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膜张力控制融合脂质体中的相平衡。

Membrane tension controls the phase equilibrium in fusogenic liposomes.

作者信息

Schmitt Laura Maria, Dreissen Georg, Kolasinac Rejhana, Csiszár Agnes, Merkel Rudolf

机构信息

Forschungszentrum Julich, Institute of Biological Information Processing 2: Mechanobiology Julich Germany.

Forschungszentrum Julich, Institute of Biological Information Processing 2: Mechanobiology Julich Germany

出版信息

RSC Adv. 2022 Aug 24;12(37):24114-24129. doi: 10.1039/d2ra04019k. eCollection 2022 Aug 22.

DOI:10.1039/d2ra04019k
PMID:36093247
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9400399/
Abstract

Fusogenic liposomes have been widely used for molecule delivery to cell membranes and cell interior. However, their physicochemical state is still little understood. We tested mechanical material behavior by micropipette aspiration of giant vesicles from fusogenic lipid mixtures and found that the membranes of these vesicles are fluid and under high mechanical tension even before aspiration. Based on this result, we developed a theoretical framework to determine the area expansion modulus and membrane tension of such pre-tensed vesicles from aspiration experiments. Surprisingly high membrane tension of 2.1 mN m and very low area expansion modulus of 63 mN m were found. We interpret these peculiar material properties as the result of a mechanically driven phase transition between the usual lamellar phase and an, as of now, not finally determined three dimensional phase of the lipid mixture. The free enthalpy of transition between these phases is very low, on the order of the thermal energy.

摘要

融合脂质体已被广泛用于向细胞膜和细胞内部递送分子。然而,它们的物理化学状态仍鲜为人知。我们通过用微量移液器抽吸融合脂质混合物中的巨型囊泡来测试材料的力学行为,发现这些囊泡的膜即使在抽吸之前也是流体且处于高机械张力下。基于这一结果,我们开发了一个理论框架,用于从抽吸实验中确定此类预张紧囊泡的面积膨胀模量和膜张力。我们发现膜张力高达2.1 mN/m,面积膨胀模量极低,为63 mN/m。我们将这些特殊的材料特性解释为脂质混合物在通常的层状相和目前尚未最终确定的三维相之间机械驱动的相变结果。这些相之间的转变自由焓非常低,约为热能的量级。

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