Abstract
Additive manufacturing is an emerging tool that has contributed to the sustainable fabrication of devices in several areas based on the concept of “zero waste”. Considering extrusion-based manufacturing (or 3D printing), polylactic acid (PLA) has been highlighted due to its biodegradability, obtention from renewable sources, and compatibility for 3D printing. Composites of PLA with conducting fillers, such as carbon-black (CB/PLA), are commercially-available and compatible with extrusion-based 3D printers and 3D pen. Herein, we investigate the electrochemical behavior of several antioxidant species (catechol, hydroquinone, propyl-gallate, octyl-gallate, dopamine, gallic acid and pyrogallol (PY)) on 3D-printed electrodes. Experiments by cyclic voltammetry demonstrated that electrochemical surface treatment in NaOH aqueous solution is an important strategy to improve the response of all antioxidants. Thus, PY was selected to evaluate the analytical performance of the proposed 3D-printed sensor. For this, a fast and simple method using batch-injection analysis with amperometric detection (BIA-AD) has been developed, which showed a limit of detection of 0.15 µmol L-1, wide linear range (0.5 to 300 µmol L-1), good precision (relative standard deviation (RSD) < 3.4%) and selectivity. This method was applied in biodiesel samples, after dilution (400-fold) in electrolyte. Recovery percentages ranging from 82 to 119% attested absence of matrix effect and good accuracy.
Keywords:
3D printing; antioxidants; carbon black/polylactic acid; biodiesel; batch-injection analysis
Introduction
Additive manufacturing has been recognized as an emerging tool that enables cost-effective and efficient fabrication towards sustainability. Different areas have been benefited by additive manufacturing technologies, including aerospace, medicine, electronics, civil engineering, food and pharmaceutics.11 Ngo, T. D.; Kashani, A.; Imbalzano, G.; Nguyen, K. T. Q.; Hui, D.; Composites, Part B 2018, 143, 172. Additive manufacturing has also caused a great impact on chemistry, including organic synthesis in flow conditions,22 Dragone, V.; Sans, V.; Rosnes, M. H.; Kitson, P. J.; Cronin, L.; Beilstein J. Org. Chem. 2013, 9, 951. analytical chemistry from separation to detectors,33 Wang, L.; Pumera, M.; TrAC, Trends Anal. Chem. 2021, 135, 116151.
4 Agrawaal, H.; Thompson, J. E.; Talanta Open 2021, 3, 100036.-55 Carrasco-Correa, E. J.; Simó-Alfonso, E. F.; Herrero-Martínez, J. M.; Miró, M.; TrAC, Trends Anal. Chem. 2021, 136, 116177. catalysis66 Martín de Vidales, M. J.; Nieto-Márquez, A.; Morcuende, D.; Atanes, E.; Blaya, F.; Soriano, E.; Fernández-Martínez, F.; Catal. Today 2019, 328, 157. and electrochemistry (energy and sensing applications).77 Cardoso, R. M.; Kalinke, C.; Rocha, R. G.; dos Santos, P. L.; Rocha, D. P.; Oliveira, P. R.; Janegitz, B. C.; Bonacin, J. A.; Richter, E. M.; Munoz, R. A. A.; Anal. Chim. Acta 2020, 1118, 73.
8 Pang, Y.; Cao, Y.; Chu, Y.; Liu, M.; Snyder, K.; MacKenzie, D.; Cao, C.; Adv. Funct. Mater. 2020, 30, 1906244.-99 Browne, M. P.; Redondo, E.; Pumera, M.; Chem. Rev. 2020, 120, 2783.
There are different types of additive manufacturing techniques, also named as three-dimensional printing (3D printing) and some of them has been applied for electrochemical applications, such as ink-jet printing, extrusion-based of polymeric filaments and photopolymerization under ultraviolet light.1010 Silva, A. L.; Salvador, G. M. S.; Castro, S. V. F.; Carvalho, N. M. F.; Munoz, R. A. A.; Front. Chem. 2021, 9, 684256. The most affordable and employed technique for the construction of electrochemical devices is based on the deposition of extruded filaments, also named as fused deposition modelling (FDM), which was enabled by the obtaining of conductive filaments.1111 Omar, M. H.; Razak, K. A.; Ab Wahab, M. N.; Hamzah, H. H.; RSC Adv. 2021, 11, 16557. Polylactic acid (PLA) filaments containing graphene, carbon-black or nanocarbon conductive particles have been applied to produce electrochemical sensors.1212 Manzanares Palenzuela, C. L.; Novotný, F.; Krupička, P.; Sofer, Z.; Pumera, M.; Anal. Chem. 2018, 90, 5753.
