Department of Chemical Engineering, Loughborough University, Loughborough LE11 3TU, United Kingdom.
Department of Chemical Engineering, Loughborough University, Loughborough LE11 3TU, United Kingdom.
J Colloid Interface Sci. 2017 Jul 15;498:387-394. doi: 10.1016/j.jcis.2017.03.067. Epub 2017 Mar 18.
Core-shell microcapsules and crescent-shaped microparticles can be used as picolitre bioreactors for cell culture and microwells for cell trapping/immobilisation, respectively.
Monodisperse polylactic acid (PLA) core-shell microcapsules with a diameter above 200μm, a shell thickness of 10μm, and 96% water entrapment efficiency were produced by solvent evaporation from microfluidically generated W/O/W emulsion drops with core-shell structure, and used to encapsulate Saccharomyces cerevisiae yeast cells in their aqueous cores. The morphological changes of the capsules stained with Nile red were studied over 14days under different osmotic pressure and pH gradients.
The shell retained its integrity under isotonic conditions, but buckling and particle crumbling occurred in a hypertonic solution. When the capsules containing 5wt% aqueous Eudragit® S 100 solution in the core were incubated in 10M HCl solution, H diffused through the PLA film into the core causing an ionic gelation of the inner phase and its phase separation into polymer-rich and water-rich regions, due to the transition of Eudragit from a hydrophilic to hydrophobic state. Crescent-shaped composite microparticles with Eudragit cores and PLA shells were fabricated by drying core-shell microcapsules with gelled cores, due to the collapse of PLA shells encompassing water-rich crescent regions.
核壳微胶囊和新月形微粒可以分别用作细胞培养的皮升级生物反应器和细胞捕获/固定的微井。
通过从具有核壳结构的微流体制备的 W/O/W 乳液滴中的溶剂蒸发,产生了直径大于 200μm、壳厚 10μm、水包埋效率为 96%的单分散聚乳酸(PLA)核壳微胶囊,并用于在其水核中封装酿酒酵母细胞。用尼罗红染色研究了在不同渗透压和 pH 梯度下微胶囊 14 天内的形态变化。
在等渗条件下,壳保持完整,但在高渗溶液中会出现弯曲和颗粒破碎。当含有 5wt%水相 Eudragit® S100 溶液的核芯的胶囊在 10M HCl 溶液中孵育时,H 通过 PLA 膜扩散到核中,导致内部相的离子凝胶化及其分离成富含聚合物和富含水的区域,这是由于 Eudragit 从亲水状态转变为疏水状态。通过干燥具有凝胶核的核壳微胶囊,制备了具有 Eudragit 核和 PLA 壳的新月形复合微粒,这是由于包围富含水的新月形区域的 PLA 壳塌陷所致。
