Solubility Measurement, Model Correlation, and Solvent Effect Analysis of Spectinomycin Dihydrochloride Pentahydrate in Three Binary Solvents

IF 1.4 4区 化学 Q4 CHEMISTRY, PHYSICAL
Dechen Wang, Yu Zhou, Chunyan Liu, Ying Bao
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引用次数: 0

Abstract

The solubility data of spectinomycin dihydrochloride pentahydrate (SDP) in three binary solvents were determined over a temperature range of 278.15–318.15 K by the gravimetric method. Among the selected binary solvents, the solubility of SDP increased with the rise in temperature and initial methanol composition of binary solvents, and the general order of solubility of SDP under the same conditions was: (methanol + ethanol) > (methanol + n-propanol) > (methanol + i-propanol). Subsequently, solubility–temperature models including van’t Hoff equation, λh equation, Yaws equation, and Apelblat equation; solubility–solvent composition models including general single model; solubility–temperature and solvent composition models including NRTL equation and modified Jouyban–Acree model were used to correlate the solubility data. Regarding the application of the NRTL equation in binary solvent systems, the influence of solvent composition on model parameters was first taken into account by introducing a solvent composition correction factor, thereby exhibiting an enhancement in fitting accuracy. To gain deeper insights into the dissolving behavior of SDP, molecular electrostatic potential surface, Hirshfeld surface analysis and the KAT-LSER model were applied to analyze the molecular interactions between SDP molecules and the solvent effects. Meanwhile, entire solubility data in three binary solvent systems at 298.15 K were associated as a function of solvent properties on the basis of KAT-LSER model. The results revealed that SDP primarily acts as hydrogen bond acceptors in solution, and polar interactions between SDP and solvent molecules can play a crucial role in promoting the dissolution of SDP.

Abstract Image

盐酸大观霉素五水合物在三种二元溶剂中的溶解度测量、模型相关性和溶剂效应分析
采用重量法测定了五水合盐酸光谱霉素(SDP)在三种二元溶剂中的溶解度数据,温度范围为 278.15-318.15 K。在所选的二元溶剂中,SDP的溶解度随着温度的升高和二元溶剂中初始甲醇成分的增加而增加,在相同条件下,SDP溶解度的一般顺序为:(甲醇+乙醇)>;(甲醇+正丙醇)>;(甲醇+异丙醇)。随后,采用了溶解度-温度模型(包括范特霍夫方程、λh 方程、Yaws 方程和 Apelblat 方程)、溶解度-溶剂组成模型(包括一般单一模型)、溶解度-温度和溶剂组成模型(包括 NRTL 方程和修正的 Jouyban-Acree 模型)来关联溶解度数据。在二元溶剂体系中应用 NRTL 方程时,首先考虑了溶剂组成对模型参数的影响,引入了溶剂组成校正因子,从而提高了拟合精度。为了深入了解 SDP 的溶解行为,应用分子静电位面、Hirshfeld 表面分析和 KAT-LSER 模型分析了 SDP 分子间的相互作用和溶剂效应。同时,在 KAT-LSER 模型的基础上,将 SDP 在 298.15 K 下三种二元溶剂体系中的全部溶解度数据作为溶剂性质的函数进行了关联分析。结果表明,SDP 在溶液中主要作为氢键受体,SDP 与溶剂分子之间的极性相互作用对促进 SDP 的溶解起着至关重要的作用。
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来源期刊
Journal of Solution Chemistry
Journal of Solution Chemistry 化学-物理化学
CiteScore
2.30
自引率
0.00%
发文量
87
审稿时长
3-8 weeks
期刊介绍: Journal of Solution Chemistry offers a forum for research on the physical chemistry of liquid solutions in such fields as physical chemistry, chemical physics, molecular biology, statistical mechanics, biochemistry, and biophysics. The emphasis is on papers in which the solvent plays a dominant rather than incidental role. Featured topics include experimental investigations of the dielectric, spectroscopic, thermodynamic, transport, or relaxation properties of both electrolytes and nonelectrolytes in liquid solutions.
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