拉曼光谱分析用于监测阿司匹林暴露于等离子火焰后的化学成分

Q4 Chemistry Spectroscopy Europe Pub Date : 2022-01-01 DOI:10.1255/sew.2022.a15
J. Jamur
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引用次数: 1

摘要

为了提高药品的稳定性,确定降解产物和杂质是否具有毒性,需要进一步了解药品降解结构的细节。温度在我们的生活中是一个重要的组成部分,尤其是在气候系统中,在化合物的化学变化中起着关键作用。由于暴露在等离子体火焰温度下,一些药物化合物被破坏或产生有毒化学物质暴露于这些温度已被证明与人类健康的不利影响直接和间接相关。因此,这些快速的变化对化学化合物对环境和生物的影响产生了严重的影响各种分析技术,如近红外(NIR),傅里叶变换红外(FT-IR),核磁共振(NMR)和高效液相色谱(HPLC)已被用于分析药物固体化合物最近,研究人员研究了温度对药物样品稳定性的影响。Al-Maydama等人通过HPLC、光催化、x射线衍射(XRD)和扫描电子显微镜(SEM)等方法研究了阿司匹林样品在40°C下经过300 W UV-A灯照射12小时后的热稳定性,发现阿司匹林样品的热稳定性低于未处理样品在Acharya等人的研究中,成功应用IR、质谱和1H NMR等方法对阿司匹林与水杨酸相互作用得到的热降解产物进行了分析。本研究证实了新热降解产物的结构与阿司匹林和水杨酸的结构不同用高效液相色谱法研究了青蒿素C和对香豆酸经高温处理后的化学成分,发现其稳定性受到影响然而,高效液相色谱法价格昂贵,运行时间长,消耗溶剂。在Johnsiani等人的研究中,利用核磁共振、四倍飞行时间质谱(Q-TOF/MS)和电喷雾电离碰撞诱导解离串联质谱(ESI-CID-MS/MS)等技术研究了暴露在不同应激条件下(包括温度)后tosylate索拉非尼的降解Vishnuvardhan和他的同事已经证明,这种药物有明显的降解
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Raman spectroscopy analysis for monitoring of chemical composition of aspirin after exposure to plasma flame
Introduction Further details about the degradation structure of pharmaceutical products are required to improve their stability and determine whether the degradation products and impurities have any toxicity.1–4 Temperature is an important component in much of our lives, not least in the climate system, and plays a key role in the chemical change of compounds. Some pharmaceutical compounds are damaged or toxic chemicals produced due to exposure at plasma flame temperatures.5 Exposure to these temperatures has been shown to be related to adverse effects in human health both directly and indirectly. Therefore, these rapid changes are having a serious effect on the environmental and biological impacts of chemical compounds.6 Various analytical techniques such as near infrared (NIR), Fourier transform infrared (FT-IR), nuclear magnetic resonance (NMR) and high-performance liquid chromatography (HPLC) have been used to analyse pharmaceutical solid compounds.7 Recently, investigators have examined the effects of temperature on the stability of pharmaceutical samples. The thermal stability of aspirin samples after treatment at 40 °C and exposure to a 300 W UV-A lamp for 12 h was studied by Al-Maydama et al. and found to be lower to that of the untreated samples using HPLC, photocatalytic, X-ray diffraction (XRD) and scanning electron microscopy (SEM) methods.8 In the study by Acharya and co-workers, IR, mass spectrometry and 1H NMR methods were successfully applied for analysis of the thermal degradation product obtained from the interaction of aspirin and salicylic acid. This study confirmed that the structure of the new thermal degradation product is different to those of aspirin and salicylic acid.9 The chemical composition of artepillin C and p-coumaric acid was investigated using HPLC after exposure to high temperature and it showed that the stability of these compounds was affected.10 However, HPLC is expensive, has long run times and consumes solvents. In the study by Johnsiani et al., several techniques such as NMR, quadruple time-of-flight mass spectrometry (Q-TOF/MS) and electrospray ionisation collision-induced dissociation tandem mass spectrometry (ESI-CID-MS/MS) were used to study the degradation of sorafenib tosylate after exposure to different stress conditions including temperature.11 Vishnuvardhan and co-workers have shown there was significant degradation of the drug DOI: 10.1255/sew.2022.a15
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Spectroscopy Europe
Spectroscopy Europe Chemistry-Analytical Chemistry
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期刊介绍: Spectroscopy Europe is the only European publication dedicated to all areas of Spectroscopy. It publishes a wide range of articles on the latest developments, interesting and important applications, new techniques and the latest development in the field. This controlled-circulation magazine is available free-of-charge to qualifying individuals engaged in spectroscopy within Europe. Includes regular news, a comprehensive diary of events worldwide, product introductions, meeting reports, book reviews and regular columns on chemometrics, data handling, process spectroscopy and reference materials.
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