Optimization and Isothermal Studies of Antibiotics Mixture Biosorption From Wastewater Using Palm Kernel, Chrysophyllum albidum, and Coconut Shells Biocomposite

Q4 Environmental Science
Ogundipe S. Opeoluwa, Latinwo G. Kayode, Ayobami O. Ajani, Tinuade J. Afolabi, Idris O. Okeowo, Adetoro R. Olaitan, Abass O. Alade
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Abstract

The presence of persistent pharmaceutical products in water bodies is a significant problem that obstructs wastewater reuse. This study investigated the adsorption process for removing the recalcitrant antibiotics, including tetracycline (TC), ampicillin (AMP), and amoxicillin (AMOX) from an aqueous solution using a composite biosorbent made from a mixture of palm kernel shell (PKS), Chrysophyllum albidum (CAS), and coconut shell (CS). Simplex centroid design in the Design of Expert (12.0.1.0) was applied to optimize the percentage composition (20-55%) of the composite biosorbent precursor and to remove TC-AMP-AMOX mixtures from the aqueous solution in a batch study. The equilibrium data were fitted to 12 isotherm models and analyzed statistically. The maximum adsorption capacity of 9.12 mg/g, 8.66 mg/g, and 7.11 mg/g was achieved for TC, AMP, and AMOX, respectively, using the biocomposite biosorbent with an optimal mixture of 55% PKS, 20% CAS, and 25% CS. The adsorption behavior of TC, AMP, and AMOX was well-described by the Langmuir/Elovich isotherm (R2=1.000), Hill-DeBoer (R2=0.9953), and Freundlich/ Halsey (R2=0.9898) models, respectively. The obtained results showed that the biocomposite PKS-CAS-CS leverages the individual adsorptive capacity of each constituent to enhance the adsorption process. Moreover, the composite biosorbent demonstrated excellent potential for removing recalcitrant pharmaceuticals from wastewater effectively.
棕榈仁、金菊、椰壳复合材料对废水中抗生素混合生物吸附的优化及等温研究
水体中持久性药品的存在是阻碍废水回用的一个重要问题。以棕榈仁壳(PKS)、金菊(CAS)和椰子壳(CS)为原料制备复合生物吸附剂,研究了对水溶液中顽固性抗生素四环素(TC)、氨苄西林(AMP)和阿莫西林(AMOX)的吸附工艺。采用design of Expert(12.0.1.0)中的单纯形质心设计优化复合生物吸附剂前驱体的百分比组成(20-55%),并在批量研究中从水溶液中去除TC-AMP-AMOX混合物。将平衡数据拟合到12个等温线模型中,并进行统计分析。在最佳配比为55% PKS、20% CAS和25% CS的条件下,对TC、AMP和AMOX的最大吸附量分别为9.12 mg/g、8.66 mg/g和7.11 mg/g。Langmuir/Elovich模型(R2=1.000)、Hill-DeBoer模型(R2=0.9953)和Freundlich/ Halsey模型(R2=0.9898)较好地描述了TC、AMP和AMOX的吸附行为。结果表明,生物复合材料PKS-CAS-CS利用了各组分的个体吸附能力来增强吸附过程。此外,复合生物吸附剂在有效去除废水中的顽固性药物方面表现出良好的潜力。
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来源期刊
Avicenna Journal of Environmental Health Engineering
Avicenna Journal of Environmental Health Engineering Environmental Science-Health, Toxicology and Mutagenesis
CiteScore
1.00
自引率
0.00%
发文量
8
审稿时长
8 weeks
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