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Tytuł artykułu

Removal of Amoxicillin from an Aqueous Solution by Activated Carbon Prepared from Biomass

Treść / Zawartość
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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Amoxicillin type Amox-500 is a β-lactam antibiotic belonging to the penicillin family, used to treat infections caused by bacteria. This drug has been, purified by the slow recrystallization method and characterized by RAMAN. The treatment of antibiotic-laden effluent is of interest for environmental protection, which is why the field of wastewater treatment is essential for the protection of our environment. In our research, we studied the elimination of amoxicillin as a trace pollutant in untreated wastewater discharges in an aqueous solution prepared in the laboratory, using activated carbon made from banana peel. We also showed the presence of these pharmaceutical pollutants (amoxicillin and paracetamol) in wastewater from the Dradeb area of the city of Tangier in Morocco. In this research, we took advantage of the use of activated carbon, which has been, previously treated in our laboratory for a study, which is, published [Abdellah Touijer et al, 2023]. The amount of amoxicillin adsorption is influenced by various operating parameters, and with the help of a parametric study, we have deduced the best conditions from these parameters to promote good amoxicillin adsorption yield. The amount adsorbed at equilibrium increases proportionally with amoxicillin concentration, and equilibrium is reached after the first 20 min. The maximum equilibrium amoxicillin adsorption capacity (qe) is 35 mg/g for PBC600 (banana peel carbonized at 600°C for 60 min) and PBC700 (banana peel carbonized at 700 °C for 60 min), and 25 mg/g for PBC500 (banana peel carbonized at 500 °C for 60 min). Under the following operating conditions: C0 = 20 mg/l, temperature 20±5 °C, pH=6 lower than pHpzc, adsorbent/adsorbat ratio 0.5 mg/ml, stirring time 45 min. The best adsorption efficiency was 85.2% for PBC700, 79.31% for PBC600 and 12.47% for PBC500, indicating that the amount of amoxicillin adsorbed at equilibrium is proportional to the carbonization temperature. The theoretical study of the adsorption isotherm of amoxicillin on activated carbon prepared from banana peel shows that the Langmuir, Freundlich and Temkin models describe this adsorption phenomenon well, similar to the experimental results. Adsorption of amoxicillin follows a pseudo-second-order kinetic model. Thermodynamic analysis has shown that standard enthalpy (ΔH°), standard free enthalpy (ΔG°), and free entropy (ΔS°) are negative values, allowing us to say that this adsorption process is spontaneous and favorable, meaning the decrease in disorder.
Słowa kluczowe
Rocznik
Strony
63--79
Opis fizyczny
Bibliogr. 34 poz., rys., tab.
Twórcy
  • Laboratory of Organic Chemistry, Catalysis and Environment, Department of Chemistry, Faculty of Sciences, Ibn Tofaïl University, B.P. 133, 14000 Kenitra, Morocco
  • Laboratoiry of Physical Chemistry of Materials, Naturel Substances and Environment (UAE/U16FST), Department of Chemistry, Faculty af Sciences and Technology of Tangier, Old Airport Road, Km 10, Ziaten, B.P. 416, Tangier, Morocco
  • Laboratoiry of Physical Chemistry of Materials, Naturel Substances and Environment (UAE/U16FST), Department of Chemistry, Faculty af Sciences and Technology of Tangier, Old Airport Road, Km 10, Ziaten, B.P. 416, Tangier, Morocco
  • Laboratoiry of Physical Chemistry of Materials, Naturel Substances and Environment (UAE/U16FST), Department of Chemistry, Faculty af Sciences and Technology of Tangier, Old Airport Road, Km 10, Ziaten, B.P. 416, Tangier, Morocco
autor
  • Laboratory of Organic Chemistry, Catalysis and Environment, Department of Chemistry, Faculty of Sciences, Ibn Tofaïl University, B.P. 133, 14000 Kenitra, Morocco
  • Laboratory of Organic Chemistry, Catalysis and Environment, Department of Chemistry, Faculty of Sciences, Ibn Tofaïl University, B.P. 133, 14000 Kenitra, Morocco
  • Laboratory of Organic Chemistry, Catalysis and Environment, Department of Chemistry, Faculty of Sciences, Ibn Tofaïl University, B.P. 133, 14000 Kenitra, Morocco
Bibliografia
  • 1. Adak, A., Bandyopadhyay, M., Pal, M. 2005. Removal of anionic surfactant from wastewater from alumina: A case study. Colloids and Surfaces A, 254(2005), 165–171.
