Development of an electrochemical sensor for the determina-tion of the total antioxidant capacity in berries based on boron doped diamond


doi: 10.5599/jese.2012.0024 1 

J. Electrochem. Sci. Eng. 3(1) (2013) 1-9; doi: 10.5599/jese.2012.0024 

 
Open Access : : ISSN 1847-9286 

www.jESE-online.org  

Original scientific paper 

Development of an electrochemical sensor for the determina-
tion of the total antioxidant capacity in berries based on boron 
doped diamond 

BRUNA PEKEC*
,
***, BIRGIT FEKETEFÖLDI**, VOLKER RIBITSCH**, ASTRID 

ORTNER*** and KURT KALCHER* 

*Institute of Chemistry, Department of Analytical Chemistry, Karl-Franzens University, Graz, Austria 

**Joanneum Research Forschungsgesellschaft mbH - Materials, Weiz, Austria 

***Institute of Pharmaceutical Science, Department of Pharmaceutical Chemistry, Karl-Franzens 
University, Graz, Austria 

Corresponding Author: E-mail: kurt.kalcher@uni-graz.at, Stremayrgasse 16/III, 8010; Tel.: +43 (0)316 380 - 
5310; 5313; Fax: +43 (0)316 380-9845 

Received: August 28, 2012; Revised: October 18, 2012; Published: November 06, 2012  
 

Abstract 
Many antioxidants can be electrochemically oxidized using graphite-based electrodes; 
nevertheless problems arise due to the strong adsorption of redox species at the sensing area. 
We have demonstrated that boron doped diamond (BDD) electrodes do not show this property, 
which can be exploited for the design of a new amperometric sensor for the quantification of 
antioxidants as “total antioxidant capacity” (AOC). As reference substances hydroquinone (HQ) 
and 6-hydroxy-2,5,7,8-tetramethylchromane-2-carboxylic acid (Trolox) were studied in more 
detail. The supporting electrolyte was a phosphate buffer solution (PBS, 0.1 mol/L, pH 7.0). The 
limits of detection (LOD) were 1.5 mg/L and 2.5 mg/L for HQ and Trolox, respectively. The 
repeatability was 3 % RSD for concentration of 200 mg/L HQ. The method could be applied for 
the determination of AOC in different berry samples, such as strawberry, blueberry, grape and 
bramble. A comparison with a standard photometric assay showed good correlation between 
both methods. The BDD sensor features good reproducibility without fatiguing over at least two 
months of operation. 

Keywords  
Boron doped diamond electrode; total antioxidant capacity; amperometric sensor; berry 
extracts. 

http://www.jese-online.org/
mailto:kurt.kalcher@uni-graz.at


J. Electrochem. Sci. Eng. 3(1) (2013) 1-9 SENSOR TOTAL ANTIOXIDANT CAPACITY 

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Introduction 

The term “antioxidant” identifies a huge number of substances, in majority of cases phenolic or 

polyphenolic substances that inhibit the oxidation of molecules. They are strongly reducing agents 

that neutralize reactive oxygen species (ROS). These ROS are oxidizing radicals or molecules that 

are formed during the respiratory chain and cause damage on cell own material. Antioxidants 

neutralize these species and therefore they are of enormous scientific interest. 

The free scavenger effect of antioxidants has been in use for many years to prolong the stability 

of lipid foods especially of edible oils. Reports go back to 1947 where butylated hydroxyanisole 

was used as the first antioxidant for the prevention of the deterioration of fat-containing  

food [1-2]. Nowadays antioxidants are also in the medicinal focus because of their tissue 

protecting effects by neutralization of ROS. Therapeutic progress has been made with many 

diseases that show a high degeneration rate, such are diabetes, coronary heart failure or 

Alzheimer disease [3-5]. Ever since in 2003 Sinclair et al. found out that resveratrol, an antioxidant 

occurring in grape, extends the lifespan of yeast cells and causes a decrease of typical aging 

effects, antioxidants became also interesting for cosmetic branches and for anti-aging research [6-

7].  

Antioxidants are mostly secondary plant metabolites. Especially berries, such as grape, red or 

black currant, bramble or raspberries, are known to form high amounts of flavonoids. Their 

synthesis is a response of the plant to stress attacks like strong light exposure or fungal or 

microbial infection. In the latter case, the plant uses them as phytoalexines for tissue protection. 

