Genuine Antiplasticizing Effect of Water on a Glass-former Drug

Overview

Journal Sci Rep

Specialty Science

Date 2017 Aug 9

PMID 28785030

Citations 4

Authors

Guadalupe N Ruiz

Michela Romanini

Astrid Hauptmann

Thomas Loerting

Evgenyi Shalaev

Josep Ll Tamarit

Luis C Pardo

Roberto Macovez

Affiliations

Soon will be listed here.

Abstract

Water is the most important plasticizer of biological and organic hydrophilic materials, which generally exhibit enhanced mechanical softness and molecular mobility upon hydration. The enhancement of the molecular dynamics upon mixing with water, which in glass-forming systems implies a lower glass transition temperature (T ), is considered a universal result of hydration. In fact, even in the cases where hydration or humidification of an organic glass-forming sample result in stiffer mechanical properties, the molecular mobility of the sample almost always increases with increasing water content, and its T decreases correspondingly. Here, we present an experimental report of a genuine antiplasticizing effect of water on the molecular dynamics of a small-molecule glass former. In detail, we show that addition of water to prilocaine, an active pharmaceutical ingredient, has the same effect as that of an applied pressure, namely, a decrease in mobility and an increase of T . We assign the antiplasticizing effect to the formation of prilocaine-H O dimers or complexes with enhanced hydrogen bonding interactions.

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