13 Vaněčková, E.; Bouša, M.; Nováková Lachmanová, Š.; Rathouský, J.; Gál, M.; Sebechlebská, T.; Kolivoška, V.; J. Electroanal. Chem. 2020, 857, 113745.-1414 Jain, S. K.; Tadesse, Y.; Int. J. Nanosci. 2019, 18, 1850026. PLA is a biopolymer, that is obtained from renewable sources and biodegradable, thus offers great promises to the 3D printing sustainable electrochemical devices.1515 Sfragano, P. S.; Laschi, S.; Palchetti, I.; Front. Chem. 2020, 8, 644. Carbon electrochemistry has been well documented in the literature, hence the comparison of the electrochemical activity of the 3D-printed electrodes with conventional ones, such as glassy-carbon electrode, boron-doped diamond electrode, carbon-paste electrode or screen-printed electrode, is easily assessed.1616 Cardoso, R. M.; Mendonça, D. M. H.; Silva, W. P.; Silva, M. N. T.; Nossol, E.; da Silva, R. A. B.; Richter, E. M.; Muñoz, R. A. A.; Anal. Chim. Acta 2018, 1033, 49.,1717 Richter, E. M.; Rocha, D. P.; Cardoso, R. M.; Keefe, E. M.; Foster, C. W.; Munoz, R. A. A.; Banks, C. E.; Anal. Chem. 2019, 91, 12844. The performance of 3D-printed electrodes using PLA containing graphene or carbon black is poor when compared with such conventional electrodes, however, after a surface treatment, it can be dramatically improved.1818 Rocha, D. P.; Rocha, R. G.; Castro, S. V. F.; Trindade, M. A. G.; Munoz, R. A. A.; Richter, E. M.; Angnes, L.; Electrochem. Sci. Adv., in press, DOI: 10.1002/elsa.202100136.
https://doi.org/10.1002/elsa.202100136...
One simple protocol to improve the electrochemical activity of 3D-printed carbon electrodes is the electrochemical treatment in a NaOH solution, which consumes the PLA matrix and makes more available the conductive particles within the polymeric matrix.1717 Richter, E. M.; Rocha, D. P.; Cardoso, R. M.; Keefe, E. M.; Foster, C. W.; Munoz, R. A. A.; Banks, C. E.; Anal. Chem. 2019, 91, 12844.,1919 Rocha, D. P.; Squissato, A. L.; da Silva, S. M.; Richter, E. M.; Munoz, R. A. A.; Electrochim. Acta 2020, 335, 135688.
Desktop FDM 3D printers are widely available worldwide, they can be constructed following tutorials using low-cost parts that can also be 3D printed, which certainly contributed to their great popularity.2020 Tully, J. J.; Meloni, G. N.; Anal. Chem. 2020, 92, 14853. Analogous to such 3D printers, 3D pen that is available as a toy for kids can also be employed to fabricate electrochemical sensors.2121 Cardoso, R. M.; Castro, S. V. F.; Stefano, J. S.; Muñoz, R. A. A.; J. Braz. Chem. Soc. 2020, 31, 1764. Advantages include the reduced amount of filament required to prototype a device, hand-held portability, and much lower cost. The obvious disadvantage is the absence of the precise three-dimensional control of the 3D-printer extruder. The solution found by different groups to overcome this drawback is the use of customized templates.2222 Cardoso, R. M.; Rocha, D. P.; Rocha, R. G.; Stefano, J. S.; Silva, R. A. B.; Richter, E. M.; Muñoz, R. A. A.; Anal. Chim. Acta 2020, 1132, 10.,2323 de Oliveira, F. M.; de Melo, E. I.; da Silva, R. A. B.; Sens. Actuators, B 2020, 321, 128528.
In this context, we show a novel application of 3D-printed electrodes using PLA containing conductive carbon-black particles, which after electrochemical treatment provides excellent electrochemical activity to the oxidation of diverse antioxidants. We also show how 3D-printed electrodes can be applied for the detection of the antioxidant pyrogallol in biodiesel, a complex sample, with great analytical features, including wide linear range, low limit of detection and high sample throughput using batch injection analysis with amperometric detection (BIA AD). This technique has been reported by different groups worldwide due to its portability and simplicity of operation, important features for routines analyses.2424 Veloso, W. B.; Ribeiro, G. A. C.; da Rocha, C. Q.; Tanaka, A. A.; da Silva, I. S.; Dantas, L. M. F.; Measurement 2020, 155, 107516.
25 Ribeiro, G. A. C.; da Rocha, C. Q.; Veloso, W. B.; Fernandes, R. N.; da Silva, I. S.; Tanaka, A. A.; Microchem. J. 2019, 146, 1249.
26 Corrêa Ribeiro, G. A.; Quintino da Rocha, C.; Tanaka, A. A.; Santos da Silva, I.; Anal. Methods 2018, 10, 2034.-2727 Higino, G. S.; Machado, Í. R.; Nascimento, G. F.; Pedrotti, J. J.; J. Braz. Chem. Soc. 2021, 32, 2215. The proposed BIA-AD method using 3D-printed electrodes presents superior sensing performance in comparison with other electroanalytical methods previously reported.
