Determination of H2O2 in Human Serum Samples with Novel Electrochemical Sensor Based on V2O5/VO2 Nanostructures

Maryam Fayazi

doi:10.5812/amh.96175

Determination of H₂O₂ in Human Serum Samples with Novel Electrochemical Sensor Based on V₂O₅/VO₂ Nanostructures

authors:

Maryam Fayazi ^{1
, *}

1 Department of Environment, Institute of Science and High Technology and Environmental Sciences, Graduate University of Advanced Technology, Kerman, Iran

Annals of Military and Health Sciences Research: Vol.17, issue 3; e96175

published online: September 2, 2019

article type: Research Article

received: July 9, 2019

revised: August 1, 2019

accepted: August 8, 2019

DOI: https://doi.org/10.5812/amh.96175

how to cite: Fayazi M. Determination of H₂O₂ in Human Serum Samples with Novel Electrochemical Sensor Based on V₂O₅/VO₂ Nanostructures. Ann Mil Health Sci Res. 2019;17(3):e96175. https://doi.org/10.5812/amh.96175.

Abstract

Background:

Highly selective and sensitive analysis of hydrogen peroxide (H₂O₂) has attracted considerable interest in the fields of clinical diagnostics, food industry, and environmental analysis.

Objectives:

In the present study, an efficient electrochemical sensor, based on V₂O₅/VO₂ nanostructures, was introduced for measuring hydrogen peroxide (H₂O₂) in human serum samples.

Methods:

The characterization of the prepared V₂O₅/VO₂ nanostructures was investigated by X-ray diffraction (XRD), Fourier transform infrared (FT-IR) spectroscopy, scanning electron microscopy (SEM), and energy dispersive X-ray spectroscopy (EDX). A carbon paste electrode (CPE) modified with V₂O₅/VO₂ was applied for the electrochemical detection of H₂O₂.

Results:

The prepared sensor depicted a good linear range from 8 to 215 μM and a low detection limit of 5 μM. Moreover, the modified electrode showed notable anti-interference property and high sensitivity toward H₂O₂ detection. The suggested method was also successfully applied for the determination of H₂O₂ in human serum samples.

Conclusions:

The V₂O₅/VO₂ embedded CPE offers good simplicity, sensitivity, and selectivity toward H₂O₂ determination. In addition, the suggested assay revealed good reproducibility and anti-interference property in the measuring of H₂O₂.

Keywords

Hydrogen Peroxide Electrochemical Sensor Vanadium Oxide Human Serum

1. Background

H₂O₂ plays a prominent role in different areas including clinical diagnostics, food industry, pharmaceutical, and environmental protection (1). An excessive accumulation of H₂O₂ in the human body can lead to some diseases such as DNA fragmentation and tissue damage (2). Consequently, the accurate measuring of H₂O₂ in biological samples is very important. To date, various analytical methods have been developed for determination of H₂O₂, including chromatography (3), spectrophotometry (4), and chemiluminescence (5). However, above mentioned techniques are high costs, complex, and time-consuming.

Electrochemical H₂O₂ sensing has attracted growing attention due to the intrinsic advantages such as simple operation, cost effective, rapid response, and suitability for real-time H₂O₂ analysis (6). In view of this, the design and fabrication of novel electrochemical sensors for H₂O₂ determination has attracted considerable interest in recent years (7, 8).

2. Objectives

In this study, novel V₂O₅/VO₂ nanostructures were successfully prepared with the hydrothermal method. The V₂O₅/VO₂ nanostructures were utilized for modification of a simple and cheap carbon paste electrode (CPE). The main experimental factors, calibration range, and detection limit of the V₂O₅/VO₂-CPE was also explored in detail. Moreover, the proposed sensor was applied for quantification of H₂O₂ in human serum samples.

3. Methods

3.1. Materials and Apparatus

All materials including thiourea, vanadium chloride (VCl₃), ethanol, ethylene glycol, paraffin oil, graphite powder, and H₂O₂ were obtained from Merck (Darmstadt, Germany). XRD pattern was recorded via a PANalytical Empyrean X-ray diffractometer (Almelo, Netherlands). SEM image and EDX analysis were performed on a MIRA3 LM TESCAN microscope (Brno, Czech Republic). FT-IR spectrum was measured on a Bruker Equinox 55 spectrometer (Karlsruhe, Germany). All electrochemical data were recorded on a potentiostat galvanostat impedance meter (OrigaState100, OrigaLys, Rillieux-la-Pape, France). A standard electrochemical cell including the modified CPE (working electrode), the platinum wire (counter electrode), and the Ag/AgCl (3 M KCl) electrode (reference electrode) was used for electrochemical tests.

3.2. Preparation of V₂O₅/VO₂ Nanostructures

The V₂O₅/VO₂ nanostructures were synthesized via a hydrothermal approach. Typically, 7.8 g of VCl₃ was dissolved in a mixed solution of ethanol (50 mL) and ethylene glycol (25 mL) under vigorous stirring. Afterward, 7.6 g of thiourea was added to the above mixture vigorous stirring. The mixture was transferred into a 100 mL Teflon-lined stainless-steel autoclave and then heated at 160ºC for 12 h. The black precipitates were collected via centrifuge separation, followed by repeated washing with ethanol, and then heated at 350ºC for 3 h under air condition.

3.3. Electrode Fabrication

The modified CPE (V₂O₅/VO₂-CPE) was fabricated by mixing of graphite powder (65% w/w), V₂O₅/VO₂ (10% w/w), and paraffin oil (25% w/w). Then, a portion of the obtained paste was packed into a glass tube (3 mm in diameter) in contact with a copper wire for electrical connection.

