Influence of Pore Size of Mesoporous Silica on Physical Stability of Overloaded Celecoxib Glass.

IF 4.5 2区医学 Q2 MEDICINE, RESEARCH & EXPERIMENTAL

Molecular Pharmaceutics Pub Date : 2025-04-04 DOI:10.1021/acs.molpharmaceut.4c01482

Xue Han, Kohsaku Kawakami

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引用次数: 0

Abstract

The stabilization mechanism of mesoporous silica (MS) of two different pore sizes (21 and 2.5 nm) on overloaded celecoxib (CEL) glass was investigated. Differential scanning calorimetry (DSC) measurements revealed the presence of three fractions with different molecular mobilities: free, intermediate, and rigid ones. The free fraction exhibited cold crystallization during DSC heating and was assumed to have almost the same properties as those of the bulk molecules. The rigid fraction did not exhibit either glass transition or cold crystallization behavior, which should be stabilized by interactions with the MS surface. The remaining molecules exhibited glass transition behavior without any tendency toward cold crystallization during heating, which is called the intermediate fraction. The molecular dynamics of each fraction was investigated by using broadband dielectric spectroscopy (BDS). While the intermediate and free fractions exhibited comparable mobility, the rigid fraction demonstrated pore-size-dependent behavior: enhanced and suppressed molecular mobility was observed for the rigid fraction confined in 21 and 2.5 nm-pores, respectively. Isothermal crystallization of CEL glass was investigated using DSC and BDS at 95 °C. The results revealed that the CEL glass mixed with MS with large pores exhibited slower crystallization compared to the CEL glass without MS, whereas accelerated crystallization was observed for the CEL mixed with a small amount of MS of small pores. The pore size of 21 nm was much larger than the cooperatively rearranging region (CRR) of the CEL glass, whereas the pore size of 2.5 nm was comparable to that. When the pore size was larger than that of the CRR, most of the loaded CEL molecules behaved as an intermediate fraction, presumably because the molecules could exchange inside and outside the pore. In contrast, the exchange was not likely to proceed when the pore size was comparable to or smaller than that of the CRR, leaving a large free fraction. This finding provides a deep understanding of the stabilization mechanism of overloaded pharmaceutical glass by using mesoporous materials.

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研究了两种不同孔径（21 nm 和 2.5 nm）的介孔二氧化硅（MS）在超载塞来昔布（CEL）玻璃上的稳定机制。差示扫描量热法（DSC）测量显示，存在三种分子流动性不同的馏分：自由馏分、中间馏分和刚性馏分。自由馏分在 DSC 加热过程中表现出冷结晶，因此被认为具有与大分子几乎相同的特性。刚性部分既不表现出玻璃化转变行为，也不表现出冷结晶行为，应该是通过与质谱表面的相互作用而稳定下来的。其余的分子在加热过程中表现出玻璃化转变行为，没有任何冷结晶趋势，这部分分子被称为中间部分。我们使用宽带介电光谱（BDS）研究了各馏分的分子动力学。中间馏分和自由馏分表现出相当的流动性，而刚性馏分则表现出与孔径大小相关的行为：分别在 21 nm 和 2.5 nm 孔径的刚性馏分中观察到增强和抑制的分子流动性。使用 DSC 和 BDS 在 95 °C 温度下研究了 CEL 玻璃的等温结晶。结果表明，与不含 MS 的 CEL 玻璃相比，混有大孔 MS 的 CEL 玻璃的结晶速度较慢，而混有少量小孔 MS 的 CEL 玻璃的结晶速度加快。21 nm 的孔径远大于 CEL 玻璃的合作重排区 (CRR)，而 2.5 nm 的孔径与之相当。当孔径大于 CRR 时，大部分负载的 CEL 分子表现为中间部分，这可能是因为分子可以在孔内外进行交换。相反，当孔径与 CRR 相当或小于 CRR 时，交换就不可能进行，从而留下了大量的游离部分。这一发现有助于深入了解利用介孔材料稳定超载药用玻璃的机制。

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

Molecular Pharmaceutics 医学-药学

CiteScore

8.00

自引率

6.10%

发文量

391

审稿时长

2 months

期刊介绍： Molecular Pharmaceutics publishes the results of original research that contributes significantly to the molecular mechanistic understanding of drug delivery and drug delivery systems. The journal encourages contributions describing research at the interface of drug discovery and drug development. Scientific areas within the scope of the journal include physical and pharmaceutical chemistry, biochemistry and biophysics, molecular and cellular biology, and polymer and materials science as they relate to drug and drug delivery system efficacy. Mechanistic Drug Delivery and Drug Targeting research on modulating activity and efficacy of a drug or drug product is within the scope of Molecular Pharmaceutics. Theoretical and experimental peer-reviewed research articles, communications, reviews, and perspectives are welcomed.