Reproducible reformation of a bilayer lipid membrane using microair bubbles

Droplet Pub Date : 2023-06-23 DOI:10.1002/dro2.73
Izumi Hashimoto, Toshihisa Osaki, Hirotaka Sugiura, Hisatoshi Mimura, Sho Takamori, Norihisa Miki, Shoji Takeuchi
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引用次数: 1

Abstract

Planar bilayer lipid membranes (BLMs) are widely used as models for cell membranes in various applications, including drug discovery and biosensors. However, the nanometer-thick bilayer structure, assembled through hydrophobic interactions of amphiphilic lipid molecules, makes such BLM systems mechanically and electrically unstable. In this study, we developed a device to reform BLMs using a microair bubble. The device consists of a double well divided by a separator with a microaperture, where a BLM was formed by infusing a lipid-dispersed solvent and an aqueous droplet into each well in series. When the BLM ruptured, a microair bubble was injected from the bottom of the well to split the merged aqueous droplet at the microaperture, which resulted in the reformation of two lipid monolayers on the split droplets. By bringing the two droplets into contact, a new BLM was formed. An angled step design was introduced in the BLM device to guide the bubble and ensure the splitting of the merged droplet. We also elucidated the optimal bubble inflow rate for the reproducible BLM reformation. Using a 4-channel parallel device, we demonstrated the individual and repeatable reformation of BLMs. Our approach will aid the development of automated and arrayed BLM systems.

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利用微气泡对双层脂质膜进行可重复重组
平面双层脂质膜(BLM)被广泛用作各种应用中的细胞膜模型,包括药物发现和生物传感器。然而,通过两亲性脂质分子的疏水相互作用组装的纳米厚双层结构使这种BLM系统在机械和电学上都不稳定。在这项研究中,我们开发了一种使用微气泡改造BLM的设备。该装置由一个由带微孔的分离器分隔的双孔组成,其中通过将脂质分散的溶剂和水滴串联注入每个孔中形成BLM。当BLM破裂时,从井底注入微气泡,在微孔处分裂合并的液滴,这导致分裂液滴上的两个脂质单层的重组。通过使两个液滴接触,形成了新的BLM。在BLM装置中引入了倾斜台阶设计,以引导气泡并确保合并液滴的分裂。我们还阐明了可重复BLM改造的最佳气泡流入速率。使用4通道并行设备,我们展示了BLM的单独和可重复的改造。我们的方法将有助于开发自动化和阵列BLM系统。
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Issue Information Front Cover, Volume 3, Number 4, October 2024 Inside Back Cover, Volume 3, Number 4, October 2024 Back Cover, Volume 3, Number 4, October 2024 Inside Front Cover, Volume 3, Number 4, October 2024
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