Speciation of Iron Using Desferal via Simple pH Change and a Single Calibration Curve: High-Throughput Optical Sensor Based on 96-Well Plates and an Overhead Book Scanner as Detector
Abstract
:1. Introduction
2. Materials and Methods
2.1. Reagents and Solutions
2.2. Instrumentation
2.3. Analytical Procedure for the Speciation of Iron
3. Results and Discussion
3.1. Preliminary Experiments
3.2. Effect of the pH on the Development of the Sensor
- (i).
- Fe(III) had “uniform” behavior over almost the entire pH range regardless of the buffers used. A slight decrease of ca. 10% was observed at alkaline pH values of 8, which can be attributed to hydrolysis phenomena.
- (ii).
- No practical reaction between Fe(II) and Desferal was recorded at acidic pH values of ≤ 3. In the Acetate/Glycine buffer, Fe(II) started reacting with Desferal at pH values of > 4, and the reaction was completed at pH = 5, yielding signals equal to Fe(III).
- (iii).
- No Fe(II)-Desferal reaction was observed at pH = 5 using Tris buffer, indicating that besides the presence of dissolved oxygen, the species of the buffer plays an important role in the reaction. In Tris buffer, the reaction between Fe(II) and Desferal was evident for pH values > 7, which was in accordance with the findings of Yegorov et al., who used the same buffer at pH = 7.4 [29].
3.3. Effects of the Concentration of Desferal and the Reaction Time
3.4. Speciation of Fe(III)/Fe(II) in Aqueous Solutions
3.5. Analytical Figures of Merit
3.6. Effects of Interfering Compounds/Selectivity
- (i).
- Mg(II), Ca(II), K(I), and Na(I) had no effect at the maximum ratio tested (100-fold excess).
- (ii).
- The same results were obtained for Cl−, SO42−, NO3−, and HCOO−.
- (iii).
- Phosphate ions were tolerable at 10-fold excess since their presence seemed to slow down the complexation reaction.
- (iv).
- Al(III), Co(II), Ni(II), and Zn(II) were also adequately tolerated at 10-fold excess.
3.7. Analytical Application
4. Conclusions
Supplementary Materials
Author Contributions
Funding
Institutional Review Board Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Method Principle | Speciation of Iron (Fe(II)/Fe(III)) | LOD | Ref. |
---|---|---|---|
Color development in the nanospace of mesoporous silica MCM-41 and the chromogenic ligand bathophenathroline disulfonate (BPS) | Reduction of Fe(III) by hydroxylamine | 0.5 μM | [9] |
Ionic liquid-based in situ solvent formation micro-extraction after complexation of Fe(II) with 1,10-phenanthroline | Reduction of Fe(III) by ascorbic acid | 0.3 μg L−1 | [10] |
Carbon-dot-based fluorescent probes containing phenol groups | Oxidation of Fe(II) by H2O2 | 0.17 μM | [18] |
Flow-based photometric method using 1,10-phenanthroline | Reduction of Fe(III) by ascorbic acid | 20 μg L−1 | [19] |
Complexation between Fe(II) and 2-(5-bromo-2-pyridylazo)-5-diethylaminophenol followed by cloud point extraction | Reduction of Fe(III) by ascorbic acid | — | [20] |
Flow Injection analysis spectrophotometry based on the reaction of Fe(II) with 2-(5-bromo-2-pyridylazo)-5-(diethylamino)-phenol | Reduction of Fe(III) by ascorbic acid | 110 μg L−1 | [21] |
Flow Injection spectrophotometry using 1,10-phenanthroline | Reduction of Fe(III) by hydroxylamine | 22 μg L−1 | [22] |
Micelle-mediated extraction and photometric determination of iron using a newly synthesized salicylic acid derivative | Oxidation of Fe(II) by H2O2 | 1.2 μg L−1 | [23] |