4. Results

The FT-IR spectrum of the V₂O₅/VO₂ nanostructures is presented in Figure 1. Absorption peak appearing at 1013 cm^-1 is attributed to the stretching vibrations of V=O groups (9). The peaks at 529 and 828 cm^-1 are related to the symmetric and asymmetric stretching of the V−O−V groups, respectively (10). The peak at 620 cm^-1 can also be assigned to the stretching of the V−O groups (11).

Figure 1.

FT-IR spectrum of V2O5/VO2 material

XRD pattern of the V₂O₅/VO₂ nanostructures is shown in Figure 2. The observed characteristic reflections were matched well with the standard XRD data of V₂O₅ (vanadium pentoxide; JCPDS No 76-1803) and VO₂ (vanadium dioxide; JCPDS No 73-2362) (12).

Figure 2.

XRD pattern of V2O5/VO2 nanostructures

The SEM photograph of the V₂O₅/VO₂ nanostructures is shown in Figure 3A. As can be seen, the prepared V₂O₅/VO₂ product has a nano-sized structure. Moreover, the EDX spectrum of the V₂O₅/VO₂ nanostructures (Figure 3B) shows the existence of vanadium and oxygen elements in the prepared material. According to these results, the V₂O₅/VO₂ nanostructures have been successfully prepared by hydrothermal method.

Figure 3.

A, SEM image and B, EDX spectrum of V2O5/VO2 nanostructures

5. Discussion

The ability of the V₂O₅/VO₂ nanostructures for electrochemical reduction of H₂O₂ was investigated. Figure 4 displays the cyclic voltammograms of unmodified CPE and V₂O₅/VO₂-CPE in phosphate buffer (0.1 M, pH = 7) containing 100 μM of H₂O₂. As can be seen, the V₂O₅/VO₂-CPE shows a notable reduction peak current, indicating that the reduction of H₂O₂ was improved compared to unmodified CPE.

Figure 4.

Cyclic voltammograms of the unmodified CPE and the V2O5/VO2-CPE in phosphate buffer (0.1 M, pH = 7) containing 100 µM of H2O2 with scan rate of 50 mV s-1

To improve the sensitivity of the V₂O₅/VO₂-CPE toward H₂O₂ detection, amperometry method was used at applied potential of -450 mV. The amperometric responses of the V₂O₅/VO₂-CPE to the successive addition of H₂O₂ were studied as shown in Figure 5. The amperometric signal currents vary linearly with H₂O₂ concentration over the range of 8 to 215 μM with a detection limit (3σ) of 5 μM. The detection limit of the prepared sensor is lower than some reported H₂O₂ sensors (13-17), as listed in Table 1. The effect of some interfering species including glucose, uric acid, dopamine, and ascorbic acid was also investigated. The experimental results (Table 2) show that the prepared V₂O₅/VO₂-CPE can measure H₂O₂ with recoveries more than 95% in the presence of such interfering molecules.

Figure 5.

Amperometric responses of V2O5/VO2-CPE to successive addition of H2O2 at the potential of -0.45 V in 0.1 M buffer solution (pH = 7.0). Inset: Calibration curve of sensor.

Table 1.

Comparison of Some Different Electrochemical Sensors for Determination of H₂O₂

Electrode Modifier*	Linear Range, µM	Detection Limit, µM	Ref.
Cuprous oxide-reduced graphene oxide (Cu₂O-rGO) nanocomposites	30 - 12800	21.7	(13)
Poly (p-aminobenzene sulfonic acid) (PABS)	50 - 550	10	(14)
Magnetite (Fe₃O₄) nanoparticles	25 - 5000	7.4	(15)
Hematite (α-Fe₂O₃) nanoparticles	50 - 3145	22	(16)
Iodide	10 - 60000	10	(17)
V₂O₅/VO₂ nanostructures	8 - 215	5	This work

Table 2.

The Effect of Interfering Species

Co-existing Molecule	Recovery, %
Glucose	96.7
Uric acid	98.5
Dopamine	98.3
Ascorbic acid	96.9

The suggested V₂O₅/VO₂-CPE was validated for the H₂O₂ quantification in biological samples. Human serum samples were collected from a local hospital in Kerman. Standard addition protocol was used in the recovery experiments and the obtained results are listed in Table 3.

Table 3.

Determination of H₂O₂ in Human Serum Samples (n = 3).

Sample	Added, µM	Found, µM	RSD	Recovery, %
Male serum
	15	14.8	4.2	98.6
	30	29.5	3.6	98.3
	45	46.3	5.0	102.8
Female serum
	15	15.6	4.5	104.0
	30	28.9	5.2	96.3
	45	44.2	3.9	98.2

5.1. Conclusions

In summary, a novel electrochemical sensor for determination of H₂O₂ was presented. The fabricated H₂O₂ sensor showed a wide linear range and low detection limit. The applicability of the V₂O₅/VO₂-CPE for quantification of H₂O₂ in biological samples was successfully investigated. The good simplicity and anti-interference performance of the present method indicates that the V₂O₅/VO₂-CPE has great potential working as an efficient H₂O₂ sensor for clinical applications.

Footnotes

Conflict of Interests: The author reports no conflicts of interest in this work.
Ethical Approval: Author will agree upon standard ethical behavior.
Funding/Support: This work is not funded by any university or company.

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