Dielectric Spectroscopy in Ibuprofen-Dioxane Mixture

Pharmaceutica Analytica Acta Pub Date : 2017-12-29 DOI:10.4172/2153-2435.1000572

M. Saini

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引用次数: 3

Abstract

In recent years, the dielectric study of amorphous pharmaceuticals has made a considerable effort towards correlating the molecular mobility with their physical and chemical stability. The molecular mobility of amorphous materials is affected by temperature, additives (such as water) and specific interactions (such as Hydrogen bond). Therefore, to understand the physicochemical instability of amorphous materials, nature of their molecular mobility needs to comprehend. In this order, the Dielectric and Calorimetric measurements were performed on a mixture of ibuprofen and 1,4-dioxane. The dielectric spectroscopy reveals two relaxation processes, (designated as αD, and α) in the supercooled region. The spectral shape of αD and α process can be explained satisfactorily throughout the frequency range using Havriliak-Negami (HN) shape function. The αD process is found to be Debye-like (i.e., αHN=0 and βHN=1) in nature and α process kinetically freezes at Tg-onset (DSC) implies that α- process indeed corresponds to the glass transition event. Both processes are found to be non-Arrhenius in nature. In addition, two secondary relaxation processes (designated as βJG and β) are observed and are comparable with the literature. The activation energy of β process indicates that it‟s originating from the fluctuations of the side group larger than -OH group. Also, the calculated fragility index demonstrates that ibuprofen is a fragile glass former.

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布洛芬-二恶烷混合物的介电光谱

近年来，非晶态药物的介电研究在将分子迁移率与其物理和化学稳定性联系起来方面做出了相当大的努力。非晶材料的分子迁移率受温度、添加剂(如水)和特定相互作用(如氢键)的影响。因此，要了解非晶材料的物理化学不稳定性，就需要了解其分子迁移性的性质。按照这个顺序，对布洛芬和1,4-二恶烷的混合物进行介电和量热测量。介电光谱显示过冷区有两个弛豫过程(α d和α)。利用Havriliak-Negami (HN)形状函数可以很好地解释α d和α过程在整个频率范围内的谱形。α- d过程具有debye样(α hn =0， βHN=1)性质，α过程在Tg-onset (DSC)时动态冻结，表明α-过程确实对应于玻璃化转变事件。这两个过程在自然界中都是非阿伦尼乌斯过程。此外，还观察到两个次级弛豫过程(称为β jg和β)，并与文献相比较。β过程的活化能表明β过程起源于比-OH基团大的侧基的波动。计算得到的易碎性指数表明，布洛芬是一种易碎玻璃原体。

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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Pharmaceutica Analytica Acta

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