Multi-pumping flow system based on the reaction between Fe(II) and 2-(5-bromo-2-pyridylazo)-5-(diethylamino)-phenol | Reduction of Fe(III) by ascorbic acid | 34 μg L−1 | [24] |
In-syringe dispersive liquid–liquid micro-extraction after Fe(III) is complexed with 4,5-dihydroxy-1,3-benzendisulfonic acid | Oxidation of Fe(II) by H2O2 | 1 μg L−1 | [25] |
Sensor using micro-extraction via a high-density deep eutectic solvent after complexation of Fe(II) with ferrozine | Reduction of Fe(III) by ascorbic acid | 1 μg L−1 | [11] |
Flow Injection photometric method with ferrozine as complexing reagent | Reduction of Fe(III) by ascorbic acid | 0.65 nM | [12] |
Fluorescent probe for total iron using benzothiazole biphenyl as the fluorophore and 2-hydroxyaniline as the complexation group. | Both Fe(II) and Fe(III) react. No speciation is reported. | 1.2 μM | [13] |
Reaction of Fe(II)/Fe(III) with Nitroso-R salt | Both Fe(II) and Fe(III) react. No speciation is reported. | 45 nM | [14] |
Sequential injection using Curcuma putii Maknoi and Jenjitt. extract as a natural reagent | Both Fe(II) and Fe(III) react. No speciation is reported. | 110 μg L−1 | [15] |
PAD based on the colorimetric reaction between bathophenanthroline and Fe(II) | Reduction of Fe(III) by hydroxylamine | 60 μg L−1 | [16] |
HPLC coupled to high-resolution inductively coupled plasma optical emission spectrometry | Separation using a cation-exchange column containing pyridine–2,6–dicarboxylic acid | 40–50 mg kg−1 | [17] |
Calibration Curve | Experimental Conditions | Slope | S.D. a |
---|---|---|---|
[A] | Fe(III) at pH = 2 | 1.4335 | 0.0380 |
[B] | Fe(III) at pH = 5 | 1.4974 | 0.0220 |
[C] | Fe(II) at pH = 2 | 0.0192 | 0.0070 |
[D] | Fe(II) at pH = 5 | 1.4892 | 0.0400 |
Sample | Form | Form of Iron | Labeled Value of Fe(II) | Fe(II) Found (±SD, n = 3) | R (%) |
---|---|---|---|---|---|
1 | Capsule | Iron sulfate | 47 mg/cap | 44 (±4) | 94 |
2 | Tablet | Iron sulfate | 80 mg/tab | 83 (±5) | 104 |
3 | Powder | Iron gluconate | 37.5 mg/dose | 38.5 (±4) | 103 |
4 | Sachets | Iron gluconate | 80 mg/sachet | 76 (±3) | 95 |
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Baltzis, D.; Tsiasioti, A.; Zacharis, C.K.; Tzanavaras, P.D. Speciation of Iron Using Desferal via Simple pH Change and a Single Calibration Curve: High-Throughput Optical Sensor Based on 96-Well Plates and an Overhead Book Scanner as Detector. Chemosensors 2023, 11, 577. https://doi.org/10.3390/chemosensors11120577
Baltzis D, Tsiasioti A, Zacharis CK, Tzanavaras PD. Speciation of Iron Using Desferal via Simple pH Change and a Single Calibration Curve: High-Throughput Optical Sensor Based on 96-Well Plates and an Overhead Book Scanner as Detector. Chemosensors. 2023; 11(12):577. https://doi.org/10.3390/chemosensors11120577
Chicago/Turabian StyleBaltzis, Dimitrios, Apostolia Tsiasioti, Constantinos K. Zacharis, and Paraskevas D. Tzanavaras. 2023. "Speciation of Iron Using Desferal via Simple pH Change and a Single Calibration Curve: High-Throughput Optical Sensor Based on 96-Well Plates and an Overhead Book Scanner as Detector" Chemosensors 11, no. 12: 577. https://doi.org/10.3390/chemosensors11120577
APA StyleBaltzis, D., Tsiasioti, A., Zacharis, C. K., & Tzanavaras, P. D. (2023). Speciation of Iron Using Desferal via Simple pH Change and a Single Calibration Curve: High-Throughput Optical Sensor Based on 96-Well Plates and an Overhead Book Scanner as Detector. Chemosensors, 11(12), 577. https://doi.org/10.3390/chemosensors11120577