Thermoanalytical and Kinetic Studies for the Thermal Stability of Emerging Pharmaceutical Pollutants Under Different Heating Rates.

IF 6.8 Q1 TOXICOLOGY

Journal of Xenobiotics Pub Date : 2024-11-14 DOI:10.3390/jox14040095

Christian Ebere Enyoh, Tochukwu Oluwatosin Maduka, Miho Suzuki, Senlin Lu, Qingyue Wang

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引用次数: 0

Abstract

Emerging pharmaceutical pollutants like ciprofloxacin (CIP) and ibuprofen (IBU) are frequently detected in aquatic environments, posing risks to ecosystems and human health. Since pollutants rarely exist alone in the environment, understanding the thermal stability and degradation kinetics of these compounds, especially in mixtures, is crucial for developing effective removal strategies. This study therefore investigates the thermal stability and degradation kinetics of CIP and IBU, under different heating rates. Thermogravimetric analysis (TGA) and differential thermal analysis (DTA) were employed to examine the thermal behavior of these compounds individually and in mixture (CIP + IBU) at heating rates of 10, 20, and 30 °C/min. The kinetics of thermal degradation were analyzed using both model-fitting (Coats-Redfern (CR)) and model-free (Kissinger-Akahira-Sunose (KAS), Flynn-Wall-Ozawa (FWO), and Friedman (FR)) methods. The results showed distinct degradation patterns, with CIP decomposing between 280 and 550 °C and IBU between 152 and 350 °C, while the mixture exhibited multistep decomposition in the 157-500 °C range. The CR model indicated first-order kinetics as a better fit for the degradation (except for IBU). Furthermore, CIP exhibits higher thermal stability and activation energy compared to IBU, with the KAS model yielding activation energies of 58.09 kJ/mol for CIP, 11.37 kJ/mol for IBU, and 41.09 kJ/mol for CIP + IBU mixture. The CIP + IBU mixture generally showed intermediate thermal properties, suggesting synergistic and antagonistic interactions between the compounds. Thermodynamic parameters (ΔH°, ΔG°, ΔS°) were calculated, revealing non-spontaneous, endothermic processes for all samples (except in the FWO method) with a decrease in molecular disorder and positive ΔG° values across all models and heating rates. The study found that higher heating rates led to less thermodynamically favorable conditions for degradation. These findings provide important information concerning the thermal behavior of these pharmaceutical pollutants, which can inform strategies for their removal from the environment and the development of more effective waste-treatment processes.

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不同加热速率下新兴制药污染物热稳定性的热分析和动力学研究。

水生环境中经常检测到环丙沙星（CIP）和布洛芬（IBU）等新出现的药物污染物，对生态系统和人类健康构成威胁。由于污染物很少单独存在于环境中，因此了解这些化合物（尤其是混合物）的热稳定性和降解动力学对于制定有效的去除策略至关重要。因此，本研究调查了 CIP 和 IBU 在不同加热速率下的热稳定性和降解动力学。研究人员采用热重分析（TGA）和差热分析（DTA）方法，在 10、20 和 30 °C / 分钟的加热速率下，研究了这两种化合物单独和混合物（CIP + IBU）的热行为。采用模型拟合法（Coats-Redfern (CR)）和无模型法（Kissinger-Akahira-Sunose (KAS)、Flynn-Wall-Ozawa (FWO) 和 Friedman (FR)）分析了热降解动力学。结果显示了不同的降解模式，CIP 在 280 至 550 °C 之间分解，IBU 在 152 至 350 °C 之间分解，而混合物在 157 至 500 °C 范围内呈现多级分解。CR 模型表明，一阶动力学更适合降解（IBU 除外）。此外，与 IBU 相比，CIP 表现出更高的热稳定性和活化能，KAS 模型得出 CIP 的活化能为 58.09 kJ/mol，IBU 为 11.37 kJ/mol，CIP + IBU 混合物为 41.09 kJ/mol。CIP + IBU 混合物一般表现出中等热特性，表明化合物之间存在协同和拮抗作用。通过计算热力学参数（ΔH°、ΔG°、ΔS°），发现所有样品（除 FWO 方法外）都有非自发的内热过程，分子无序度降低，ΔG° 值在所有模型和加热速率下都为正值。研究发现，加热速率越高，降解的热力学条件越不利。这些发现提供了有关这些药物污染物热行为的重要信息，可为从环境中清除这些污染物和开发更有效的废物处理工艺提供参考。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Xenobiotics TOXICOLOGY-

CiteScore

5.30

自引率

1.70%

发文量

审稿时长

10 weeks

期刊介绍： The Journal of Xenobiotics publishes original studies concerning the beneficial (pharmacology) and detrimental effects (toxicology) of xenobiotics in all organisms. A xenobiotic (“stranger to life”) is defined as a chemical that is not usually found at significant concentrations or expected to reside for long periods in organisms. In addition to man-made chemicals, natural products could also be of interest if they have potent biological properties, special medicinal properties or that a given organism is at risk of exposure in the environment. Topics dealing with abiotic- and biotic-based transformations in various media (xenobiochemistry) and environmental toxicology are also of interest. Areas of interests include the identification of key physical and chemical properties of molecules that predict biological effects and persistence in the environment; the molecular mode of action of xenobiotics; biochemical and physiological interactions leading to change in organism health; pathophysiological interactions of natural and synthetic chemicals; development of biochemical indicators including new “-omics” approaches to identify biomarkers of exposure or effects for xenobiotics.