An efficient platform based on cupper complex-multiwalled carbon nanotube nanocomposite modified electrode for the determination of uric acid

Abstract

A new voltammetric sensor for determination of uric acid (UA) by Cupper complex- multiwalled carbon nanotube (Cu-complex-CNT) nanocomposite modified carbon paste electrode (CPE) is reported. The electrocatalytic behavior of the Cu-complex-CNT nanocomposite modified CPE were studied in pH 2.0 phosphate buffer solution by chronoamperometry (CA) and cyclic voltammetry (CV) in the presence of uric acid. Due to the excellent electrocatalytic activity, enhanced electrical conductivity and high surface area of the Cu-complex-CNT, determination of uric acid with well-defined peaks was achieved at the Cu-complex-CNT modified electrode. The catalytic peak current obtained, was linearly dependent on the UA concentrations in the range of 0.66 – 350.0µM with sensitivity of 0.05 µA µM-1. The detection limits for UA were 0.075µM, The diffusion coefficient for the oxidation of UA at the modified electrode was calculated as (4.1±0.05) ×10−5 cm2 s−1. The proposed sensor was successfully examined for real sample analysis with urine and human serum and revealed stable and reliable recovery data.

Keywords: Uric acid, Cupper complex, Multiwalled carbon nanotube, Modified electrode

INTRODUCTION

Uric acid (2,6,8-trihydroxypurine, UA), is main final products of the cellular metabolic breakdown of purine nucleotides, adenosine and guanosine in the human body [1]. Uric acid is an important analyte in clinical field and plays a significant role in bioelectrochemistry and clinical diagnostics applications. Normal UA serum levels range from 41 to 88mgmL−1 and urinary excretion is usually 250–750mg per day [2]. It has been shown that abnormal concentration levels of UA in human body could be caused of such diseases like Lesch–Nyan syndrome, chronic renal, gout, cardiovascular and kidney damage [3,4]. Hence, monitoring the concentration of UA in biological fluids may be used as an early warning of the presence of kidney diseases. There are many methods for the determination of UA, such as enzymic colorimetric [5], chemical [6], chemiluminescence [7], fluorescence [8], voltammetric–colorimetric [9], high-performance liquid chromatography (HPLC) [10,11], and enzymatic–spectrophotometric [12]. These methods suffer from some disadvantages, such as the complex operating process, expensive instruments and strict pre-disposal. In recent years electrochemical procedures because of their simplicity, less time consumption, ease of miniaturization, high sensitivity and relatively low cost as compared to other technique have been extensively investigated for the determination of UA. In general, the electrochemical methods for monitoring UA could be classified as non-enzymatic and enzymatic methods.

Enzymatic methods include irreversibly oxidization of uric acid with uricase [13,14] to produce allantois and H2O2 [15] and then determination of H2O2. But this technique is expensive and difficult. In order to overcome these difficulties, many efforts have been carried out for developing novel materials used for modifying the electrode and various modified electrodes using nanoparticles [16,17], polymer film [18], metal oxide nanoparticles [19], ionic liquid [20] and carbon nano materials [21] have been constructed. In recent years, much attention has been given to the development of novel nanostructures, which are used for signal amplification in electrochemical sensors [22-29]. Nanomaterials are usually used to take advantage of a larger surface area for biomolecules to be immobilized [30-39]. Carbon nanotubes (CNTs) have received enormous attention in the recent years due to their unique structural, mechanical, geometric and chemical properties. Because of high surface area and electronic properties of carbon nanotubes they used in construction of electrochemical sensors [40,41] as promote electron transfer. Also, the copper can be used for many applications including buffer layer and contact for device fabrication, photocatalytic etc [42].

In this paper, we proposed for the first time the application of a modified CPE using MWCNTs and CU complex for determination of UA. Low detection limits and high sensitivity for UA was obtained due to the high electrocatalytic properties of MWCNTs and Cu complex. We evaluated Analytical performance of this sensor for determination of UA by voltammetry. Finally, this sensor has been used for the determination of UA in urine and human serum as real sample. 