Experimental
Instrumentation, electrochemical cell and electrodes
All electrochemical recordings were performed using an μ-AUTOLAB Type III potentiostat/galvanostat (Metrohm Autolab BV, Utrecht, the Netherlands) coupled to a computer. The NOVA 2.1.4 software for windows 10 was used to control the instrument. Data were treated using the OriginPro8.5 software2828 OriginPro, 8.5; OriginLab Corp., Northampton, USA, 2010. for graphing and analysis (Northampton, MA, USA). The cyclic voltammetric (CV) measurements were performed using a 10 mL beaker and amperometric experiments were carried out using a 3D-printed BIA electrochemical cell (internal volume of 100 mL), as prototyped by Cardoso et al.1616 Cardoso, R. M.; Mendonça, D. M. H.; Silva, W. P.; Silva, M. N. T.; Nossol, E.; da Silva, R. A. B.; Richter, E. M.; Muñoz, R. A. A.; Anal. Chim. Acta 2018, 1033, 49. In this analysis system, all injections were conducted using an Eppendorf electronic micropipette (Multipette® E3, Hamburg, Germany), which permits injections from 1 μL to 1 mL (using a 1 mL Combtip®, Hamburg, Germany) at a programmable dispensing rate (from 17 to 300 μL s-1). The reference and auxiliary electrodes were an Ag|AgCl (saturated KCl) and a platinum wire, respectively. As working electrode, two different prototypes were proposed (tubular and planar), both composed of conductive carbon black/polylactic acid (CB/PLA) thermoplastic filament (Proto-Pasta®) obtained from Proto Plant Inc. (Vancouver, Canada).
Reagents and solutions
All solutions were prepared with high-purity deionized water (resistivity ≥ 18 MΩ cm) obtained from a Direct-Q3 water purification system (Millipore, Bedford, MA, USA). Concentrated perchloric acid (70% m/v), acetic acid (99.7% m/v) from Vetec (Rio de Janeiro, Brazil), ethanol (99.8% v/v), sodium hydroxide (98% m/m) and phosphoric acid (85% m/v) from Synth (São Paulo, Brazil) and boric acid (99.9%) from Acros Organics (USA) were diluted in an appropriate concentration to study the composition of the supporting electrolyte. The following antioxidants were evaluated: catechol (CT) (99% m/m) from Acros Organics (New Jersey, USA), hydroquinone (HQ) (99% m/m) from Vetec (Rio de Janeiro, Brazil), octyl gallate (OG) (≥ 99% m/m), dopamine hydrochloride (DP), gallic acid (GA) (≥ 97.5% m/m), propyl gallate (PG) (≥ 98% m/m), and pyrogallol (PY) (≥ 98% m/m) from Sigma-Aldrich (St. Louis, USA). The standard stock solutions of PY, PG, OG and GA were prepared in ethanol (99.8% v/v) and CT, HQ and DP were prepared in deionized water. Aqueous standard solutions of CuII, FeIII, PbII, MnII, ZnII and CdII (all at 1000 mg L-1) were purchased from Quimlab (Jacareí, Brazil). The Britton-Robinson (BR) buffer solution (0.12 mol L-1) was prepared using equimolar mixture of acetic, boric, and phosphoric acids. The adjustment of pH values was carried out using a 1.0 mol L-1 NaOH solution.
Two methyl biodiesel samples were analyzed, one produced from soybean oil in the laboratory according to a procedure described in the literature2929 Serqueira, D. S.; Fernandes, D. M.; Cunha, R. R.; Squissato, A. L.; Santos, D. Q.; Richter, E. M.; Munoz, R. A. A.; Fuel 2014, 118, 16. and another sample donated by a biodiesel power plant (Caramuru, Itumbiara, Brazil) identified as commercial biodiesel. These biofuels samples were free from synthetic antioxidants according to previous analyses.
Production of 3D-printed CB/PLA electrodes
Twenty-five customized cylinders (3.5 cm length × 3.8 mm diameter) were 3D-printed in an Anycubic Photon digital UV light processing (DLP) from ANYCUBIC Co., Ltd. (Shenzen, China) using acrylic resin. Next, a 3D pen from Sanmersen (Shenzhen, China) was used to print the conductive part of each electrode using a CB/PLA conductive filament. This step is made one by one manually and takes around 1 min each electrode. The pen has a speed controller and an integrated heating nozzle from which the molten filament is released. The fabrication of planar CB/PLA electrodes using FDM 3D-printer from Dreamer NX, Flash Force (Zheijang, China) was based on previous work.1616 Cardoso, R. M.; Mendonça, D. M. H.; Silva, W. P.; Silva, M. N. T.; Nossol, E.; da Silva, R. A. B.; Richter, E. M.; Muñoz, R. A. A.; Anal. Chim. Acta 2018, 1033, 49. Briefly, four rectangles (40 mm length × 15 mm width × 1.8 mm height) were 3D-printed employing the conductive CB/PLA filament. The layer height was set at 0.25 mm, with 2 shells (outer perimeter toolpaths) and 100% infill density.
After fabrication, both 3D-printed CB/PLA working electrode were polished in a sandpaper (600 grit followed by 1200 grit) moistened with ultrapure water until a homogeneous surface was obtained. Next, an electrochemical treatment procedure of the 3D-printed CB/PLA electrodes was performed by amperometry in NaOH (0.5 mol L-1) solution, with application of a potential of +1.4 V per 200 s, followed by a potential of -1.0 V for the same time. This protocol was optimized in a previous work that showed the great exposure of carbon black conducting sites.1919 Rocha, D. P.; Squissato, A. L.; da Silva, S. M.; Richter, E. M.; Munoz, R. A. A.; Electrochim. Acta 2020, 335, 135688.
Electrochemical measurements
The electrochemical measures were executed without removing dissolved oxygen and at laboratory room temperature (around 25 °C). The polishing process and electrochemical activation employing 0.5 mol L-1 NaOH were sequentially performed at the beginning of each working day as described in the “Production of 3D-printed CB/PLA electrodes” sub-section.
