起伏囊泡的动态结构因子:有限尺寸和球形几何效应在中子自旋回波实验中的应用。

IF 1.8 4区 物理与天体物理 Q4 CHEMISTRY, PHYSICAL
Rony Granek, Ingo Hoffmann, Elizabeth G. Kelley, Michihiro Nagao, Petia M. Vlahovska, Anton Zilman
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引用次数: 0

摘要

我们考虑了准球形囊泡的动态结构因子(DSF),并对齐尔曼和格兰尼克(ZG)最初提出的等向定向准扁平膜块散射表达式进行了概括。该表达式以起伏膜表面的多维积分形式获得。在足够大的囊泡范围内,即微米或更大的范围内,新的表达式还原为原始的拉伸指数形式。对于小得多的单淀粉囊泡,即使假定塞弗特-朗格小叶密度模式完全松弛并忽略膜粘度,也会明显偏离渐近拉伸指数方程。为了避免在拟合中子自旋回波(NSE)数据时进行详尽的数值积分,我们为多分散系统提供了一个有用的近似值,它能很好地检验完整表达式的数值积分。为了验证新表达式的有效性,我们对由 POPC/POPS 脂质混合物制成的可变大小囊泡进行了 NSE 实验,结果表明新表达式比多年来用于拟合 NSE 数据的原始拉伸指数形式或对原始 ZG 表达式的其他处理方法更具优势。特别是,使用新近似值从 NSE 数据中提取的膜弯曲刚度值对囊泡半径和散射波长不敏感,与根据文献结果计算出的有效弯曲模量预期值([公式:见正文])相比,效果非常好。此外,这里提出的针对起伏准球形壳的广义散射理论可以很容易地扩展到赫尔弗里希哈密顿以外的其他膜起伏动力学模型,从而为研究更复杂和生物相关模型膜系统的纳米尺度动力学奠定了基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Dynamic structure factor of undulating vesicles: finite-size and spherical geometry effects with application to neutron spin echo experiments

Dynamic structure factor of undulating vesicles: finite-size and spherical geometry effects with application to neutron spin echo experiments

We consider the dynamic structure factor (DSF) of quasi-spherical vesicles and present a generalization of an expression that was originally formulated by Zilman and Granek (ZG) for scattering from isotropically oriented quasi-flat membrane plaquettes. The expression is obtained in the form of a multi-dimensional integral over the undulating membrane surface. The new expression reduces to the original stretched exponential form in the limit of sufficiently large vesicles, i.e., in the micron range or larger. For much smaller unilamellar vesicles, deviations from the asymptotic, stretched exponential equation are noticeable even if one assumes that the Seifert-Langer leaflet density mode is completely relaxed and membrane viscosity is neglected. To avoid the need for an exhaustive numerical integration while fitting to neutron spin echo (NSE) data, we provide a useful approximation for polydisperse systems that tests well against the numerical integration of the complete expression. To validate the new expression, we performed NSE experiments on variable-size vesicles made of a POPC/POPS lipid mixture and demonstrate an advantage over the original stretched exponential form or other manipulations of the original ZG expression that have been deployed over the years to fit the NSE data. In particular, values of the membrane bending rigidity extracted from the NSE data using the new approximations were insensitive to the vesicle radii and scattering wavenumber and compared very well with expected values of the effective bending modulus (\(\tilde{\kappa }\)) calculated from results in the literature. Moreover, the generalized scattering theory presented here for an undulating quasi-spherical shell can be easily extended to other models for the membrane undulation dynamics beyond the Helfrich Hamiltonian and thereby provides the foundation for the study of the nanoscale dynamics in more complex and biologically relevant model membrane systems.

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来源期刊
The European Physical Journal E
The European Physical Journal E CHEMISTRY, PHYSICAL-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
2.60
自引率
5.60%
发文量
92
审稿时长
3 months
期刊介绍: EPJ E publishes papers describing advances in the understanding of physical aspects of Soft, Liquid and Living Systems. Soft matter is a generic term for a large group of condensed, often heterogeneous systems -- often also called complex fluids -- that display a large response to weak external perturbations and that possess properties governed by slow internal dynamics. Flowing matter refers to all systems that can actually flow, from simple to multiphase liquids, from foams to granular matter. Living matter concerns the new physics that emerges from novel insights into the properties and behaviours of living systems. Furthermore, it aims at developing new concepts and quantitative approaches for the study of biological phenomena. Approaches from soft matter physics and statistical physics play a key role in this research. The journal includes reports of experimental, computational and theoretical studies and appeals to the broad interdisciplinary communities including physics, chemistry, biology, mathematics and materials science.
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