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非晶态阿折地平及其与哌嗪的共非晶态相的物理和热力学稳定性比较。

Comparison of the physical and thermodynamic stability of amorphous azelnidipine and its coamorphous phase with piperazine.

作者信息

Du Shuang, Li Wen Sheng, Wu Ya Rong, Fu Yan, Yang Caiqin, Wang Jing

机构信息

College of Pharmaceutical Sciences, Hebei Medical University Shijiazhuang 050017 People's Republic of China

出版信息

RSC Adv. 2018 Sep 21;8(57):32756-32764. doi: 10.1039/c8ra05535a. eCollection 2018 Sep 18.

DOI:10.1039/c8ra05535a
PMID:35547669
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9086389/
Abstract

A major challenge in drug development is that the majority of drugs are water insoluble, and a powerful method to conquer this obstacle is to transfer a crystalline drug into its amorphous phase (AP) or coamorphous phase (CAP) with a coformer. In the present study, the physical and chemical stabilities of an AP and a CAP based on the dihydropyridine calcium ion antagonist azelnidipine (AZE) were investigated using thermal analysis and a solution chemistry method. The identification of two APs (named α-AP and β-AP, from crystalline α-AZE and β-AZE, respectively) and one AZE-piperazine CAP was attempted using powder X-ray diffraction, temperature modulated differential scanning calorimetry and Fourier-transform infrared spectroscopy. The transition thermodynamics from the two APs and the CAP to stable crystalline β-AZE (β-Cry) were investigated using a solubility method. The solubility of the two APs, the CAP and β-Cry in 0.01 M HCl medium at 298, 304, 310, 316 and 322 K was investigated; the values obtained were used to calculate the thermodynamic parameters of the transition reaction. The transition temperatures of α-AP, β-AP and the CAP to form β-Cry in 0.01 M HCl were 237.7, 400.3, and 231.4 K, respectively. The glass transition temperature ( ) values of α-AP, β-AP and the CAP were 365.5, 358.9 and 347.6 K, respectively, indicating a high physical stability for α-AP. However, β-AP proved to be the most thermodynamically stable form at room temperature compared with α-AP and CAP in the 0.01 M HCl medium. As evidenced by those observations, no general relationship occurred between the solid physical stability and the solution chemical stability for AP and CAP. The kinetics of the solid-state decomposition, studied using DSC analysis, showed that the activation energies for decomposition of α-AP, β-AP and CAP at high temperatures were 133.0, 114.2 and 131.6 kJ mol, respectively.

摘要

药物研发中的一个主要挑战是大多数药物难溶于水,克服这一障碍的有效方法是将结晶药物与共形成剂转化为其无定形相(AP)或共无定形相(CAP)。在本研究中,使用热分析和溶液化学方法研究了基于二氢吡啶类钙离子拮抗剂阿折地平(AZE)的AP和CAP的物理和化学稳定性。尝试使用粉末X射线衍射、温度调制差示扫描量热法和傅里叶变换红外光谱法鉴定两种AP(分别命名为α-AP和β-AP,分别来自结晶α-AZE和β-AZE)和一种AZE-哌嗪CAP。使用溶解度方法研究了两种AP、CAP和稳定结晶β-AZE(β-Cry)之间的转变热力学。研究了两种AP、CAP和β-Cry在298、304、310、316和322K的0.01M HCl介质中的溶解度;所得值用于计算转变反应的热力学参数。α-AP、β-AP和CAP在0.01M HCl中形成β-Cry的转变温度分别为237.7、400.3和231.4K。α-AP、β-AP和CAP的玻璃化转变温度( )值分别为365.5、358.9和347.6K,表明α-AP具有较高的物理稳定性。然而,在0.01M HCl介质中,与α-AP和CAP相比,β-AP在室温下被证明是热力学上最稳定的形式。这些观察结果表明,AP和CAP的固体物理稳定性与溶液化学稳定性之间不存在普遍关系。使用DSC分析研究的固态分解动力学表明,α-AP、β-AP和CAP在高温下分解的活化能分别为133.0、114.2和131.6kJ mol。

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