Green chemistry approach for the removal of delafloxacin from aqueous solutions using calcinated layered double hydroxide: Adsorption mechanism and material characterization

被引:0
作者
Mahgoub, Samar M. [1 ]
Mahmoud, M. Ramadan [2 ]
Hafez, Sarah H. M. [3 ]
Allam, Ahmed A. [4 ]
Alfassam, Haifa E. [5 ]
Abdel-Hady, E. E. [3 ]
Anwar, Alaa A. A. [6 ]
Mahmoud, Rehab [6 ]
机构
[1] Beni Suef Univ, Fac Postgrad Studies Adv Sci, Mat Sci & Nanotechnol Dept, Bani Suwayf, Egypt
[2] Al Azhar Univ, Fac Pharm, Assiut, Egypt
[3] Menia Univ, Fac Sci, Phys Ddept, POB 61519, Al Minya, Egypt
[4] Beni Suef Univ, Fac Sci, Dept Zool, Bani Suwayf 65211, Egypt
[5] Princess Nourah bint Abdulrahman Univ, Coll Sci, Dept Biol, POB 84428, Riyadh 11671, Saudi Arabia
[6] Beni Suef Univ, Fac Sci, Dept Chem, Bani Suwayf 62514, Egypt
来源
SCIENTIFIC AFRICAN | 2025年 / 27卷
关键词
DLX; Calcinated LDH; Adsorption isotherm; Kinetic models; FLUOROQUINOLONE ANTIBIOTICS; METHYLENE-BLUE; CATIONIC DYE; KINETICS; WATER; PHARMACEUTICALS; SORPTION; CARBON; CIPROFLOXACIN; ENVIRONMENT;
D O I
10.1016/j.sciaf.2025.e02535
中图分类号
O [数理科学和化学]; P [天文学、地球科学]; Q [生物科学]; N [自然科学总论];
学科分类号
07 ; 0710 ; 09 ;
摘要
The efficacy of calcinated Layered Double Hydroxide (LDH) was explored as an effective adsorbent for delafloxacin (DLX), which has been identified as one of the most persistent pharmaceuticals found in wastewater because of the increased use of antibiotic drugs in recent decades. The synthesized LDH was characterized via various techniques, including IR spectroscopy, X-ray photoelectron spectroscopy (XPS), X-ray diffraction (XRD), surface analysis via BET, and transmittance electron microscope (TEM) and scanning electron microscopy (SEM). Adsorption investigations revealed that the maximum removal capacity was achieved at pH 7, with an adsorbent dosage of 0.2 g and an optimum temperature of 40 degrees C. Eight nonlinear equilibrium isotherm models were assessed to fit the experimental equilibrium data. The adsorption of DLX conformed well to the Langmuir-Freundlich model, with a high regression value (R2) of 0.99. Additionally, the adsorption process of DLX followed pseudo-second-order kinetics, with an R2 value of approximately 0.99. The maximum adsorption capacity (q_max) for DLX was determined to be 957.82 mg/g. This study investigated the cytotoxic effects of LDH nanoparticles on WI-38 cells, a widely used human lung fibroblast line. The cells were exposed to various concentrations of LDH nanoparticles, and their viability was assessed via the MTT assay. The results indicate concentration-dependent cytotoxicity, suggesting careful consideration of LDH nanoparticle dosage in biomedical applications. Two green metrics were applied: the Analytical Eco-scale and the Analytical GREENness Calculator (AGREE).
引用
收藏
页数:16
相关论文
共 63 条
  • [1] Sungur S., Pharmaceutical and personal care products in the environment: occurrence and impact on the functioning of the ecosystem, Emerg. Contam. Environ., pp. 137-157, (2022)
  • [2] Oluwole A.O., Omotola E.O., Olatunji O.S., Pharmaceuticals and personal care products in water and wastewater: a review of treatment processes and use of photocatalyst immobilized on functionalized carbon in AOP degradation, BMC. Chem., 14, pp. 1-29, (2020)
  • [3] Meyer M.F., Powers S.M., Hampton S.E., An evidence synthesis of pharmaceuticals and personal care products (PPCPs) in the environment: imbalances among compounds, sewage treatment techniques, and ecosystem types, Environ. Sci. Technol., 53, pp. 12961-12973, (2019)
  • [4] Cacace D., Fatta-Kassinos D., Manaia C.M., Cytryn E., Kreuzinger N., Rizzo L., Karaolia P., Schwartz T., Alexander J., Merlin C., Antibiotic resistance genes in treated wastewater and in the receiving water bodies: a pan-European survey of urban settings, Water. Res., 162, pp. 320-330, (2019)
  • [5] Lagesson A., Fahlman J., Brodin T., Fick J., Jonsson M., Bystrom P., Klaminder J., Bioaccumulation of five pharmaceuticals at multiple trophic levels in an aquatic food web-Insights from a field experiment, Sci. Total Environ., 568, pp. 208-215, (2016)
  • [6] Gandra S., Joshi J., Trett A., Lamkang A.S., Laxminarayan R., Scoping report on antimicrobial resistance in India, Cent. Dis. Dyn. Econ. Policy Washington, DC, USA, 2017, pp. 1-146, (2017)
  • [7] Kostich M.S., Batt A.L., Lazorchak J.M., Concentrations of prioritized pharmaceuticals in effluents from 50 large wastewater treatment plants in the US and implications for risk estimation, Environ. Pollut., 184, pp. 354-359, (2014)
  • [8] Kummerer K., Antibiotics in the aquatic environment–a review–part I, Chemosphere, 75, pp. 417-434, (2009)
  • [9] Balakrishna K., Rath A., Praveenkumarreddy Y., Guruge K.S., Subedi B., A review of the occurrence of pharmaceuticals and personal care products in Indian water bodies, Ecotoxicol. Environ. Saf., 137, pp. 113-120, (2017)
  • [10] Akici A., Aydin V., Kiroglu A., Assessment of the association between drug disposal practices and drug use and storage behaviors, Saudi Pharm. J., 26, pp. 7-13, (2018)
1234567