This study investigates the effects of boron concentration on boron-doped diamond (BDD) electrodes for electrochemical sensors of ciprofloxacin. The effects of boron concentration, scan rate, and pH of BDD electrodes with boron concentrations of 0.1, 0.5, and 1% were examined to determine the optimal conditions. Furthermore, square wave voltammetry (SWV) in phosphate buffer pH 7 was used to analyze the electrochemical behavior of ciprofloxacin. The results revealed a linear calibration curve in the concentration range of 30–100 μM with a recovery of 85–110%. Meanwhile, BDD electrode with the highest boron concentration in this experiment (1%) showed a very low limit of detection of 0.17 μM, meaning that 1% BDD gave a highly sensitive and significant measurement result for the electrochemical sensor of ciprofloxacin. With the results given, this study provides new insights for controlling boron concentrations in diamond electrodes for the electrochemical sensors of quinolone antibiotics.

[1] Zhang, G.F., Liu, X., Zhang, S., Pan, B., and Liu, M.L., 2018, Ciprofloxacin derivatives and their antibacterial activities, Eur. J. Med. Chem., 146, 599–612.

[2] Gayen, P., and Chaplin, B.P., 2016, Selective electrochemical detection of ciprofloxacin with a porous nafion/multi-walled carbon nanotube composite film electrode, ACS Appl. Mater. Interfaces, 8 (3), 1615–1626.

[3] Gissawong, N., Srijaranai, S., Boonchiangma, S., Uppachai, P., Seehamart, K., Jantrasee, S., Moore, E., and Mukdasai, S., 2021, An electrochemical sensor for voltammetric detection of ciprofloxacin using a glassy carbon electrode modified with activated carbon, gold nanoparticles and supramolecular solvent, Microchim. Acta, 188 (6), 208.

[4] Reddy, K.R., Brahman, P.K., and Suresh, L., 2018, Fabrication of high performance disposable screen printed electrochemical sensor for ciprofloxacin sensing in biological samples, Measurement, 127, 175–186.

[5] Faria, L.V., Pereira, J.F.S., Azevedo, G.C., Matos, M.A.C., Munoz, R.A.A., and Matos, R.C., 2019, Square-wave voltammetry determination of ciprofloxacin in pharmaceutical formulations and milk using a reduced graphene oxide sensor, J. Braz. Chem. Soc., 30, 1947–1954.

[6] Radičová, M., Behúl, M., Marton, M., Vojs, M., Bodor, R., Redhammer, R., and Vojs Staňová, A., 2017, Heavily boron doped diamond electrodes for ultra sensitive determination of ciprofloxacin in human urine, Electroanalysis, 29 (6), 1612–1617.

[7] Girardi, C., Greve, J., Lamshöft, M., Fetzer, I., Miltner, A., Schäffer, A., and Kästner, M., 2011, Biodegradation of ciprofloxacin in water and soil and its effects on the microbial communities, J. Hazard. Mater., 198, 22–30.

[8] Hu, X., Goud, K.Y., Kumar, V.S., Catanante, G., Li, H., Zhu, Z., and Marty, J.L., 2018, Disposable electrochemical aptasensor based on carbon nanotubes-V₂O₅-chitosan nanocomposite for detection of ciprofloxacin, Sens. Actuators, B, 268, 278–286.

[9] Vella, J., Busuttil, F., Bartolo, N.S., Sammut, C., Ferrito, V., Serracino-Inglott, A., Azzopardi, L.M., and LaFerla, G., 2015, A simple HPLC-UV method for the determination of ciprofloxacin in human plasma, J. Chromatogr. B, 989, 80–85.

[10] Pascual-Reguera, M.I., Pérez Parras, G., and Molina Dı́az, A., 2004, A single spectroscopic flow-through sensing device for determination of ciprofloxacin, J. Pharm. Biomed. Anal., 35 (4), 689–695.

[11] Fotouhi, L., and Alahyari, M., 2010, Electrochemical behavior and analytical application of ciprofloxacin using a multi-walled nanotube composite film-glassy carbon electrode, Colloids Surf., B, 81 (1), 110–114.

[12] Xu, X., Liu, L., Jia, Z., and Shu, Y., 2015, Determination of enrofloxacin and ciprofloxacin in foods of animal origin by capillary electrophoresis with field amplified sample stacking–sweeping technique, Food Chem., 176, 219–225.

[13] Forster, R.J., Walsh, D., and Adamson, K., 2019, "Voltammetry | Overview" in Encyclopedia of Analytical Science, 3^rd Ed., Eds. Spain, E., Worsfold, P., Poole, C., Townshend, A., and Miró, M., Academic Press, Oxford, UK, 209–217.