EXPERIMENTAL

Reagents and solutions

The UA were purchased from Sigma-Aldrich and used as received. The stock solution of UA solution (0.01 M) was prepared by dissolving appropriate amount of UA in a small volume of .1 mol L−1 NaOH olution and diluted to reach desired concentration. The solution was kept in a refrigerator in dark. More dilute solutions were prepared by serial dilution phosphate buffer solutions. Multiwall carbon nanotubes (MWCNT), with nanotube diameters, OD = 20–30 nm, wall thickness = 1–2 nm, length = 0.5–2 m and purity of >95% was purchased from Aldrich. A series of buffer solution including H3PO4 were prepared and pHs were adjusted using NaOH (0.1 M) in the range from 1.0 to 6.0. The other reagents used were analytical reagent grade and all solutions were prepared with double distilled deionized water. All the chemicals were used without further purification.

Apparatus

IR spectrum was recorded on a FT-IR JASCO 680-PLUS spectrometer (20 spectra/sec, 16 cm-1 resolution, MCT-W detector) using KBr pellets from 4000-400 cm-1. The surface morphology of the composites was analyzed with KYKY, EM 3200 Scanning Electron Microscopy (SEM). Electrochemical measurements were performed with an SAMA500 Electroanalyser (SAMA Research Center, Iran) controlled by a personal computer. The three-electrode cell system consisted of carbon past working electrode (modified or unmodified), a saturated calomel electrode (SCE) as reference electrode and a Pt wire electrode as the auxiliary electrode. All the electrochemical experiments were carried out under a pure nitrogen atmosphere at room temperature.

Synthesis of [Cu(Cip)(phen)](NO3).4H2O

A solution of 1,10-phenantroline (49.6 mg, 0.25 mmol) was added to a suspension of sodium ciprofloxacinate (102.5 mg, 0.25 mmol). After 10 min of vigorous stirring, a solution of Cu(NO3)2.3H2O (60.5 mg, 0.25 mmol) was added. The solvent used was a mixture of MeOH: H2O (1:1) and the final volume was 50 mL. The pH was adjusted to 7.84 with 1 M NaOH. The solution was irradiated by sonochemical with the power of 60 W and temperature 50 °C for 30 min. The obtained precipitates were filtered, subsequently washed with water and then dried. The elemental analysis and IR spectra of the nano-structure produced by the sonochemical method as well as the bulk material produced by literature [43]. Anal. Calc. for C29H33N6O10FCu: C, 49.15%; H, 4.66%; N, 11.86%. Found: C, 48.67%, H, 4.73%; N, 11.79%, Cu, 8.81%. IR (KBr): ν(O–H and N–H) = 3600-2300 cm-1; ν(C=O) = 1730 cm-1; ν(C=N) = 1610 cm-1; ν(arC–C) = 1514 cm-1.

Fig. 1 shows representative SEM image of [Cu(Cip)(phen)](NO3).4H2O nanoparticles. Sphere-like [Cu(Cip)(phen)](NO3).4H2O nanoparticles with a size of ~50 nm were directly synthesized by ultrasonic method. The SEM image shows that there are some small holes inside the product, which indicate that it can be used in catalysis.

Please insert Fig.1.

Preparation of the modified electrode

 Modified electrode was mad by hand mixing of CU complex, graphite powder and MWCNT (1.0, 89 and 10 percent respectively) with a mortar and pestle. Paraffin (Dc 350, Merck) was added to the above mixture using a 5mL syringe and mixed for 20min until a uniformly wetted paste was obtained. The paste was then packed into the end of a glass tube (ca. 2mm i.d. and 10 cm long). Electrical contact was made by inserting a copper wire into the glass tube at the back of the mixture. When a new surface was necessary, it was obtained by pushing an excess of paste out of the tube and polishing it on a weighing paper. The efficiency of the modified electrode for the determination of real samples was maintained for more than one week. Unmodified carbon paste was made in the same way without adding Cu complex and carbon nanotube to the mixture and was used for comparison purposes.

