{Cyclic voltammetry: a simple method for determining contents of total and free iron ions in sodium ferric gluconate complex}


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J. Electrochem. Sci. Eng. 10(3) (2020) 281-291; http://dx.doi.org/10.5599/jese.749   

 
Open Access: ISSN 1847-9286 

www.jESE-online.org 
Original scientific paper 

Cyclic voltammetry: A simple method for determining contents of 
total and free iron ions in sodium ferric gluconate complex 

Hong Liu, Qiao Yu1, Yixuan Ma2, Baoyu Liu1 and Hongchun Pan1 
1College of Pharmaceutical Sciences, Southwest University, Chongqing, China 
2Affiliated Hospital of Qinghai University 

Corresponding author: lhphch@126.com; Tel.:13368261386;  

Received: November 1, 2019; Revised: April 3, 2020; Accepted: April 4, 2020 
 

Abstract 
Sodium ferric gluconate complex (SFGC) is the third generation of iron supplement of 
polysaccharide iron (III) complex (PIC). For evaluation of technological level and application 
value of the prepared SFGC, it would be of great significance to determine the iron content 
in SFGC in a simple but effective way. This paper introduces the cyclic voltammetry (CV) 
method for determination of iron content in SFGC. Under established optimal experimental 
conditions, the content of free iron ions can be directly scanned and calculated, while the 
total iron content can also be determined by completely acidifying SFGC into Fe3+ ions. After 
optimizing and screening, the optimal scanning conditions are determined as pH 3 and 
0.05 V/s of the scanning rate. Prior CV measurements, 0.4 V of the enrichment potential, 
and 3 min of the enrichment time are found optimal. It has also been verified that CO32- ions 
present in the solution show little interference in the system within the experimental range 
of investigation. The contents of free Fe3+, Fe2+ ions and the total iron determined after acid-
hydrolysis of SFGC can be accurately calculated according to the corresponding linear 
relationships between peak currents and iron concentrations. In this paper, the repeatability 
and accuracy of the method are verified, and its feasibility as a convenient and effective 
method to determine the iron supplements is confirmed. 

Keywords: Iron content; free iron ions content; iron supplements 
 

Introduction 

The iron-deficiency anemia is currently the most common type of anemia, which widely exists in 

many countries around the world, especially in the developing countries [1,2]. By inadequate iron 

intake, the synthesis of hemoglobin in human’s body will be affected, resulting in inadequate oxygen 

supply to cells and tissues [1,3]. Iron-deficiency anemia has usually been treated by iron 

supplements. Development of iron supplements is carried out through three stages, where the third 

generation, namely the macromolecular compound iron supplement, is a new type of iron complex 

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formed by ferric ions and the carrier of organic macromolecular complex [4]. Compared with 

previous two generations, the third one has higher iron content and better solubility, because iron 

in the complex does not exist as ions. Hence iron supplements of this new generation cause little 

digestive side effects and among them, the saccharide-iron complexes are under wide research work 

[5]. In addition to being the iron supplement, the saccharide itself has many biological activities, and 

is beneficial to the body by various synergistic effects after being absorbed. Therefore, the 

saccharide-iron (III) complex is a promising type of nutritional iron supplement [6,7]. 

Gluconic acid sodium salt (D-SG)(Figure 1) is used as a molecular shell to effectively adsorb the 

metal iron ions in the solution, forming a stable iron complex. The complex is called sodium ferric 

gluconate complex (SFGC), having possible structure shown in Figure 2. This iron supplement is 

highly stable and has no toxic side effects.  

 
Figure 1. Molecular structure of D-SG 

 
Figure 2. Proposed structure of SFGC 

The iron content is one of the most important indicators to analyze the complexation process 

and technological results of sodium ferric gluconate complex (SFGC) preparation [8-10]. Since less 

content of free iron ions can reduce irritation in the digestive tract, high content of complex iron 

increases a status of the product. Therefore, it is important to determine the contents of free and 

total iron in SFGC rapidly and accurately. 

