was also applied for the determination 

of HU in spiked urine samples. The recoveries from urine were measured by spiking drug-free 

urine with known amounts of HU. The urine samples were diluted 100 times with the phosphate 

buffer solution before analysis without further pretreatments. A quantitative determination can 

be carried out by adding the standard solution of HU into the detect system of urine sample. The 

calibration graph was used for the determination of spiked HU in urine samples. The detection 

results of four urine samples obtained are listed in Table 5. Thus, satisfactory recoveries of the 



J. Electrochem. Sci. Eng. 4(3) (2014) 111-121 ELECTROANALYSIS OF HYDROXYUREA AT GC AND Au ELECTRODE 

120  

analyte from the real samples and a good agreement between the concentration ranges studied 

and the real ranges encountered in the urine samples when treated with the drug make the 

developed method applicable in clinical analysis. 

Table 5. Determination of HU in urine samples using differential pulse voltammetric method 

Urine 

sample 

Amount of 
spiked HU, 

10
-4

 M 

Amount of detected HU*, 
10

-4
 M 

Recovery, % RSD, % Bias, % 

GCE GE GCE GE GCE GE GCE GE 

1 0.3 0.3025 0.3092 100.8 103.1 2.32 4.12 0.83 3.07 

2 0.7 0.6995 0.7101 99.94 101.4 0.34 1.41 -0.07 1.44 

3 3.0 2.9424 2.9424 98.08 98.08 1.73 1.73 -1.92 -1.92 

4 7.0 7.0799 6.9966 101.1 99.95 1.35 0.82 1.14 -0.05 

* average of six determinations. 

Conclusions 

The voltammetric oxidation of HU at glassy carbon and gold electrodes under physiological 

condition, i.e., pH 7.0 in phosphate buffer solutions has been investigated. HU undergoes two 

electron-two proton change and follows the diffusion-controlled process at both the electrodes. A 

suitable oxidation mechanism was proposed. The proposed method can be used successfully to 

assay the drug in pharmaceutical dosage form as well as in spiked real samples. High percentage 

recovery and study of excipients showed that the method is free from the interferences of the 

commonly used excipients in the formulations of drugs. The proposed method is suitable for 

quality control laboratories as well as pharmacokinetic studies where economy and time are 

essential. 

Acknowledgment: Keerti M. Naik thanks UGC, New Delhi for the award of Research Fellowship in 
Science for Meritorious Students (RFSMS). 

Nomenclature 

HU  = Hydroxyurea 
GCE  = glassy carbon electrode 
GE  = gold electrode 
DPV  = differential pulse voltammetry 
LSV  = linear sweep voltammetry 

CV  = cyclic voltammetry 
Ipa  = anodic peak current μA 
n  = number of electrons transferred 
A  = surface area of the electrode cm

2
 

D0  = diffusion coefficient, cm
2
 s

-1
 

υ  = scan rate, mV s
-1

 
C0  = concentration, M 
Ep  = peak potential, V 

 
Ip  = peak current, μA 
α  = transfer coefficient 
k

o 
= standard rate constant of the reaction, cm s

-1
 

F  = Faraday constant, C mol
-1

 

E
o
  = formal redox potential, V 

R  = gas constant, J K
-1

 mol
-1

 
T  = temperature, K 
LOD  = limit of detection, M 
LOQ  = limit of quantification, M 
s  = standard deviation of the peak currents 
m  = slope of the calibration curve 
RSD  = relative standard deviation 

References 

[1] R. Donehower, In Cancer Chemotherapy: Principles and Practice, B. A. Chabner, J. M. Collins, 
(Eds), J. B. Lippincott Co., Philadelphia, PA, 1990. 

[2] S. J. P. Van Belle, M. M. de Planque, I. E. Smith, A. T. van Oosterom, T. J. Schoemaker, W. 
Deneve, J. G.  McVie, Cancer Chemother. Pharmacol. 18 (1986) 27–32. 



K. M. NAIK et al. J. Electrochem. Sci. Eng. 4(3) (2014) 111-121 

: 10.5599/jese.2014.0064 121 

[3] D. Heerenberg, Basic Principles in Therapeutics, McGraw-Hill, New York, 1992. 
[4] R. C. Donehower, Semin. Oncol. 19 (1992) 11-19.  
[5] S. Charache, G. J. Dover, R. D. Moore, Blood 79 (1992) 2555-2565. 
[6] W. Y. Gao, A. Cara, R. C. Gallo, F. Lori, Proc. Natl. Acad. Sci. U.S.A. 90 (1993), 8925-8928. 
[7] I. H. Krakoff, N. C. Brown, P. Reichard, Cancer Res. 28 (1968) 1559–1565. 
[8] K. B. Main, T. Medwick, L. C. Bailey, J. H. Shinkai, Pharm. Res. 4 (1987) 412–415. 
[9] The U. S. Pharmacopia 23

rd
 Ed., U. S. Pharmacopeial Convention, Rockville, MD, 1995. 

[10] Q. Wang, H. J. Altermatt, H. B. Ris, B.E. Reynolds, J. C. M. Stewart, R. Bonnett, C. K. Lim, 
Biomed. Chromatogr. 7 (1993) 155–157. 

[11] E. W. Iyamu, P. D. Roa, P. Koposmbut, M. D. P. Aguinaga, E.A . Turner, J. Chromatogr. B 
Biomed. Appl. 709 (1998) 119–126. 

[12] K. K. Manouilov, T. R. McGruire, P. R. Gwilt, J. Chromatogr. B Biomed. Appl. 708 (1998) 321–
324. 

[13] A. El-Yazigi, S. Al-Rawithi, Pharm. Res. 9 (1992) 115–118. 
[14] C. Radovan, D. Cinghita, F. Manea, M. Mincea, C. Cofan, V. Ostafe, Sensors 8 (2008) 4330-

4349. 
[15] C. D. Souza, O. C. Braga, I. C. Vieira, A. Spinelli, Sens. Actuators B: Chem. 135 (2008) 66-73. 
[16] S. A. Ozkan, B. Uslu,  H. Y.  Aboul-Enein, Crit. Rev. Anal. Chem. 33 (2003) 155-181.  
[17] N. Erk, Anal. Bioanal. Chem. 378 (2004) 1351-1356. 
[18] G. D. Christian, W. C. Purdy, J. Electroanal. Chem. 3 (1962) 363-367. 
[19] B. Rezaei, S. Damiri, Sens. Actuators B 134 (2008) 324-331. 
[20] C. Barus, P. Gros, M. Comtat, S. Daunes-marion, R. Tarroux, Electrochim. Acta 52 (2007) 

7978-7985. 
[21] K. M. Naik, S. T. Nandibewor, Sensors and Actuators A 212 (2014) 127-132 
[22] D. K. Gosser, Cyclic Voltammetry: Simulation and Analysis of Reaction Mechanisms; VCH: 

New York, 1993. 
[23] E. Laviron, J. Electroanal. Chem. 101 (1979) 19-29. 
[24] A. J. Bard, L. R. Faulkner, Electrochemical methods; Fundamentals and Applications. 2

nd
 edn, 

Wiley, 2004. 
[25] M. Mazloum-Ardakani, H. Rajabi, H. Beitollahi, B. B. F. Mirjalili, A. Akbari, N. Taghavinia, Int. 

J. Electrochem. Sci. 5 (2010) 147-157. 
[26] J. Havard, J.  Grygiel, D.  Sampson, J. Chromatogr. B. 584 (1992) 270-274. 

 
 
 
 
 
 
 
 
 
 
 
 
 

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