  • 2. Al-Khateeb, L.A., Almotiry, S., Salam, M.A. 2014. Adsorption of pharmaceutical pollutants onto graphene nanoplatelets, Chem. Eng. J., 248(2014), 191–199.
  • 3. Allahdin, O., Wartel, M., Mabingui, J., Boughriet, A. 2015. Implication of Electrostatic Forces on the Adsorption Capacity of a Modified Brick for the Removal of Divalent Cations from Water. American Journal of Analytical Chemistry, 6(1), 11–25.
  • 4. Antunes, M., Esteves, V.I., Guégan, R., Crespo, J.S., Fernandes, A.N., Giovanela, M. 2012. Removal of diclofenac sodium from aqueous solution by Isabel grape bagasse, Chem. Eng. J., 192(2012), 114–121.
  • 5. Arivoli, S. 2009. Adsorption of malachite green onto carbon prepared from borassus bark. Arabian Journal for Science and Engineering, 34(2), 31–42.
  • 6. Aubry, C., Bouloc, P., Bury-Moné, S. 2018. Degradation of an anticancer agent in wastewater: a gold medal for the GO Paris-Saclay team. Med Sci (Paris), 34(12), 1111–1114.
  • 7. Cuerda-Correa, E.M., Domínguez- Vargas, J.R., Olivares-Marín, F.J., de Heredia, J.B. 2010. On the use of carbon blacks as potencial low-cost adsorbents for the removal of non-steroidal anti-inflammatory drugs from river waters. Journal of Hazardous Materials, 177(2010), 1046–1053.
  • 8. Ferreira, R.C., Couto Jr. O.M., Carvalho, K.Q., Arroyo, P.A., Barros, M.A.S.D. 2015. Effect of solution pH on the removal of paracetamol by activated of dende coconut mesocarp, Chem. Biochem. Eng. Q., 29(2015), 47–53.
  • 9. Ghanbari, R., Amanat, N. 2022. Approaches of Membrane Modification for Water Treatment. Mater. Chem. Horizons, 1, 153–167.
  • 10. Gimbert, F. et al. 2008. Adsorption isotherm models for dye removal by cationized starch-based material in a single component system: Error analysis. Journal of Hazardous Materials, 157(1), 34–46.
  • 11. Goldberg, S. 2005. Equations and Models Describ- ing Adsorption Processes in Soils. Soil Science Society of America, 677 S. Segoe Road, Madison, WI, 53711, USA. Chemical Processes in Soils. SSSA Book Series, no. 8, California, USA.
  • 12. Hall, K.R., Eagleton, L.C., Acrivos, A., et al. 1996. Pore- and Solid-Diffusion Kinetics in Fixed-Bed Adsorption under Constant-Pattern Conditions. American Chemical Society, 5(2), 212–223
  • 13. Ho, Y.S., McKay, G. 1999. Pseudo-second order model for sorption processes. Process Biochemistry, 34(5), 451–465.
  • 14. Ho, Y.S., Mckay, G. 1999. Pseudo-second order model for sorption processes. Process Biochemistry, 34(1999), 451–465.
  • 15. Hu, D., Wang, L. 2016. Adsorption of amoxicillin onto quaternized cellulose from flax noil: kinetic, equilibrium and thermodynamic study. J. Taiwan Inst Chem Eng, 64, 227–234.
  • 16. Joshi S. 2002. HPLC separation of antibiotics present in formulated and unformulated samples. J Pharm Biomed Anal, 28(5), 795–809.
  • 17. Limousy, L., Ghouma, I., Ouederni, A., Jeguirim, M. 2017. Amoxicillin removal from aqueous solution using activated carbon prepared by chemical activation of olive stone. Environ Sci Pollut Res, 24(11), 9993–10004.