Unfortunately, isolated antioxidants are highly sensitive to light, temperature and oxygen. 

Although natural antioxidants are an interesting tool to prevent lipid products, e.g. oily food or 

cosmetics, to become rancid, their stabilization is still a problem to be solved. 

Responding to a growing interest some analytical methods, mostly photometric assays, were 

developed. Standardized techniques are the ORAC-assay (oxygen radical absorbance capacity) 

involving hydrogen transfer reactions, the Folin-Ciocalteu-assay and the TEAC-assay (Trolox 

equivalent antioxidant capacity) that base on electron transfer reactions [8]. Although these 

methods have been well approved they are rather complex, time-consuming and use high priced 

chemicals or test kits. 

Most antioxidants show electrochemical activity and could be determined using voltammetric 

or amperometric methods. Unfortunately, during the electrochemical process reduced and 

oxidized species adsorb very strongly on the surface of many electrode types, such as graphite or 

carbon paste electrodes (CPE).  

Diamond electrodes offer an alternative approach. Ever since in 1987 Pleskov et al. [9] 

commenced studies on the electrochemistry of boron doped diamond (BDD) their development 

and fundamental research gained rising tendency. In contrast to graphite electrodes the C-sp
3 

hybridization and tetrahedral bonding of boron doped diamond electrodes (BDDE) leads to 

properties like chemical inertness, hardness, thermal conductivity and low fatigue [10]. Their main 

field of application is the treatment of wastewater [11]. The potential window of BDDEs is much 

wider (-0.75 to +2.35 V) than of graphite electrodes (-0.5 to +1 V) because neither oxygen  nor 

hydrogen evolution  interfere in the analysis. Because commercial BDDEs are usually synthesized 

by chemical vapor deposition (CVD) they contain non-diamond and metallic impurities [10]. Also, 

surface oxygen can cause disturbances and it needs to be removed. For surface cleaning and 

pretreatment of BDDEs a few suggestions, like acid washing or anodic polarization, have been 

offered [12,13].   



B. Pekec et al. J. Electrochem. Sci. Eng. 3(1) (2013) 1-9 

doi: 10.5599/jese.2012.0024 3 

In this work the pretreatment of boron doped diamond electrodes by polarization in Na2SO4 at 

+1 V, and the use of this electrode for the electrochemical determination of antioxidants in 

ethanolic berry extract, was investigated.  

Experimental  
Chemicals and materials  

The investigated target analytes were phenolic and polyphenolic ingredients of different berries 

(grape, bramble, blueberry, strawberry) that are known to show antioxidative potential [14]. 

Therefore ferulic acid, vanillic acid, syringic acid, coumaric acid, sinapic acid, caffeic acid and p-

hydroxybenzoic acid, all purchased from Sigma-Aldrich GmbH (Vienna, Austria), were selected. 

Trolox [(±)-6-Hydroxy-2,5,7,8-tetramethylchromane-2-carboxylic acid] and hydroquinone (HQ) 

were chosen as reference substances and were purchased, like all other standards, from Sigma-

Aldrich GmbH (Vienna, Austria). To prepare the standard solutions the appropriate amount of 

substance was dissolved in deionized water. The aqueous solutions were prepared freshly before 

use, kept cool and protected from light. Phosphate buffer (Na2HPO4/NaH2PO4 0.1 mol/L, pH 7) was 

selected as electrolyte medium.  

Apparatus 

All electrochemical experiments were performed using potentiostat (Metrohm AUTOLAB
® 

PGstat302N) in a three electrode arrangement controlled by the corresponding software 

(NOVA 1.6). The BDDEs purchased from Fraunhofer (Michigan, USA), plated on titanium substrate 

with gold as a contact, a saturated calomel electrode (SCE) and a platinum wire were used as 

working, reference and auxiliary electrode respectively. All potential values in this work are given 

against SCE. 

Cyclic voltammetry and hydrodynamic amperometry were chosen as techniques to obtain the 

electrochemical data. In the case of cyclic voltammetry the explored potential window was 

between -1 V and +1.2 V. The other operating parameters were: scan rate: 50.0 mV/s, step 

potential: 2.0 mV and time interval: 0.050 s. For hydrodynamic amperometry measurements the 

characteristic potential of the oxidation current peak was selected.   

