The Effects of the Solvent Choice of the Continuous Phase on the Poly(Urea-Urethane) Microcapsules Properties

F. Salaün
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Abstract

Xylitol, a natural crystalline polyol, presents a cooling effect due to its negative heat of solution at 35 °C supported by humidity absorption, contributing to a fresh sensation when it dissolves. Since this material is sometimes in a liquid state, it cannot be incorporated in or onto a substrate without being protected. One of the strategies to protect the active substance may be forming a barrier layer at its surface, i.e., microencapsulation. The present work is devoted to studying the effect of continuous phase parameters affecting on encapsulation of xylitol with a poly (urea-urethane) shell through a two-step microencapsulation process. The first step is liquid-liquid dispersion either in toluene or Miglyol 812N, and the second step is microencapsulation by interfacial polymerization. The process can be used to control the size distribution of the microparticles, the thickness, and the chemical nature of the shell, which influences the release rate of the active substance. The choice of the continuous phase solvent (toluene or Miglyol 812N) required some changes in the formulation of the system, especially the HLB of the surfactant mixture, to obtain a stable emulsion with a narrow particle size distribution. The thermo-chemical and morphological characteristics of microparticles were studied by Fourier transform-infrared spectroscopy (FT-IR), differential scanning calorimetry (DSC), enthalpy of dilution, and scanning electron microscope (SEM). The microparticle size is governed by the emulsion step and the chemical composition of the organic phase. Most of the thermal properties are related to their porous structure and their chemical shell formation during the interfacial polymerization step.
连续相溶剂选择对聚脲-氨基甲酸乙酯微胶囊性能的影响
木糖醇是一种天然结晶多元醇,由于其在35°C时的溶液负热,在湿度吸收的支持下,呈现冷却效果,有助于在溶解时产生清新的感觉。由于这种材料有时是液态的,它不能在没有保护的情况下掺入基材中。保护活性物质的策略之一可能是在其表面形成屏障层,即微胶囊化。采用两步法研究了连续相参数对木糖醇包封过程的影响。第一步是在甲苯或Miglyol 812N中进行液液分散,第二步是通过界面聚合进行微胶囊化。该工艺可用于控制微颗粒的大小分布、厚度和壳的化学性质,这些都影响活性物质的释放速度。选择连续相溶剂(甲苯或Miglyol 812N)需要改变体系的配方,特别是表面活性剂混合物的HLB,以获得粒径分布窄的稳定乳液。采用傅里叶变换红外光谱(FT-IR)、差示扫描量热法(DSC)、稀释焓和扫描电镜(SEM)研究了微颗粒的热化学和形态特征。微颗粒的大小由乳化步骤和有机相的化学组成决定。大部分的热性能与它们的多孔结构和在界面聚合过程中形成的化学壳有关。
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