[14] Martin Santos, A., Wong, A., Araújo Almeida, A., and Fatibello-Filho, O., 2017, Simultaneous determination of paracetamol and ciprofloxacin in biological fluid samples using a glassy carbon electrode modified with graphene oxide and nickel oxide nanoparticles, Talanta, 174, 610–618.

[15] Kawde, A.N., Aziz, M.A., Odewunmi, N., Hassan, N., and AlSharaa, A., 2014, Electroanalytical determination of antibacterial ciprofloxacin in pure form and in drug formulations, Arabian J. Sci. Eng., 39 (1), 131–138.

[16] Cinková, K., Andrejčáková, D., and Švorc, Ľ., 2016, Electrochemical method for point-of-care determination of ciprofloxacin using boron-doped diamond electrode, Acta Chim. Slovaca, 9 (2), 146–151.

[17] Xu, J., Natsui, K., Naoi, S., Nakata, K., and Einaga, Y., 2018, Effect of doping level on the electrochemical reduction of CO₂ on boron-doped diamond electrodes, Diamond Relat. Mater., 86, 167–172.

[18] Jiwanti, P.K., and Einaga, Y., 2020, Further study of CO₂ electrochemical reduction on palladium modified bdd electrode: Influence of electrolyte, Chem. - Asian J., 15 (6), 910–914.

[19] Diksy, Y., Rahmawati, I., Jiwanti, P.K., and Ivandini, T.A., 2020, Nano-Cu modified Cu and Nano-Cu modified graphite electrodes for chemical oxygen demand sensors, Anal. Sci., 36, 1323–1330.

[20] Putri, Y.M.T.A., Jiwanti, P.K., Irkham, I., Gunlazuardi, J., Einaga, Y., and Ivandini, T.A., 2021, Nickel-cobalt modified boron-doped diamond as an electrode for a urea/H₂O₂ fuel cell, Bull. Chem. Soc. Jpn., 94 (12), 2922–2928.

[21] Ivandini, T.A., Ariani, J., Jiwanti, P.K., Saepudin, E., and Einaga, Y., 2017, Electrochemical detection of neuraminidase based on zanamivir inhibition reaction at platinum and platinum-modified boron-doped diamond electrodes, Makara J. Sci., 21, 34–42.

[22] Song, Y., and Swain, G.M., 2007, Total inorganic arsenic detection in real water samples using anodic stripping voltammetry and a gold-coated diamond thin-film electrode, Anal. Chim. Acta, 593 (1), 7–12.

[23] Watanabe, T., Honda, Y., Kanda, K., and Einaga, Y., 2014, Tailored design of boron-doped diamond electrodes for various electrochemical applications with boron-doping level and sp²-bonded carbon impurities, Phys. Status Solidi A, 211 (12), 2709–2717.

[24] dos Santos, A.J., Fortunato, G.V., Kronka, M.S., Vernasqui, L.G., Ferreira, N.G., and Lanza, M.R.V., 2021, Electrochemical oxidation of ciprofloxacin in different aqueous matrices using synthesized boron-doped micro and nano-diamond anodes, Environ. Res., 204, 112027.

[25] Schwarzová-Pecková, K., Vosáhlová, J., Barek, J., Šloufová, I., Pavlova, E., Petrák, V., and Zavázalová, J., 2017, Influence of boron content on the morphological, spectral, and electroanalytical characteristics of anodically oxidized boron-doped diamond electrodes, Electrochim. Acta, 243, 170–182.

[26] Kingsley, M.P., Kalambate, P., and Srivastava, A.K., 2016, Simultaneous determination of ciprofloxacin and paracetamol by adsorptive stripping voltammetry using copper zinc ferrite nanoparticles modified carbon paste electrode, RSC Adv., 6 (18), 15101–15111.

[27] Zeng, Y., Chen, D., Chen, T., Cai, M., Zhang, Q., Xie, Z., Li, R., Xiao, Z., Liu, G., and Lv, W., 2019, Study on heterogeneous photocatalytic ozonation degradation of ciprofloxacin by TiO₂/carbon dots: Kinetic, mechanism and pathway investigation, Chemosphere, 227, 198–206.

[28] Voigtman, E., 2017, Limits of Detection in Chemical Analysis, John Wiley & Sons, Hoboken, New Jersey, US.

[29] Švorc, Ĺ., Jambrec, D., Vojs, M., Barwe, S., Clausmeyer, J., Michniak, P., Marton, M., and Schuhmann, W., 2015, Doping level of boron-doped diamond electrodes controls the grafting density of functional groups for DNA assays, ACS Appl. Mater. Interfaces, 7 (34), 18949–18956.

[30] Matsunaga, T., Kondo, T., Osasa, T., Kotsugai, A., Shitanda, I., Hoshi, Y., Itagaki, M., Aikawa, T., Tojo, T., and Yuasa, M., 2020, Sensitive electrochemical detection of ciprofloxacin at screen-printed diamond electrodes, Carbon, 159, 247–254.