Measuring procedure  

The BDDE was conditioned at +1 V for 1 h in 0.1 mol/L Na2SO4 solution prior to the start and 

also between the measurements to remove impurities and for the baseline correction.  

All experiments were carried out in 20 mL phosphate buffer (0.1 M, pH 7) after degassing with 

argon. Aliquots of the standard solutions were added to the cell and cyclic voltammograms and 

hydrodynamic amperograms, respectively, were recorded by applying the aforementioned 

parameters.  

Photometric analysis 

The photometric Trolox Equivalent Antioxidant Capacity assay (TEAC-Assay) was selected as a 

reference method. According to the report of Li et al. [15] the redox indicator 2,2´-Azinobis-(3-et-

hylbenzthiazolin-6-sulfonic acid) (ABTS) forms a radical in contact with potassium persulfate. The 

ABTS radical cation is of green color which decreases in intensity upon addition of substances with 

antioxidative potential. The solution was diluted using phosphate buffer saline (pH = 7) until it 

showed an absorption of 0.700 ± 0.050 at 734 nm. To 3 mL of that solution 100 µL of the sample 

were added and the absorption decrease was measured. For the calibration Trolox and HQ 



J. Electrochem. Sci. Eng. 3(1) (2013) 1-9 SENSOR TOTAL ANTIOXIDANT CAPACITY 

4  

solutions of 0.1, 0.2, 0.3 and 0.4 mol/L were used and the AOC of the berry samples was calculated 

as Trolox- or hydroquinone-equivalent (TE, HQE). 

Preparation of the samples  

The berry marcs (donated from Grünewald Fruchtsaft GmbH) were dried at 50 °C. For the 

recovery of the phenolic compounds the milled raw material was extracted with a mixture of 

absolute ethanol and water (75:25 v/v) at a 8:1  solvent-to-sample ratio (volume to mass of oven-

dried marc). The extraction was performed using sonication at a temperature of 50 °C for 15 min. 

After centrifugation (7000 rpm, 20 min) the extract was then filtered through a glass fiber filter 

(type AP2029325, Millipore) and stored at 4 °C.  

Results and Discussion 

Cyclic voltammetry  

Cyclic voltammetry (CV) was basically used to determine the oxidation potential of the standard 

berry antioxidants with CPEs and BDDEs (Table 1). The quoted potentials correspond to the 

maximum of the oxidation current registered in the anodic scan. Typical CVs of hydroquinone and 

Trolox are shown in Fig. 1. As can be seen the electrochemical behavior of both substances on 

both electrodes is rather similar with the exception of carbon paste electrode where the currents 

are significantly higher. This behavior is due to the adsorption of the analyte at CPE and therefore 

due to the strong  electron interaction of the aromatic ring with the graphite structure. Both 

substances were used as reference compounds, by converting the response of other antioxidants 

to Trolox- (TE) and hydroquinone-equivalents (HQE), respectively. 
 

Figure 1. Cyclic voltammograms of 30 mg/L (a) Trolox and (b) HQ measured in PBS (0.1 mol/L, pH 7)  
on• BDDE and • CPE. 

The investigated antioxidants (Table 1) produce typical peak currents in CV at BDDEs in the 

range of 4 to 8 mA mol
-1

 with the exception of HQ which is about four times higher; probably 

because HQ ideally interacts with the graphite surface finally yielding benzoquinone, whereas 

a b 

  



B. Pekec et al. J. Electrochem. Sci. Eng. 3(1) (2013) 1-9 

doi: 10.5599/jese.2012.0024 5 

other oxidants are reduced to the corresponding R-O radical with ensuing follow-up effects. Again 

it  is evident  that carbon paste electrode favors adsorption of the oxidation product which exerts 

a positive effect for the first cycle in cyclic voltammetry but it is deteriorating the signals in further 

scans and in amperometry (see below) by blocking the active surface area.  

Since the sensors based on boron-doped diamond should be used for alcoholic extracts of 

berries, the influence of ethanol on the signal was investigated. Concentrations from 0.5 to 20 % 

ethanol were added to the supporting electrolyte; no influence on peak position or peak height 

was observed.  

Table 1. Oxidation potentials, Epa, and peak currents, ipa, from cyclic voltammetry of typical antioxidants 
found in berries. Concentration: 30, respectively 90 mg/L, supporting electrolyte: PBS (0.1 mol/L, pH 7); 

potential window: -1.5 to +1.5 V, scan rate: 50 mV/s. 