So far, the determination of iron content mainly includes the methods such as potassium dichro-

mate solution titration, phenanthroline spectrophotometry, atomic absorption spectrometry, etc. 

[11,12]. However, the titration technique not only consumes plenty of time and chemicals, but also 

produces a great deal of pollutants because of the utilization of toxic potassium dichromate and 

mercuric chloride in the operation [13]. The spectrophotometry requires a pre-treated sample with a 

complicated operation and has low sensitivity and poor accuracy [14]. Although the atomic absorption 

spectrophotometry does not require a pretreatment process, the operation is simple and fast and 

accuracy is high, the equipment is expensive, and difficult to popularize [15]. The most important is 

that all above mentioned methods cannot accurately distinguish and separately determine the 

contents of free iron ions and total iron in the complex when they both exist in the system. This brings 

difficulties to evaluation of the complexation process and outcome of the iron complex system. 

Therefore, it would be of great importance to develop an accurate, rapid, convenient and cost-

efficient method for respective determinations of free iron ions and total iron in the complex. 

In this paper, a classical electrochemical research method [16,17], that is cyclic voltammetry 

technique is adopted. It allows free Fe3+ and Fe2+ ions in the sample solution to form a reversible 

redox system and generate current peaks by corresponding redox reactions. Based on these redox 

reactions, the content of free iron ions in SFGC can be determined directly, while the total iron 

content can be determined after conversion of SFGC into free Fe3+ ions by acid-hydrolysis. Acid-

hydrolysis conditions, pH, potential scanning rate and some other experimental parameters are 



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optimized in this paper, and the methodological verification is carried out in order to obtain a 

practical and efficient detection method. 

Experimental  

Reagents and materials 

D-sodium gluconate (D-SG) was purchased from Chengdu Kelong Chemical Co., Ltd., Sichuan 

Province, China. Ultrapure water (18.25 MΩ cm) was used throughout the experiment. All other 

reagents and chemicals employed in this experiment were of analytical grade. 

Apparatus 

The electrochemical measurements of cyclic voltammetry (CV) were performed with a CHI610E 

electrochemical workstation (Chenhua Co. Ltd., Shanghai, China). It contains a conventional three-

electrode system comprised of platinum as the auxiliary electrode, saturated calomel electrode as 

the reference electrode and 3-mm-diameter glassy carbon (GC) as the working electrode. The pH 

measurements were assayed with a FE20 FiveEasyTM pH meter (Mettler Toledo, Shanghai, China). 

All measurements were carried out at indoor temperature. 

Preparation of SFGC 

40 mL of 1.18 mol/L Na2CO3 solution was added to another 40 mL solution which contained 10 g 

D-SG. Afterwards, the solution containing (60 mL) 1.25 mol/L of FeCl3·6H2O was added dropwise 

under continuous stirring. The synthesis of the complex was performed at pH 11 (adjusted by adding 

5 mol/L NaOH). The mixture was heated at 100 °C at least 3 h in the oil bath, and then filtered and 

cooled to room temperature. The complex was precipitated by 0.2 L of ethanol. After 4 h of standing, 

the ethanol was decanted, and the precipitate was centrifuged at 3000 r/min for 10 min. The 

supernatant was decanted, and the precipitate was dissolved in 0.1 L redistilled water. Dialysis of 

the solution was used to remove unbound ions (Cl-, Na+, Fe3+). Finally, the complex was washed 

successively from the dialyzed solution by ethanol and acetone and dried for 3 h in vacuum after 

decantation. Thus, the sodium ferric gluconate complex (SFGC) was obtained as a black powder. 

Preparation of Fe standard solutions and acid hydrolysis of SFGC  

0.01 mol/L Fe3+ standard solution: 0.1351 g of FeCl3·6H2O was dissolved in ultrapure water, mixed 

and diluted to the required concentration (50 mL). After that, the samples of standard solution were 

diluted to different concentrations (0.009, 0.008, 0.007, 0.006, 0.005 mol/L, 50 mL).  

