Mechanical characterization of freestanding lipid bilayers with temperature-controlled phase†

IF 2.9 3区 化学 Q3 CHEMISTRY, PHYSICAL
Soft Matter Pub Date : 2024-10-17 DOI:10.1039/D4SM00706A
Arash Yahyazadeh Shourabi, Roland Kieffer, Djanick de Jong, Daniel Tam and Marie-Eve Aubin-Tam
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Abstract

Coexistence of lipid domains in cell membranes is associated with vital biological processes. Here, we investigate two such membranes: a multi-component membrane composed of DOPC and DPPC lipids with gel and fluid separated domains, and a single component membrane composed of PMPC lipids forming ripples. We characterize their mechanical properties below their melting point, where ordered and disordered regions coexist, and above their melting point, where they are in fluid phase. To conduct these inquiries, we create lipid bilayers in a microfluidic chip interfaced with a heating system and optical tweezers. The chip features a bubble trap and enables high-throughput formation of planar bilayers. Optical tweezers experiments reveal interfacial hydrodynamics (fluid-slip) and elastic properties (membrane tension and bending rigidity) at various temperatures. For PMPC bilayers, we demonstrate a higher fluid slip at the interface in the fluid-phase compared to the ripple phase, while for the DOPC:DPPC mixture, similar fluid slip is measured below and above the transition point. Membrane tension for both compositions increases after thermal fluidization. Bending rigidity is also measured using the forces required to extend a lipid nanotube pushed out of the freestanding membranes. This novel temperature-controlled microfluidic platform opens numerous possibilities for thermomechanical studies on freestanding planar membranes.

Abstract Image

具有温控相的独立脂质双分子层的力学特性。
细胞膜中脂质结构域的共存与重要的生物过程有关。在这里,我们研究了两种这样的膜:一种由 DOPC 和 DPPC 脂质组成的多组分膜,具有凝胶和流体分离的结构域;另一种由 PMPC 脂质组成的单组分膜,形成波纹。我们分析了它们在熔点以下(有序和无序区域共存)和熔点以上(处于流体相)的机械特性。为了进行这些研究,我们在一个与加热系统和光学镊子相连接的微流体芯片中制作了脂质双层膜。该芯片具有气泡捕获器,可高通量形成平面双层膜。光学镊子实验揭示了不同温度下的界面流体力学(流体滑动)和弹性特性(膜张力和弯曲刚度)。对于 PMPC 双层膜,我们证明在流体相界面处的流体滑移比波纹相界面处的更高,而对于 DOPC:DPPC 混合物,在过渡点下方和上方测量到的流体滑移相似。两种成分的膜张力在热流化后都会增加。此外,还利用从独立膜中推出的脂质纳米管的伸展力测量了弯曲刚度。这种新型温控微流体平台为独立平面膜的热力学研究提供了多种可能性。
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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来源期刊
Soft Matter
Soft Matter 工程技术-材料科学:综合
CiteScore
6.00
自引率
5.90%
发文量
891
审稿时长
1.9 months
期刊介绍: Where physics meets chemistry meets biology for fundamental soft matter research.
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