Substance Formula 
CPE BDDE 

Epa / V ipa / mA mol
-1

 Epa / V ipa / mA mol
-1

 

Syringic acid 

 

0.95 23.3 0.80 8.2 

Sinapic acid 

 

0.70 15.2 0.65 4.3 

Caffeic acid 

 

0.48 10.2 0.50 7.5 

Vanillic acid 

 

0.88 78.6 0.88 4.9 

Ferulic acid 

 

0.50 19.2 0.50 7.9 

Coumaric acid 

 

0.90 37.5 0.75 5.1 

p-Hydroxybenzoic acid 

 

0.90 148.5 1.0 6.9 

Trolox 

 

0.50 14.2 0.50 6.2 

Ascorbic acid 

 

 

0.61 56.4 0.54 36.4 

Hydroquinone 

 

0.50 44.0 0.50 26.7 

http://www.google.at/imgres?q=trolox&um=1&hl=de&sa=N&biw=1024&bih=743&tbm=isch&tbnid=KOOH3AGe4ddOdM:&imgrefurl=http://www.lookchem.com/Trolox-C/&docid=Fgka14GbpzMrdM&imgurl=http://www.lookchem.com/300w/casimage/2011-01-08-16/56305-04-5.gif&w=300&h=300&ei=mS29TqRIhamyBqii3JYD&zoom=1
http://www.labspaces.net/101359/New_year__new_vitamin_C_discovery__It__cures__mice_with_accelerated_aging_disease
http://www.google.at/imgres?q=hydroquinon&um=1&hl=de&sa=X&biw=1024&bih=743&tbm=isch&tbnid=fOISxc8DzfZt0M:&imgrefurl=http://dorisdalton.blogspot.com/2009/07/snow-white-and-her-seven-whitening.html&docid=LjD6ZLE81MOwqM&imgurl=http://2.bp.blogspot.com/_Kyhgz5nbXzk/Sl9sWhPmziI/AAAAAAAAAK4/-48TAoqdlG0/s320/hyroquinone.png&w=300&h=300&ei=Qi69TuK9JMr1sgbRqMGaAw&zoom=1


J. Electrochem. Sci. Eng. 3(1) (2013) 1-9 SENSOR TOTAL ANTIOXIDANT CAPACITY 

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Hydrodynamic amperometry  

Basic studies 

Hydrodynamic amperometry was applied to the antioxidants listed in Table 1 applying a 

working potential which corresponds to the maximum of the oxidation current in CV. After 

attaining a stable baseline the analytes were added to a stirred solution.  

Figure 2 shows a comparison of the electrochemical behavior of HQ between BDDE (a) and 

CPE (b) electrodes under identical conditions. As can be seen a strong adsorption of the quinone 

on the CPE leads to a fast decrease of the signal due to blocking of the active electrode surface 

area with a very small current steps after ensuing additions. BDDE does not show any obvious 

adsorption therefore, after addition of the electrochemically active analyte, the signal remains 

constant. Repetitive additions lead to clear step-like increases of current. For this reason BDDE 

seems to be an ideal electrode material for the determination of phenolic antioxidants due to the 

absent tendency for adsorption.  

 
a b 

  

Figure 2. Hydrodynamic amperograms of subsequent additions of 30 mg/L HQ in phosphate buffer (0.1 M, 
pH 7) using (a) BDDE and (b) CPE. Working potential: +1V. 

Validation of analytical parameters 

The analytical method based on hydrodynamic amperometry was evaluated with hydroquinone 

and Trolox as standards. Under optimized conditions the linearity range of the BDD-sensor was 

estimated to be between 10 and 400 mg/L for Trolox and 10 to 300 mg/L for HQ (Fig. 3). The 

calibration curves can be described by the following regression equations: 

 i HYDROQUINONE / µA = 43.04 × γ / (mg/L) + 0.387  and  

iTROLOX / µA= 22.09 × γ / (mg/L) + 0.609,  

both with a mean correlation coefficient of R = 0.999.  For the concentrations above 400 mg/L 

(Trolox) and 300 mg/L (HQ) the calibration graph levels off but still remains linear to 

concentrations above 1 g/L, in fact with a very small sensitivity. The limit of detection (LOD) and 

the limit  of quantification (LOQ estimated as the three-fold of LOD) were determined as 1.5 mg/L 

and 4.5 mg/L for HQ, and 2.5 mg/L and 7.5 mg/L for Trolox according to the International 

Conference on Harmonisation, ICH, Quality Guidelines for Analytical Evaluation [Q2(R1)] guidelines 

for visual evaluation [16]. 