The electrochemical behavior of different antioxidant species was performed by CV on untreated and treated surfaces. The pH effect on the electrochemical response of PY (1 mmol L-1) was evaluated using BR buffer solution (0.12 mol L-1) with pH values ranging from 2.0 to 8.0 (Figure S1, Supplementary Information (SI) Supplementary Information Supplementary data (voltammetric data regarding pH variation of the supporting electrolyte and amperometric data regarding optimization of the analytical parameters for the determination of pyrogallol) are available free of charge at http://jbcs.sbq.org.br as PDF file. section). For the determination of PY in biodiesel by BIA-AD, the parameters, working potential, dispensing rate and injection volume were optimized using a PY standard solution (100 µmol L-1) with measurements in triplicates (n = 3).
Biodiesel sample preparation
Biodiesel samples were initially diluted 40-fold in ethanol, and then 1 mL aliquot of this solution was added to a 10 mL volumetric flask and the meniscus adjusted with BR buffer (0.12 mol L-1, pH 6.0).
Results and Discussion
Electrochemical response of the antioxidants on the 3D-printed CB/PLA
The electrochemical profiles of seven different antioxidants were investigated using the 3D-printed CB/PLA electrodes. Figure 1 shows the voltammetric profile of PY, PG, OC, CT, HQ, DP and GA in 0.1 mol L-1 HClO4 using untreated (red lines) and treated surfaces (blue lines).
Cyclic voltammetric recordings for 1 mmol L-1 of each (a) CT, (b) HQ, (c) PG, (d) PY, (e) GA, (f) DP, (g) OG in 0.1 mol L-1 HClO4 in 10% (v/v) ethanol before (red line) and after (blue line) chemical/electrochemical treatment of electrode. The dashed lines correspond to the respective blanks. Other conditions: scan rate: 50 mV s-1 and step potential: 5 mV.
The electrochemical oxidation of the seven antioxidants is feasible on the 3D-printed CB/PLA electrode with oxidation peaks at +0.55 V for CT, +0.59 V for GA, +0.55 V for DP, +0.48 V for HQ, +0.78 V for OG, +0.62 V for PG and +0.60 V for PY. Interestingly, all the electrochemical oxidation processes were facilitated on the electrochemically treated CB/PLA electrode (blue lines) probably by the formation of oxygenated species and higher exposure of carbon black sites as documented in previous work.1919 Rocha, D. P.; Squissato, A. L.; da Silva, S. M.; Richter, E. M.; Munoz, R. A. A.; Electrochim. Acta 2020, 335, 135688. A previous work3030 Ataide, V. N.; Rocha, D. P.; de Siervo, A.; Paixão, T. R. L. C.; Muñoz, R. A. A.; Angnes, L.; Microchim. Acta 2021, 188, 388. evaluated in details the surface changes of 3D-printed CB/PLA electrodes after the same electrochemical protocol in NaOH solution using X-ray spectroscopy and the authors revealed an increase in bonds (C-C) that indicated the formation of graphitic structures, probably due to the consumption of PLA exposing more carbon black sites after treatment. Such a surface modification contributed to the improved electrochemical oxidation of the antioxidants; however, further investigation is required to understand and prove this hypothesis.
Aiming at a sensitive and selective determination of PY in biodiesel samples, its electrochemical response was investigated at different pH-values (2.0 to 8.0) using BR buffer, as shown in Figure S1 (SI section
Supplementary Information
Supplementary data (voltammetric data regarding pH variation of the supporting electrolyte and amperometric data regarding optimization of the analytical parameters for the determination of pyrogallol) are available free of charge at http://jbcs.sbq.org.br as PDF file.
). A pH-dependent behavior was observed up to pH 8.0, after this value, PY shows low stability. From the linear adjustment between EP (peak potential) and pH (see Figure S1B), slope values of 55 and 60 mV pH-1 were obtained, suggesting that the same number of protons and electrons are involved in both oxidation processes, which is in agreement with other works reported in the literature.3131 Hung, C. H.; Chang, W. T.; Su, W. Y.; Cheng, S. H.; Electroanalysis 2014, 26, 2237.
32 Nasr, B.; Hsen, T.; Abdellatif, G.; J. Environ. Manage. 2009, 90, 523.-3333 Cañizares, P.; Lobato, J.; Paz, R.; Rodrigo, M. A.; Sáez, C.; Water Res. 2005, 39, 2687. Considering that pH 6.0 provided a better response as well as a considerable anticipation of both oxidation processes, this buffered solution was selected for further experiments.
Determination of PY antioxidant in biodiesel by BIA-AD
Initially, the BIA-AD parameters (working potential, dispensing rate and injected volume) were evaluated in order to provide good selectivity, increase in analytical response, lower consumption of reagents and higher analytical frequency. The influence of each parameter on the electrochemical response of PY is shown in SI section Supplementary Information Supplementary data (voltammetric data regarding pH variation of the supporting electrolyte and amperometric data regarding optimization of the analytical parameters for the determination of pyrogallol) are available free of charge at http://jbcs.sbq.org.br as PDF file. (Figures S2, S3 and S4). Table 1 summarizes the assessed BIA-AD parameters, the studied range and the selected values for subsequent studies.
