A comprehensive study on capillary surface modifications for electrophoretic separations of liposomes

Alice Šimonová, Renata Píplová, Martin Balouch, František Štěpánek, Tomáš Křížek
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Abstract

Electroosmotic flow significantly impacts the resolution of separations in capillary electrophoresis and its modification is often necessary. Coating of the inner capillary surface either dynamically or permanently offers a way to alter the electroosmotic flow, potentially reducing the adsorption of analytes, in our case liposomes, to the capillary wall. At first, we measured fluorescently labeled liposomes in an uncoated capillary by capillary electrophoresis with laser-induced fluorescence detection. We used a special procedure of the electrophoretic experiment allowing us to observe the development of peak shape at the early stages of migration. We proved that the liposomes were adsorbed to the capillary wall, which led to a very quick and severe dispersion of their peak during their electromigration. For this reason, we used a commercially coated capillary with polyvinyl alcohol, where at the same separation conditions, we observed the peak of the liposome with a stable shape during the migration. However, this capillary is costly, thus four simple dynamic coating methods were tested for four polymers, namely Pluronic F-127, polyvinyl pyrrolidone K30, polyethylene glycol, and polydiallyldimethylammonium chloride. Among them, we chose a method where we flushed the capillary with a 10% solution of polyvinyl pyrrolidone K30 before the first measurement. In addition, in-house made permanent coating with linear polyacrylamide was investigated, which has led to effective suppression of the electroosmotic flow and stable liposome peak, not dispersed during its migration. Liposome separation using this coating fully confirmed that the studied liposomes are negatively charged and migrate in the anodic direction.

Graphical abstract

Abstract Image

用于脂质体电泳分离的毛细管表面改性综合研究
电渗流对毛细管电泳分离的分辨率有很大影响,因此通常需要对其进行调节。对毛细管内表面进行动态或永久涂层可以改变电渗流,从而减少毛细管壁对分析物(在我们的例子中是脂质体)的吸附。首先,我们利用毛细管电泳和激光诱导荧光检测技术测量了未涂层毛细管中的荧光标记脂质体。我们使用了一种特殊的电泳实验程序,可以观察到迁移初期峰形的发展。我们证明,脂质体被吸附在毛细管壁上,导致其在电泳过程中峰值迅速而严重地分散。因此,我们使用了市售的聚乙烯醇涂层毛细管,在相同的分离条件下,我们观察到脂质体的峰值在迁移过程中形状稳定。然而,这种毛细管成本较高,因此我们对四种聚合物(即 Pluronic F-127、聚乙烯吡咯烷酮 K30、聚乙二醇和聚二烯丙基二甲基氯化铵)进行了四种简单的动态涂层方法测试。其中,我们选择的方法是在第一次测量前用 10%的聚乙烯吡咯烷酮 K30 溶液冲洗毛细管。此外,我们还研究了自制的线性聚丙烯酰胺永久涂层,它能有效抑制电渗流,使脂质体峰值稳定,在迁移过程中不会分散。使用这种涂层进行脂质体分离完全证实了所研究的脂质体带负电荷,并向阳极方向迁移。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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