RESULTS AND DISCUSSION

Electrochemical properties of Cu-complex - CNTPE

Cyclic voltammograms of Cu-complex - CNTPE in PBS (pH 2) at different scan rates are shown in Fig. 2. A pair of reduction and oxidation peak at 0.178 and 0 .201 was appeared and 0.23m V potential peak separation was obtained. The corresponding plot for the anodic peak current (Ipa) and catodic peak current (Ipc) as a function of scan rate (υ) is shown as inset in Fig. 2B was linearly dependent on the scan rate (υ) over the range of 5–450mVs−1, with the regression equation Ipa (µA) = 0.0164υ + 0.9765 (correlation coefficient, r = 0.9933) and Ipc (µA) = –0.165υ – 0.9229 (correlation coefficient, r = 0.9972), indicating a surface-controlled electrode processes. From the behavior of the modified Cu-complex - CNTPE with scan rate, we can conclude that the electrode reaction was a diffusion less system and a reversible electron transfer. The peaks can be attributed to redox reaction of Cu (II) to Cu (I), assumed to be a reversible one-electron transfer:

                                                                   (1)

The influence of scan rate on the redox peak potential was also studied. Based on the results with the increase of scan rate, potential of the oxidation peak shifted positively and potential of the reduction peak shifted negatively. Laviron and coworker [44] demonstrated that the kinetic electrochemical parameters (ks and) could be derived:

Where α is the electron transfer coefficient, n is the electron transfer number, v is the scan rate, other symbols have their normal meanings. AS can be seen in Fig.2D, the Epa and Epc were linearly dependent on the logv with the regression equations of Epa = 0.0563logv + 0.1037 (V, mVs−1, R = 0.9973) and Epc =−0.0363logv − 0. 243 (V, mVs−1, R = 0.9918). Base on slope of this equations and number of electron involved n=1, α was calculated to be 0.607.

Please insert Fig. 2.

Voltammetric behaviors of UA 

  Electrochemical behaviors of the UA (200 µM) in 0.1M PBS of pH 2 were carefully investigated at the surfaces of bare CPE, Cu-complex- CPE and Cu-complex- CNTPE using cyclic voltammetriy. CPE electrodes showed a weak and broad oxidation peak for a UA at 0.608V (see Fig. 3) suggesting slow electron transfer kinetics. In contrast when Cu-complex -CPE was applied well defined sharp peak appeared. As is shown, the oxidation peak for UA at the Cu-complex -CPE is several times larger than unmodified electrode. This increase is due to catalytic effect of Cu complex. At last, when carbon nanotubes added to electrode composite, the peak showed an increase because of large specific surface area and high electrical conductivity of carbon nanotubes. It was also noted that the reduction current responses for the oxidation product of UA on the three type electrodes were all negligible, which indicated that the electrochemical redox of UA at these electrodes was irreversible. 

Please insert Fig. 3.

Effect pH on the oxidation of UA

The acidity of electrolyte has a significant influence on the UA electrooxidation because protons take part in the electrode reaction. The effect of pH on  Cu-complex - CNTPE signal were carefully investigated by cyclic voltammetry using 0.1 mol L−1 buffer solutions at pH levels ranging from 1 to 6. The results were shown in Fig. 4A. Based on the results, the peak current UA increase slightly with an increase in the solution pH until it reaches 2 and then decrease. It can be seen from Fig. 4B that the highest peak current was obtained at pH 2. It was observed that as pH of the medium was gradually increased, peak potentials for the oxidation of UA shifted towards less positive values, showing that protons have taken part in their electrode processes. Out of these, phosphate buffer solution with pH 2 gave the best response in terms of peak current and peak shape and negatively shifts, hence was chosen as optimal pH for further studies. Plot of Ep vs. pH for UA in the working pH range was shown in Fig. 4C. As can be seen, the Ep of UA has linear relationship with pH of the buffer solution regarding following equations:

UA: Ep (V) = 0.0567 − 0.7321pH (R2 = 0.9991) (5)

Regarding the observed slopes of 0.0567 mV/pH for UA which was close to the anticipated Nernstian value for a two-electron, two-proton electrochemical reaction [28]. It can be concluded that equal number of electrons and protons are involved in the electrode reactions.

Please insert Fig. 4.

Influence of scan rate on the electrochemical behavior of UA

The influence of scan rate on the oxidation peak current of UA was investigated on Cu-complex - CNTPE by cyclic voltammetry. As can be seen in Fig. 5 A, the peak current intensity increases continuously with the increase of scan rate. Furthermore, the current was directly proportional to the square root of the scan rate over the range of 10–1000 mV s−1 as shown in Fig. 5B, which powerfully proposed that the redox reactions of UA are diffusion controlled. The influence of scan rate on the redox peak potential was also studied. Based on the results with the increase of scan rate, potential of the oxidation peak shifted positively .Laviron and coworker demonstrated that the kinetic electrochemical parameter (α) could be derived.