Under the selected parameters listed in Table 1, the sensor was evaluated for the determination PY. The linear ranges between the peak currents and the concentration levels of PY were obtained from 0.5 to 300 μmol L-1 with good correlation coefficients, r = 0.996 and r = 0.999 for increasing and decreasing concentrations, respectively (Figure 2). Similar slopes, 0.2243 and 0.2124, demonstrated the absence of memory effect after consecutive injections of PY standard solution. The linear regression equation, Ipa (μA) = (0.224 ± 0.006)[PY] (μM) - 0.002 ± 0.001, was obtained for increasing concentration.
(A) BIA-AD responses for triplicate injections of (a) 0.5, (b) 1.0, (c) 5.0, (d) 10 (e) 20, (f) 40, (g) 50, (h) 75, (i) 100 (j) 150 and (k) 300 μmol L-1 PY standard solutions in BR buffer (0.12 mol L-1, pH 6.0) and (B) respective calibration curves: increasing and decreasing PY concentrations. Optimized conditions in Table 1.
From these curves, the limit of detection (LOD) and quantification (LOQ) values for PY were estimated. LOD and LOQ values were calculated according to the International Union of Pure and Applied Chemistry (IUPAC)3434 Mocak, J.; Bond, A. M.; Mitchell, S.; Scollary, G.; Bond, A. M.; Pure Appl. Chem. 1997, 69, 297. definition as follows: LOD = 3σ/s and LOQ = 10σ/s, in which σ indicates the standard deviation of baseline noise while s corresponds to the sensitivity of the calibration curve (slopes).
Subsequently, a series of repetitive electrochemical determinations (n = 10) were performed to evaluate the precision of this method. The repeatability study was conducted with three different levels of concentration of PY (10, 20 and 50 μmol L-1) (shown in Figure 3) using the same 3D-printed electrode. All relative standard deviation (RSD) values were lower than 3.36%, indicating good precision.
Repeatability data obtained from successive injections of a solution containing (a) 5, (b) 20 and (c) 50 µmol L-1 PY (n = 10). Analysis conditions: working potential: +0.4 V, dispensing rate: 200 μL s-1, injected volume: 100 μL, electrolyte: BR buffer (0.12 mol L-1, pH 6.0).
The values of the inter-day variation were calculated by the RSD values of slopes from two analytical curves obtained in two different days. The electrode fabrication was evaluated by the inter-electrode variation and the values of 6.44% for PY proved the high reproducibility of the protocol. Table 2 describes the analytical features obtained for the PY using 3D-printed sensor associated with BIA-AD.
Selectivity study
The metallic ions, such as copper, iron, manganese and nickel, affect tremendously the biodiesel oxidative stability as the metallic species acts catalyzers of oxidation processes, leading to biodiesel degradation.3535 Knothe, G.; Steidley, K. R.; Fuel Process. Technol. 2018, 177, 75.,3636 Fernandes, D. M.; Squissato, A. L.; Lima, A. F.; Richter, E. M.; Munoz, R. A. A.; Renewable Energy 2019, 139, 1263. Considering these negative effects, maximum limits for some contaminants, including water, methanol, sulfate, chloride, sodium, and iron, are established by regulatory agencies worldwide (e.g., in Europe, the US and Brazil). The Brazilian agency ANP presents a resolution3737 Agência Nacional do Petróleo, Gás Natural e Biocombustíveis (ANP); Resolução No. 842, de 14 de maio de 2021, Estabelece a Especificação do Diesel Verde, bem como as Obrigações Quanto ao Controle da Qualidade a Serem Atendidas Pelos Agentes Econômicos que o Comercializem em Território Nacional; ANP: Rio de Janeiro, 2021, available at https://www.in.gov.br/en/web/dou/-/resolucao-anp-n-842-de-14-de-maio-de-2021-320059616, accessed in January 2022.
https://www.in.gov.br/en/web/dou/-/resol...
that defines a strict upper limit for some metallic ions (FeIII, CuII, PbII, MnII, and CrII) in the biofuel (1.0 mg kg-1). Such high amounts of metals in biodiesel may occur due to the corrosion of metallic parts (engines or tanks) in contact with the biofuel.3838 Rocha Jr., J. G.; dos Santos, M. D. R.; Madeira, F. B.; Rocha, S. F. L. S.; Bauerfeldt, G. F.; da Silva, W. L. G.; Salomão, A. A.; Tubino, M.; J. Braz. Chem. Soc. 2019, 30, 1751.
39 de Santana, P. M. B.; Meira, M.; Tentardini, E. K.; Mater. Res. 2015, 18, 164.-4040 Domingos, A. K.; Saad, E. B.; Vechiatto, W. W. D.; Wilhelm, H. M.; Ramos, L. P.; J. Braz. Chem. Soc. 2007, 18, 416.
The metallic species FeIII, CuII, PbII, MnII, CdII and ZnII were kept at 1 mg L-1 as interferents on the detection of PY at 50 μmol L-1. Amperometric recordings for these experiments are presented in Figure 4. Low deviations (lower than 7.13%) were obtained for PY even after the addition of each interferent. All metallic species did not provide an electrochemical response concomitant with PY oxidation peaks, hence no interference from FeIII, CuII, PbII, MnII, ZnII and CdII was observed.