  • 18. Mohan, S., Karthikeyan, J. 1997. Removal of lignin and tannin color from aqueous solution by adsorption onto activated charcoal. Environmental Pollution, 97(1–2), 183–187.
  • 19. Nasseh, N., Barikbin, B., Taghavi, L., Nasseri, M.A. 2019. Adsorption of metronidazole antibiotic using a new magnetic nanocomposite from simulated wastewater (isotherm, kinetic and thermodynamic studies). Compos. Part B Eng., 159, 146–156.
  • 20. Neghi, N., Krishnan, N.R., Kumar, M. 2018. Analy- sis of metronidazole removal and micro-toxicity in photolytic systems: Effects of persulfate dosage, anions and reactor operation-mode. J. Environ. Chem. Eng., 6, 754–761.
  • 21. Newcombe, G., Donati, C., Drikas, M., Hayes, R. 1996. Adsorption onto activated carbon: electrostatic and non-electrostatic interactions. Water Supply, 14(2), 129–144.
  • 22. Riviere, J.E., Craigmill, A.L., Sundlof, S.F. 1996. Handbook of comparative pharmacokinetics and residues of veterinary antimicrobials. Boca Raton CRC, U.S Florida.
  • 23. Rodríguez-Chueca, J., Della Giustina, S.V., Rocha, J., et al 2019. Assessment of full-scale tertiary wastewater treatment by UV-C based-AOPs: Removal or persistence of antibiotics and antibiotic resistance genes? Sci. Total Environ, 652, 1051–1061.
  • 24. Silva, E.K., Borges, S.V., da Costa, J.M.G., Queiroz, F. 2015. Thermodynamic properties, kinetics and adsorption mechanisms of Swiss cheese bioaroma powder. Powder Technology, 272(2015), 181–188.
  • 25. Singh, D. 2000. Studies of the adsorption thermo-dynamics of oxamyl on fly ash. Adsorption Science & Technology, 18(8), 741–748.
  • 26. Ternes, T. 2001. Pharmaceuticals and metabolites as contaminants of aquatic environment: An overview. Journal of the American Chemical Society, 791(13), 39–54.
  • 27. Thabet, M.S., Ismaiel, A.M. 2016. Sol-Gel γ-Al2O3 Nanoparticles Assessment of the Removal of Eosin Yellow Using: Adsorption, Kinetic and Thermody dynamic Parameters. Journal of Encapsulation and Adsorption Sciences, 6(3), 70–90.
  • 28. Thouria, B., Ammar, S., Djaafar, D. 1018. Adsorption of copper (II) ions from aqueous solution using bottom ash of expired drugs incineration. Adsorption Science & Technology, 36(1–2), 114–129.
  • 29. Tiwari, B., Sellamuthu, B., Ouarda, Y., Drogui, P., Tyagi, R.D., Buelna, G. 2017. Review on fate and mechanism of removal of pharmaceutical pollutants from wastewater using biological approach. Bioresour. Technol, 224, 1–12.
  • 30. Touijer, A., et al. 2023. Adsorption of Acetaminophen on Activated Carbon Prepared Based on Banana Peel. Indian Journal of Environmental Protection, 43(5), 397–399.
  • 31. Valix, M., Cheung, W.H., Zhang, K. 2006. Roleof heteroatoms in activated carbon for removal of hexavalent chromium wastewaters. Journal of hazardous Materials, B135, 395–405.
  • 32. Voudrias, E., Fytianos, F., Bozani, E. 2002. Sorption Description isotherms of Dyes from aqueous solutions and Wastewaters with Different Sorbent materials. Global Nest: The Int. J., 4(1), 75–83.
  • 33. Wise, R. 2002. Antimicrobial resistance: Priorities for action. The Journal of Antimicrobial Chemo- therapy, 49(4), 585–586.
  • 34. Zhu, J., Tian, M., Zhang, Y., Zhang, H., Liu, J. 2015. Fabrication of a novel “loose” nanofiltration membrane by facile blending with Chitosan–Montmorillonite nanosheets for dyes purification. Chem. Eng. J., 265, 184–193.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-e5ac9363-6584-4741-b0e7-adc6ffe602ab
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