Department of Chemical Engineering, Graduate School of Science and Engineering, Kagoshima University, 1-21-40 Korimoto, Kagoshima 890-0065, Japan.
Frontier Research Institute for Interdisciplinary Sciences, Tohoku University, 6-3 Aramaki aza Aoba, Aoba-ku, Sendai, Miyagi 980-8578, Japan.
J Colloid Interface Sci. 2019 Feb 15;536:414-423. doi: 10.1016/j.jcis.2018.10.058. Epub 2018 Oct 23.
In our previous study, we prepared millimeter-sized spherical hard capsules by solidifying droplets of liquid monomer or polymer solution placed on superamphiphobic surface. Application of liquid marbles in place of the naked droplets for capsule preparation has a great potential to increase encapsulation efficiency of high volatile ingredients. Further, interfacial thermodynamic prediction of internal configuration of capsules from spreading coefficients may be effective to prepare core/shell capsule.
Droplets of liquid monomer containing a volatile ingredient were rolled on superamphiphobic powders to prepare liquid marbles and solidified by photopolymerization. For preparation of core/shell capsules, the liquid marbles injected with an immiscible water droplet were also solidified.
A volatile ingredient could be encapsulated with higher efficiency than our previous method. Interfacial thermodynamic prediction of internal configuration of capsules from spreading coefficients indicated successful formation of core/shell capsules. However, photopolymerization of the liquid marbles in a static condition resulted in formation of not only core/shell capsules but also acorn-type capsules. Furthermore, the core/shell capsules were distorted and the shell thickness was not uniform. Rolling of the liquid marbles, which generated centrifugal force inside of the liquid marbles, was effective to prepare spherical capsules with highly uniform shell thickness.
在我们之前的研究中,我们通过将放置在超疏水表面上的液体单体或聚合物溶液液滴滴固化来制备毫米级球形硬胶囊。将液体大理石应用于胶囊制备中裸露液滴的位置,对于高挥发性成分的封装效率具有很大的提高潜力。此外,通过铺展系数对内部分型胶囊的界面热力学预测,可能有助于制备核/壳胶囊。
含有挥发性成分的液体单体液滴滴落在超疏水粉末上以制备液体大理石,并通过光聚合进行固化。为了制备核/壳胶囊,还将注入不混溶液滴的液体大理石进行固化。
与我们之前的方法相比,挥发性成分的封装效率更高。通过铺展系数对胶囊内部分型的界面热力学预测表明成功形成了核/壳胶囊。然而,在静态条件下对液体大理石进行光聚合不仅会形成核/壳胶囊,还会形成橡果型胶囊。此外,核/壳胶囊会变形,且壳层厚度不均匀。滚动液体大理石会在液体大理石内部产生离心力,有助于制备具有高度均匀壳层厚度的球形胶囊。