(A) BIA-AD recordings obtained for 50 µmol L-1 of PY (a) and a mixture containing the same concentration of this antioxidant and 1 mg L-1 of (b) CuII, (c) ZnII, (d) CdII, (e) MnII, (f) FeIII and (g) PbII under the optimized conditions. (B) Interference percentage of each metal on the PY response.
Application in biodiesel samples
After the analytical features were obtained, the BIA-AD method using the manufactured CB/PLA electrode was applied for the determination of PY in biodiesel samples (soybean and commercial).
The accuracy of the method was evaluated by addition-recovery tests, which means that the samples were spiked with known amounts of PY antioxidant in three levels, (2.5, 6.3 and 12.6 mg L-1) which correspond to 20, 50 and 100 μmol L-1 PY injected into the electrochemical cell. The content of antioxidant in biodiesel was estimated based on the literature to achieve 12 h of induction period by the Rancimat method, official protocol to measure oxidative stability.4141 Ryu, K.; J. Mech. Sci. Technol. 2009, 23, 3105.
Figure 5 and Table 3 summarize the recovery values for the analysis of spiked biodiesel samples. Satisfactory recovery values were verified (from 82 to 119%), according to the acceptance criteria for recovery, established by the National Institute of Metrology, Quality and Technology (INMETRO)4242 Instituto Nacional de Metrologia, Normalização e Qualidade Industrial (INMETRO); DOQ-CGCRE-008, Orientações sobre Validação de Métodos Analíticos, 2020, available at http://www.inmetro.gov.br/Sidoq/Arquivos/Cgcre/DOQ/DOQ-Cgcre-8_05.pdf, accessed in January 2022.
http://www.inmetro.gov.br/Sidoq/Arquivos...
of Brazil, showing acceptable accuracy in the level of studied concentrations and no interference problems from the sample matrix (soybean biodiesel and biodiesel plant samples) under the optimized conditions. Therefore, the acceptable recovery values indicated that the proposed BIA-AD method can be used to quantify PY at low concentration levels using the 3D printed CB/PLA electrode.
Concentration and recovery values obtained for the analysis of biodiesel samples before and after spiking with PY (n = 3). Spiked values correspond to the concentration injected into the BIA-AD system after sample dilution
(A) Amperogram for PY determination by BIA-AD in soybean biodiesel (C), spiked soybean biodiesel (C1, C2 and C3), commercial biodiesel (D) and spiked commercial biodiesel (D1, D2 and D3). Analytical curve: (a) 1, (b) 5, (c) 10, (d) 20, (e) 50, (f) 75, (g) 100, and (h) 150 µmol L-1. (B) Respective calibration curves. Analysis conditions: working potential: +0.4 V, dispensing rate: 200 μL s-1, injected volume: 100 μL, electrolyte: BR buffer (0.12 mol L-1, pH 6.0).
The procedure developed for determination of PY in biodiesel using the CB/PLA electrode was compared with other procedures available in the literature, as shown in Table 4.
Comparative methods: overview of the literature reported for the determination of PY in biodiesel by various electroanalytical techniques
The evaluated parameters, including type of working electrode, limit of detection (LOD), limit of quantification (LOQ) and precision, denote that the proposed method provides equivalent or better results to those already existing in the literature. Furthermore, it is noteworthy that the 3D printed sensor has a low production cost and did not require laborious surface modification steps with metallic or carbon-based nanomaterials. The proposed BIA-AD method using 3D-printed electrodes can also be adapted for the determination of other antioxidants in biodiesel, such as tert-butylhydroquinone (TBHQ), butylhydroanisole (BHA) or butyl hydroxytoluene (BHT), which can be added to biofuels including biodiesel samples to increase oxidation stability. The electrochemistry of TBHQ on a graphene-PLA composite has been demonstrated recently,4848 Joao, A. F.; Matias, T. A.; Gomes, J. S.; Guimaraes, R. R.; Sousa, R. M. F.; Munoz, R. A. A.; ACS Sustainable Chem. Eng. 2021, 9, 16052. thus probably TBHQ is oxidized on the proposed 3D-printed CB/PLA and hence its electrochemical profile needs to be evaluated. Eventually, the electrochemical oxidation of two antioxidants (e.g., TBHQ and PY) can be accomplished using multiple-pulse amperometric detection. Further investigation is required depending on the analyzed samples (biodiesel or other biofuels) and antioxidants added by the biofuel producers. Nevertheless, the proposed BIA-AD method can be easily adapted for the quality control of biofuels.
Conclusions
This work has showed that the environmentally-friendly composite made of carbon black-integrated PLA can be used to fabricate 3D-printed electrodes to be applied for the quality control of biodiesel using the portable BIA system. The CB/PLA electrode was successfully used as a working electrode for the determination of PY by BIA-AD in soybean biodiesel samples as well as in a commercial biodiesel sample. The proposed protocol is precise, accurate and sensitive, which are confirmed by the repeatability and recovery studies. Selectivity of the sensor was also confirmed through assessments with interfering agents. Therefore, it is possible to conclude that the use of such a source of disposable electrodes for this purpose makes the method cheaper and portable, allowing field analysis. It is noteworthy that the CB/PLA electrode presented an analytical performance comparable to conventional electrodes for the determination of antioxidant PY. Thus, the proposed 3D-printed electrode has proven to be an important analytical tool for applications in biofuels as well in other types of samples.