0.05 mol/L Fe2+ standard solution: 0.4970 g of FeCl2·12H2O was dissolved in ultrapure water, mixed 

and rapidly diluted to the required concentration (50 mL). After that, the samples of standard solution 

were diluted to different concentrations (0.045, 0.040, 0.035, 0.030, 0.025 mol/L, 50 mL). As Fe2+ ions 

are easily oxidized into Fe3+ ions, all prepared Fe2+ solutions should be used right after preparation. 

SFGC acid-hydrolysis solution: 0.2500 g of SFGC was dissolved in ultrapure water, mixed and 

diluted to 5 g/L (50 mL). Hydrochloric acid solutions (2 mL) with different concentrations (1, 3, 5, 

7 mol/L) were slowly added to 4 mL of 5 g/L SFGC solution in 25 mL beaker, respectively. After 5 min 

stirring, the solution was treated by acid-hydrolysis method for 5 min at room temperature (RT), 

water bath (20 °C) and refrigerator (4 °C), respectively. 

Test method 

To improve reproducibility and sensitivity of peak currents in CV measurements, the surface of 

the working GC electrode was polished successively with 1, 0.3, and 0.05 μm alumina powders on a 

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nylon polishing cloth to achieve the hydrophobic property, and then washed for five minutes in an 

ultrasonic bath of nitrate, ethanol and water respectively [18]. It is worth noting that the K3Fe(N)6-

KCl standard solution should be scanned for the electrode testing purpose by cyclic voltammetry, 

where the potential difference of anode and cathode peaks of 60-80 mV is the main criteria of well 

electrode working [19].  

Test solutions were deoxygenated before measurements by purging with nitrogen for 5 min. 

After that, a three-electrode was placed, and then the system was rested for 2 min. Experimental 

settings included the scan rate of 0.05 V/s, and the number of cycles was 6. Cyclic voltammograms 

were measured within the potential range of +1.0 to -1.0 V, where peak currents are recorded [20]. 

Standard calibration curves are plotted with Fe3+ or Fe2+ concentrations at the abscissa, and the 

oxidation peak currents at the ordinate axis, respectively. 

Results and discussion 

Characteristic peak scanning of free iron ions and SFGC 

SFGC has chelated iron properties, and the presence of free iron ions will reduce stability of the 

composite product [21]. Therefore, the content of free iron ions in the solution is an important 

indicator for determining the complex iron [8,9]. Standard solutions of 0.01 mol/L Fe3+ and Fe2+ were 

scanned by CV and electrochemical characteristic peaks are found consistent with those reported 

in the literature [22,23] (Figure 3a,b). However, no electrochemical response indicated by absence 

of characteristic peaks of free iron ions is observed in the scanning of 1 g/L SFGC solution (Figure 3c). 

Hence, it is indicated that there are no free iron ions, or the content of free iron ions in SFGC solution 

is lower than the detection limit. 

 
Figure 3. Characteristic peaks recorded by CV (0.05 V/s) at GC electrode in standard solutions of (a) Fe3+ 

ions, (b) Fe2+ ions, (c) SFGC. 

Determination of free iron ions in SFGC 

With CV technique, the corresponding electrochemical characteristic peaks can be obtained by 

scanning free Fe3+ and Fe2+ ions under certain conditions. In experiments, the detection conditions 

should be optimized in terms of pH, potential scanning rate, as well as enrichment potential and 

enrichment time applied prior CV measurements. Additionally, with free Fe3+ and Fe2+ ions added to 

SFGC solution in the cyclic voltammetry scanning, the signal response showed a linear relationship 



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with the added concentration, suggesting that the determination of free iron ions would not be 

affected by the chelated iron. Therefore, the content of free iron ions can be detected and calculated 

by this method. 