B. Pekec et al. J. Electrochem. Sci. Eng. 3(1) (2013) 1-9 

doi: 10.5599/jese.2012.0024 7 

The precision experiments (100, 200, 375, 625, 750 and 875 mg/L; n = 4) showed a relative 

standard deviation (RSD) of 3-8 % and a RSD of the slope of 3 %. The intercept of the calibration 

curves ranged from around 0.4 (HQ) to 0.6 µA (Trolox) with a RSD of about 5 % in different 

calibrations (n = 4). 

 

 

Figure 3. Calibration curve of the BDD-sensor 10-1200 mg/L concentration range of • HQ and • Trolox. 

Application of the sensor in samples 

After it was demonstrated that the BDDEs showed only insignificant adsorption effects to the 

redox products of the investigated antioxidants they were applied to chosen samples. Thus, 

ethanolic extracts were prepared using red grape, bramble, blueberry and strawberry. The 

extracts  were injected directly to the analytical cell without further dissolution or preparation. 20 

mL of phosphate bufferwas transferred into the electrochemical cell and after the baseline 

stabilization, 100 µL of the extract was injected. The extracts were analyzed using hydrodynamic 

amperometry at +1 V and the AOC was estimated as Trolox equivalent (TE) or hydroquinone 

equivalent (HQE) using the corresponding calibration curves. The capacities of the berry samples 

were determined in the range of 8 and 23 mM TE/HQE (Table 2) and are in a good agreement with 

the results of the photometric reference method.  
 

Table 2. Comparison of the electrochemical and photometric total antioxidant  
capacity measurements of berry extracts. 

 Trolox equivalent, mmol/L Hydroquinone equivalent,  mmol/L 

TEAC Assay Electrochemical BDD sensor TEAC Assay  Electrochemical BDD sensor  

Grape 23.4 ± 1.2 23.9 ± 1.2 22.6 ± 1.1 23.3 ± 1.2 

Bramble 12.4 ± 0.6 12.4 ± 0.6 12.1 ± 0.6 13.4 ± 0.7 

Blueberry 18.5 ± 0.9 18.1 ± 0.9 18.4 ± 0.9 17.9 ± 0.8 

Strawberry 8.9 ± 0.4 8.9 ± 0.4 8.8 ± 0.4 9.1 ± 0.5 

 

Figure 4 shows a comparison between electrochemical signals determined using the BDD 

sensor and the decrease of absorption (ΔA) measured using the TEAC-Assay. It can be seen clearly 

that there is a directly proportional relation between the absorption signal decrease and 



J. Electrochem. Sci. Eng. 3(1) (2013) 1-9 SENSOR TOTAL ANTIOXIDANT CAPACITY 

8  

amperometric currents. The method employing electrochemical sensors seems well applicable to 

detect the antioxidant capacity of ethanolic berry extracts. 

 

Figure 4. Comparison of electrochemical data recorded in current intensity  
and photometric results charted as decrease of absorption. 

Our studies show that the evaluated Trolox and hydroquinone equivalents from amperometric 

measurements with BDDEs are correlating well with the optical reference method (Table 2). This 

was also verified with individual antioxidants (Table 1) which produce the same antioxidant 

equivalent capacities with both procedures, amperometric and optical. 

Maybe, in complex samples, substances which can be oxidized at an operational potential of 1.0 

V could be present and do not contribute to the antioxidant capacity. In fact, we could not, so far, 

observe such a behavior with ethanolic extracts of berries. 

Conclusions 

The investigations show that boron doped diamond used as working electrode in 

electrochemical analytics is an attractive tool because of its many advantages. Due to its low 

feature for the adsorption of redox products it can be used for quantification of antioxidants even 

in complex material. The designed sensor is inexpensive because it can be used for repetitive 

measurements, easy to prepare,  and with high reproducibility .   
 

Acknowledgements: The financial support of the Österreichische Forschungsförderungsgesel-

lschaft (FFG) for project “Antiflavo” (No.827334) is highly acknowledged.  

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