The relationship between the anodic peak potential (Epa) and logarithm of the scan rate (log) for UA was also constructed and followed the linear regression equation of Epa (V) = 0.0589logv (mVs−1) + 0.47 (R = 0.9902) in the range from 75 to 1000 mVs−1. For a completely irreversible electrode process, the relationship between Epa and logv is expressed as follows by Laviron:

 Because the electron number involved in the oxidation process is 2, α was calculated to be 0.498.

Please insert Fig. 5.

Chronoamperometric study

Chronoamperometric measurements of UA at Cu-complex - CNTPE were also studied by setting the working electrode potential at 0.65 V vs. SCE for the various concentration of UA in PBS (pH 2) (Chronoamperogram for UA was shown in Fig. 6). For an electroactive with a diffusion coefficient of D, the current for the electrochemical reaction with a mass transport limited rate is described by the Cottrell equation [45].

                                                                                (8)

 For example, under diffusion control, a plot of I vs. t−1/2 will be linear, and the slope of the linear region of the Cottrell’s plot can be used to estimate of the D for UA. The value of DUA was found to be 4.1 ×10−5 cm2 s−1.

Please insert Fig. 6.

Determination of UA

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Table 1. Determination of UA in human serum and urine samples using Cu-complex-CNTPE (n = 5).

a Mean±standard deviation for n = 5.

b Not detect

Table 2. Comparison the proposed method with other electroanalytical methods with Cu-complex-CNTPE electrodes for determination of UA.

a Room temperature ionic liquid/nickel hexacyanoferarrate nanoparticles composite paraffin wax impregnated graphite electrode graphite electrode.

b Holmium fluoride nanoparticles/multi-walled carbon nanotube

Legends for the Figures:

Fig. 1. SEM image of [Cu(Cip)(phen)](NO3).4H2O nanoparticles.

Fig. 2. (a) CVs of Cu-complex-CNTPE electrode in pH (2) at various scan rates (from inner to outer curve): 5, 15, 25, 50, 75, 100, 150, 200, 250, 300, 350, 400 and 450 mV s−1. (b) The plot of peak currents vs. scan rates.

Fig. 3. (a) CV at BCPE, (b) Cu-complex-CPE (c) Cu-complex-CNTPE electrodes in the presence of UA (250.0 µM), (d) and (e) as (c) and (a) in absence of UA in PBS (0.1 M) at pH 2.0. Scan rate: 50 mV s−1.

Fig. 4. (a) Effect of pH on the peak separation and peak current for the oxidation of UA (250 µM); pH= 1.0 – 6.0. Scan rate, 50 mVs−1. (b) Plot of peak currents vs. pH. (c) Plot of peak potential vs. pH.

Fig. 5. (a) CVs of UA (50µM) at Cu-complex-CNTPE electrode in pH (2) at various scan rates (from inner to outer curve): 10, 20, 30, 40, 50, 75, 100, 150, 200, 300, 400, 500, 600,800 and 1000 mV s−1. (b) The plot of peak currents vs. scan rates, (C)plot of peak potential vs. scan rates.

Fig. 6. (a) Chronoamperograms obtained at Cu-complex-CNTPE in 0.1 M PBS (pH 2.0) for different concentration of UA. The numbers 1–5 correspond to:s 0.0, 0.05, 0.1, 0.3 and 0.5 mM of EP. Insets: (c) Plots of I vs. t−1/2 obtained from chronoamperograms 1–5. (b) Plot of the slope of the straight lines against UA concentration.

Fig. 7. (A) CV of UA at the Cu-complex- CNTPE electrode in phosphate buffer solution (pH 2.0) at the scan rate of 50 mV s−1. Concentrations from inner to outer of curves: UA (0.0, 0.66, 1.66, 3.33,6.66, 13.3, 20.0, 26.6, 33.3, 461.6, 50.0, 58.3, 66.6, 75.0 ,83.3, 91.6, 100.0, 116.6, 141.6, 166.6, 191.6, 216.6, 250, 283.3, 316.6 and 350). Insets: (B) Plots of I vs. Concentrations.