Optimization of detection conditions 

Determination of optimal pH 

The value of pH has important impact for the studied system. As the acidity will affect the 

hydrolysis and H+ can inhibit the hydrolysis of Fe3+ [24], keeping the system stable for a certain 

period of time for easy measurement [19]. pH was adjusted to 1, 2, 3, 4, 5 and 6 respectively, for 

cyclic voltammetry scanning (Figure 4). At pH 1­3, the peak widths and peak currents changed little, 

indicating that the electrical signal within this pH range is relatively stable, what is beneficial for 

analytical determination. Since at pH 3, the electrical signal showed the strongest response and the 

highest sensitivity, the optimal pH value was selected to 3. 
 

 
Figure 4. CV curves (0.05 V/s) of GC electrode in diluted Fe3+ solution at pH (1-6). 

Determination of optimal scanning rate 

Cyclic voltammetry curves were recorded for Fe3+ standard solution diluted multiple times, within 

the scanning potential range of +1.0 to -0.4 V, at scanning rates of 0.01 - 0.09 V/s (Figure 5). It is 

seen in Figure 5 that as the scanning rate increases, the peak current also increases. At the same 

time, the oxidation peak potential is shifted positively, but the reduction peak potential is shifted 

negatively. When the scanning rate is too low, the electrical signal is weak and the curve peak is not 

so obvious, which is not conducive to the detection of Fe3+. Nevertheless, when the scanning rate is 

too high, the electrical signal is strong, and Fe3+ characteristic peak becomes deformed. Therefore, 

the optimal scan rate is chosen to be 0.05 V/s. 

 

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Figure 5. CV curves of GC electrode in diluted Fe3+ solution (pH 3) at different scanning rates (0.01- 0.09 V/s) 

Determination of optimal accumulation potential and time  

Fe3+ standard solution was taken to investigate the effect of accumulation potential applied prior 

CV measurements on the peak current (Figure 6 A). According to the results, the peak current did 

not change with the positive shift of the potential when the accumulation potential was changed 

from 0.8 V to -0.2 V, indicating that the reduction degree of iron ions on the electrode surface is 

practically the same. Hence, 0.4 V was selected as the optimal accumulation potential. Under this 

potential, the effect of accumulation time (10-240 s) on the peak current was investigated 

(Figure 6B). CVs in Figure 6 B suggest that with the extension of accumulation time, more iron ions 

are precipitated and enrichment is more complete. At this time, Fe3+ concentration around the 

electrode increases, and the peak current also increases. 3 min later, however, the peak current did 

not change much, demonstrating that adsorption reached saturation. Therefore, 3 min were 

selected as the best accumulation time. 

 

 
Figure 6. CV curves of GC electrode in standard Fe3+ solution under (A) different accumulation potentials  

(0.8 to -0.2 V) and (B) different accumulation times (10 to 240 s) 



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Method validation 

Effect of interfering ions 

Since SFGC solution contains CO32- ions, Na2CO3 was added into 0.001 mol/L Fe3+ standard solution 

in order to simulate SFGC solution and to study effect of these ions to determination results [25]. 

Na2CO3 concentrations of 0, 0.001, 0.01 and 0.1 mol/L were added respectively in the standard 

solution of Fe3+ ions, and measured CVs are shown in Figure 7. No change or different peak is observed 

in Figure 7. By comparing the peak current values, RSD was found less than ±2 %, which suggests that 

CO32- ions do not interfere to the determination of iron ions. 
 

 
Figure 7. Influence of interfering CO32- ions on CVs of GC electrode in standard Fe3+ solution for (a) three 

different concentrations of Na2CO3, (b) Fe3+ standard solution with three different concentrations of Na2CO3 

Accuracy 

On the basis of the current experiment, Fe3+ standard solutions of 80, 100 and 120 % concen-

trations were respectively added into 1 g/L SFGC solution. After iron content was determined, the 

measured value was compared with the theoretical value to calculate the recovery rate. The results 

showed that recovery rates were 100.2, 99.8 and 98.6 %, and RSDs were 3.02, 2.06 and 2.36 %, 

respectively. The same method was repeated by adding Fe2+ standard solutions. The results showed 

that the recovery rates of those three concentrations were 99.1, 99.8 and 100.6 % and RSDs were 

1.98, 1.56 and 2.63 %, respectively. 