Supplementary Information
Supplementary data (voltammetric data regarding pH variation of the supporting electrolyte and amperometric data regarding optimization of the analytical parameters for the determination of pyrogallol) are available free of charge at http://jbcs.sbq.org.br as PDF file.
Acknowledgments
The authors are grateful to the Brazilian agencies CAPES (001), CNPq (427731/2018-6, 307271/2017-0, and 163330/2020-4), FAPEMIG (PPM-00640-16) and INCTBio (CNPq grant No. 465389/2014).
References
-
1Ngo, T. D.; Kashani, A.; Imbalzano, G.; Nguyen, K. T. Q.; Hui, D.; Composites, Part B 2018, 143, 172.
-
2Dragone, V.; Sans, V.; Rosnes, M. H.; Kitson, P. J.; Cronin, L.; Beilstein J. Org. Chem. 2013, 9, 951.
-
3Wang, L.; Pumera, M.; TrAC, Trends Anal. Chem. 2021, 135, 116151.
-
4Agrawaal, H.; Thompson, J. E.; Talanta Open 2021, 3, 100036.
-
5Carrasco-Correa, E. J.; Simó-Alfonso, E. F.; Herrero-Martínez, J. M.; Miró, M.; TrAC, Trends Anal. Chem. 2021, 136, 116177.
-
6Martín de Vidales, M. J.; Nieto-Márquez, A.; Morcuende, D.; Atanes, E.; Blaya, F.; Soriano, E.; Fernández-Martínez, F.; Catal. Today 2019, 328, 157.
-
7Cardoso, R. M.; Kalinke, C.; Rocha, R. G.; dos Santos, P. L.; Rocha, D. P.; Oliveira, P. R.; Janegitz, B. C.; Bonacin, J. A.; Richter, E. M.; Munoz, R. A. A.; Anal. Chim. Acta 2020, 1118, 73.
-
8Pang, Y.; Cao, Y.; Chu, Y.; Liu, M.; Snyder, K.; MacKenzie, D.; Cao, C.; Adv. Funct. Mater. 2020, 30, 1906244.
-
9Browne, M. P.; Redondo, E.; Pumera, M.; Chem. Rev. 2020, 120, 2783.
-
10Silva, A. L.; Salvador, G. M. S.; Castro, S. V. F.; Carvalho, N. M. F.; Munoz, R. A. A.; Front. Chem. 2021, 9, 684256.
-
11Omar, M. H.; Razak, K. A.; Ab Wahab, M. N.; Hamzah, H. H.; RSC Adv. 2021, 11, 16557.
-
12Manzanares Palenzuela, C. L.; Novotný, F.; Krupička, P.; Sofer, Z.; Pumera, M.; Anal. Chem. 2018, 90, 5753.
-
13Vaněčková, E.; Bouša, M.; Nováková Lachmanová, Š.; Rathouský, J.; Gál, M.; Sebechlebská, T.; Kolivoška, V.; J. Electroanal. Chem. 2020, 857, 113745.
-
14Jain, S. K.; Tadesse, Y.; Int. J. Nanosci. 2019, 18, 1850026.
-
15Sfragano, P. S.; Laschi, S.; Palchetti, I.; Front. Chem. 2020, 8, 644.
-
16Cardoso, R. M.; Mendonça, D. M. H.; Silva, W. P.; Silva, M. N. T.; Nossol, E.; da Silva, R. A. B.; Richter, E. M.; Muñoz, R. A. A.; Anal. Chim. Acta 2018, 1033, 49.
-
17Richter, E. M.; Rocha, D. P.; Cardoso, R. M.; Keefe, E. M.; Foster, C. W.; Munoz, R. A. A.; Banks, C. E.; Anal. Chem. 2019, 91, 12844.
-
18Rocha, D. P.; Rocha, R. G.; Castro, S. V. F.; Trindade, M. A. G.; Munoz, R. A. A.; Richter, E. M.; Angnes, L.; Electrochem. Sci. Adv., in press, DOI: 10.1002/elsa.202100136.
» https://doi.org/10.1002/elsa.202100136 -
19Rocha, D. P.; Squissato, A. L.; da Silva, S. M.; Richter, E. M.; Munoz, R. A. A.; Electrochim. Acta 2020, 335, 135688.
-
20Tully, J. J.; Meloni, G. N.; Anal. Chem. 2020, 92, 14853.
-
21Cardoso, R. M.; Castro, S. V. F.; Stefano, J. S.; Muñoz, R. A. A.; J. Braz. Chem. Soc. 2020, 31, 1764.
-
22Cardoso, R. M.; Rocha, D. P.; Rocha, R. G.; Stefano, J. S.; Silva, R. A. B.; Richter, E. M.; Muñoz, R. A. A.; Anal. Chim. Acta 2020, 1132, 10.
-
23de Oliveira, F. M.; de Melo, E. I.; da Silva, R. A. B.; Sens. Actuators, B 2020, 321, 128528.
-
24Veloso, W. B.; Ribeiro, G. A. C.; da Rocha, C. Q.; Tanaka, A. A.; da Silva, I. S.; Dantas, L. M. F.; Measurement 2020, 155, 107516.
