Degradation kinetics and prediction of primary intermediates of cephalexin in aqueous media

IF 2.1 4区 化学 Q3 CHEMISTRY, MULTIDISCIPLINARY
Seyda Aydogdu, Arzu Hatipoglu
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引用次数: 0

Abstract

The presence of pharmaceuticals such as the antibiotic cephalexin in aqueous environments increases public health concerns due to their adverse biological effects and antibiotic resistance. It may be promising to remove these compounds from the aquatic environment through degradation reactions that convert them into non-toxic products. For this purpose, Density Functional Theory (DFT) molecular orbital calculations were performed to investigate the kinetics and mechanism of the degradation reaction of cephalexin with the hydroxyl (OH) radical. Reaction rate constants and branching ratios for 11 different reaction paths were calculated in the temperature range of 200 to 400 K. The total rate constant was calculated as 7.05 × 109 M−1 s−1 and is in good agreement with the experimental value. According to the kinetic and thermodynamic results, it can be concluded that the hydroxyl radical preferentially attacks the beta-lactam ring. The effect of water on the reaction mechanism was investigated in both implicit and explicit solvation models. Explicitly added water molecules affect the degradation reaction kinetic so that the results become compatible with the experimental ones. Ecotoxicity and bioaccumulation calculations on cephalexin and its degradation products show that some of its degradation products are harmful.

Abstract Image

头孢氨苄在水介质中的降解动力学及主要中间产物的预测
水环境中存在抗生素头孢菌素等药物,会产生不良的生物效应和抗生素耐药性,从而增加公众对健康的担忧。通过降解反应将这些化合物转化为无毒产品,从而将其从水生环境中去除,可能是一个很有前景的方法。为此,我们进行了密度泛函理论(DFT)分子轨道计算,以研究头孢菌素与羟基(OH)自由基发生降解反应的动力学和机理。计算得出的总速率常数为 7.05 × 109 M-1 s-1,与实验值十分吻合。根据动力学和热力学结果,可以得出羟基自由基优先攻击β-内酰胺环的结论。在隐式和显式溶解模型中研究了水对反应机理的影响。显式添加的水分子会影响降解反应动力学,从而使结果与实验结果相一致。对头孢氨苄及其降解产物进行的生态毒性和生物累积计算表明,其中一些降解产物是有害的。
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来源期刊
Structural Chemistry
Structural Chemistry 化学-化学综合
CiteScore
3.80
自引率
11.80%
发文量
227
审稿时长
3.7 months
期刊介绍: Structural Chemistry is an international forum for the publication of peer-reviewed original research papers that cover the condensed and gaseous states of matter and involve numerous techniques for the determination of structure and energetics, their results, and the conclusions derived from these studies. The journal overcomes the unnatural separation in the current literature among the areas of structure determination, energetics, and applications, as well as builds a bridge to other chemical disciplines. Ist comprehensive coverage encompasses broad discussion of results, observation of relationships among various properties, and the description and application of structure and energy information in all domains of chemistry. We welcome the broadest range of accounts of research in structural chemistry involving the discussion of methodologies and structures,experimental, theoretical, and computational, and their combinations. We encourage discussions of structural information collected for their chemicaland biological significance.
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