Stability and repeatability 

In order to investigate stability of the system and repeatability of measured data, six cyclic 

voltammetry curves in standard Fe3+ and Fe2+ solutions were repeatedly measured according to the 

experimental conditions determined above [26]. RSD of the peak current was calculated to be 

0.9 - 1.6 %, and the peak shape of each curve was good. Therefore, this test method has high 

reproducibility and high stability, and can be applied in practice. 

Limit of detection (LOD) and limit of quantitation (LOQ) 

When the concentration of Fe3+ is greater than 5.0×10-3 mol/L (LOQ), the oxidation peak area 

does not change with the concentration increase, indicating that Fe3+ ions are adsorbed on the 

electrode surface. LOD was calculated to be about 1.0 x 10-3 mol/L at SNR of 3 times. In the same 

way, LOD of Fe2+ was determined as 8.9×10-3 mol/L and LOQ was 2.5×10-2 mol/L. 

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Linearity and range 

Gradient of standard solution concentrations of Fe3+ (0.005-0.01 mol/L) and Fe2+ (0.025-0.05 mol/L) 

were added to 1 g/L SFGC solution, respectively and their CVs are scanned under the optimal 

experimental conditions (Figures 8 and 9). Linear regression equations for two standard Fe3+ and Fe2+ 

solutions could be then obtained: Y = 12.85667 + 2786X, R2 = 0.9961 (Fe3+) and Y = 42.32+703.8X, 

R2 = 0.9924 (Fe2+). The detection limit was low, reaching mM level. Thereupon, it could be reasoned 

that iron in the complex would not affect the interference of free iron ions and that the content of 

free iron ions in any SFGC sample could be calculated according to the standard curve equation. 
 

 
Figure 8. CVs of GC electrode in SFGC solution containing standard Fe3+ solutions (0.005-0.01 mol/L) and 

calibration plot (line is linear fit) 

 
Figure 9. CVs of GC electrode in SFGC solution containing standard Fe2+ solutions (0.025-0.05 mol/L) and 

calibration plot (line is linear fit). 

Determination of the total iron content in SFGC 

The cyclic voltammetry was employed to scan 1 g/L SFGC solution and 1 mol/L D-sodium 

gluconate solution. In both solutions, however, no characteristic peak of free iron ions is observed 

(Figure 10a and b). Nevertheless, the characteristic electrochemical behavior can be observed after 

the acid-hydrolysis of SFGC solution (Figure 10c). These results showed that stability of the 



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complexed iron is high because D- sodium gluconate serves as a molecular shell to effectively adsorb 

the metal iron ions in the solution, forming a stable complex. Therefore, the iron core content is 

difficult to be determined directly by the electrochemical scanning [27]. When the sample was acid-

decomposed, the complexed iron is completely converted into free Fe3+ ions, and the 

electrochemical redox peak appeared in the potential range of -0.4-1.0 V. The ratio of anode to 

cathode peak currents (IPC/IPA) is 1.026, what is close to the theoretical value of 1 for the reversible 

reaction. This means that the redox reaction of iron ions is a reversible process. 
 

 
Figure 10. Comparison of cyclic voltammograms of (a) SFGC solution before acid-hydrolysis,  

(b) D-SG solution, (c) SFGC solution after acid-hydrolysis 

0.01 M Fe3+ standard solution, 5 g/L SFGC solution and their mixture were acidolyzed at the same 

time. After the cyclic voltammetry scanning (Figure 11), it can be seen that the characteristic peaks 

of Fe3+ are similar in shape, but with some horizontal stretching. The results showed that the 

complex iron can be completely converted to Fe3+ ions by acid-hydrolysis in SFGC solution. 
 