-
25Ribeiro, G. A. C.; da Rocha, C. Q.; Veloso, W. B.; Fernandes, R. N.; da Silva, I. S.; Tanaka, A. A.; Microchem. J. 2019, 146, 1249.
-
26Corrêa Ribeiro, G. A.; Quintino da Rocha, C.; Tanaka, A. A.; Santos da Silva, I.; Anal. Methods 2018, 10, 2034.
-
27Higino, G. S.; Machado, Í. R.; Nascimento, G. F.; Pedrotti, J. J.; J. Braz. Chem. Soc. 2021, 32, 2215.
-
28OriginPro, 8.5; OriginLab Corp., Northampton, USA, 2010.
-
29Serqueira, D. S.; Fernandes, D. M.; Cunha, R. R.; Squissato, A. L.; Santos, D. Q.; Richter, E. M.; Munoz, R. A. A.; Fuel 2014, 118, 16.
-
30Ataide, V. N.; Rocha, D. P.; de Siervo, A.; Paixão, T. R. L. C.; Muñoz, R. A. A.; Angnes, L.; Microchim. Acta 2021, 188, 388.
-
31Hung, C. H.; Chang, W. T.; Su, W. Y.; Cheng, S. H.; Electroanalysis 2014, 26, 2237.
-
32Nasr, B.; Hsen, T.; Abdellatif, G.; J. Environ. Manage. 2009, 90, 523.
-
33Cañizares, P.; Lobato, J.; Paz, R.; Rodrigo, M. A.; Sáez, C.; Water Res. 2005, 39, 2687.
-
34Mocak, J.; Bond, A. M.; Mitchell, S.; Scollary, G.; Bond, A. M.; Pure Appl. Chem. 1997, 69, 297.
-
35Knothe, G.; Steidley, K. R.; Fuel Process. Technol. 2018, 177, 75.
-
36Fernandes, D. M.; Squissato, A. L.; Lima, A. F.; Richter, E. M.; Munoz, R. A. A.; Renewable Energy 2019, 139, 1263.
-
37Agência Nacional do Petróleo, Gás Natural e Biocombustíveis (ANP); Resolução No. 842, de 14 de maio de 2021, Estabelece a Especificação do Diesel Verde, bem como as Obrigações Quanto ao Controle da Qualidade a Serem Atendidas Pelos Agentes Econômicos que o Comercializem em Território Nacional; ANP: Rio de Janeiro, 2021, available at https://www.in.gov.br/en/web/dou/-/resolucao-anp-n-842-de-14-de-maio-de-2021-320059616, accessed in January 2022.
» https://www.in.gov.br/en/web/dou/-/resolucao-anp-n-842-de-14-de-maio-de-2021-320059616 -
38Rocha Jr., J. G.; dos Santos, M. D. R.; Madeira, F. B.; Rocha, S. F. L. S.; Bauerfeldt, G. F.; da Silva, W. L. G.; Salomão, A. A.; Tubino, M.; J. Braz. Chem. Soc. 2019, 30, 1751.
-
39de Santana, P. M. B.; Meira, M.; Tentardini, E. K.; Mater. Res. 2015, 18, 164.
-
40Domingos, A. K.; Saad, E. B.; Vechiatto, W. W. D.; Wilhelm, H. M.; Ramos, L. P.; J. Braz. Chem. Soc. 2007, 18, 416.
-
41Ryu, K.; J. Mech. Sci. Technol. 2009, 23, 3105.
-
42Instituto Nacional de Metrologia, Normalização e Qualidade Industrial (INMETRO); DOQ-CGCRE-008, Orientações sobre Validação de Métodos Analíticos, 2020, available at http://www.inmetro.gov.br/Sidoq/Arquivos/Cgcre/DOQ/DOQ-Cgcre-8_05.pdf, accessed in January 2022.
» http://www.inmetro.gov.br/Sidoq/Arquivos/Cgcre/DOQ/DOQ-Cgcre-8_05.pdf -
43Cardoso, R. M.; Dornellas, R. M.; Lima, A. P.; Montes, R. H. O.; Richter, E. M.; Munoz, R. A. A.; J. Braz. Chem. Soc. 2017, 28, 1650.
-
44Araujo, A. S. A.; Caramit, R. P.; Oliveira, L. C. S.; Ferreira, V. S.; Electroanalysis 2015, 27, 1152.
-
45Chýlková, J.; Tomášková, M.; Janíková, L.; Šelešovská, R.; Navrátil, T.; Chudobová, P.; Chem. Pap. 2017, 71, 1047.
-
46Ziyatdinova, G.; Gainetdinova, A.; Morozov, M.; Budnikov, H.; Grazhulene, S.; Red’kin, A.; J. Solid State Electrochem. 2012, 16, 127.
-
47Matemadombo, F.; Apetrei, C.; Nyokong, T.; Rodríguez-Méndez, M. L.; de Saja, J. A.; Sens. Actuators, B 2012, 166-167, 457.
-
48Joao, A. F.; Matias, T. A.; Gomes, J. S.; Guimaraes, R. R.; Sousa, R. M. F.; Munoz, R. A. A.; ACS Sustainable Chem. Eng. 2021, 9, 16052.
Edited by
Publication Dates
-
Publication in this collection
17 June 2022 -
Date of issue
2022
History
-
Received
24 Nov 2021 -
Published
02 Feb 2022