 
Figure 11. Verification of Fe3+ characteristic peaks in solutions of (a) FeCl3, 

 (b) FeCl3 and SFGC mixture, (c) SFGC 

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Optimization of acid hydrolysis conditions 

The electrochemical scanning results of reduction peak currents (ipc) in SFGC solutions after acid-

hydrolysis at different concentrations of hydrochloric acid solution and different temperatures are 

compared in Table 1. It is shown that iron core in the complexing iron could be completely released 

and converted into free Fe3+ ions by acid-hydrolysis with 5 mol/mL hydrochloric acid solution for 5 

min. The temperature has small effect on the acid-hydrolysis process, which can be carried out 

directly at room temperature. 
 

Table 1. Determination of acid-hydrolysis conditions  

 
HCl concentration, moll/L Temperature, ℃ 

1 3 5 7 RT 4 20 
Acid­hydrolysis 5 min ­ ipca / μA 9.85 10.79 11.04 11.12 11.04 10.99 11.08 
Acid­hydrolysis 10 min ­ ipca / μA 9.85 10.82 11.11 11.09 11.09 11.03 11.07 

aipc : Reduction peak current 

Linearity range 

 Standard solutions of Fe3+ ions after acid-hydrolysis at different concentrations were scanned 

under optimal conditions (Figure 12A). Within the range of 0.01 - 0.04 mol/L, the peak currents 

presented a good linear relationship with Fe3+ concentration (Y = 2.27714+836X), R2 = 0.9957 

(Figure 12B). Therefore, the total iron content in any SFGC sample solution can be obtained using 

this linear fitted equation. 

 
Figure 12. (A) CV curves for different concentrations of standard Fe3+ solution after acid-hydrolysis of SFGC, 

(B) reduction peak current vs. concentration of Fe3+ 

Application 

Three sample solutions with concentration of 0.1 g/L were prepared by SFGC containing 10 mg 

iron, and the content of free iron in the samples was determined by cyclic voltammetry under the 

optimal conditions. Further, acid-hydrolysis was carried out before the sample was measured. The 

total iron content in SFGC was calculated by the linear regression equation, and RSD value was then 

acquired (Table 2). 
 

Table 2. Determination of free iron ions and total iron content in SFGC. 

Sample number Free iron 
Total amount of iron 

Founda, mg Relative to labeled, % RSD, % 
1  --b 9.89 98.9 0.75 
2 -- 10.16 101.6 1.65 
3 -- 10.08 100.8 1.07 

amean value of 6 parallel measurements; bno free iron ions were detected 



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Conclusions 

In this paper, the contents of free iron ions and total iron in the system were detected by the 

cyclic voltammetry scanning with glassy carbon electrode. The optimized experimental conditions 

were defined as solution pH 3, potential scanning rate 0.05 V/s. Before CV measurements, 

enrichment potential 0.4 V and enrichment time 3 min were found optimal. Free Fe3+ ions were 

measured in the range of 0.005-0.01 mol/L, while free Fe2+ ions were measured in the range of 

0.025-0.05 mol/L. The peak current was linearly correlated with the concentration of iron ions, and 

the results showed that the method is stable and reproducible. The chelated iron can be completely 

converted to Fe3+ ions by acid-hydrolysis under 5 mol/L hydrochloric acid solution for 5 min, and 

then calculated according to the linear relationship. 

Compared with the previous methods for determination of iron content, here proposed 

electrochemical detection method can determine the contents of free iron ions and total iron in the 

system. Also, the proposed method has the advantages of simple operation, short response time, 

good sensitivity, and accurate stable results. This method can also be used for determination of 

other complexes of iron. 

Acknowledgements: The investigations were carried out with the equipment of Administrative Office 
of Laboratory and Equipment, Southwest University. 

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