Main phase transition in lipid bilayers: phase coexistence and line tension in a soft, solvent-free, coarse-grained model

TL;DR

This paper introduces a new coarse-grained, solvent-free model for lipid bilayers that captures key physical properties and accurately locates the main phase transition, coexistence, and line tension.

Contribution

The authors develop a novel soft, solvent-free coarse-grained model that reproduces lipid membrane properties and studies phase transition and line tension.

Findings

Model reproduces membrane properties like bending rigidity and area per lipid.

Accurately locates the liquid-gel phase coexistence.

Provides estimates for line tension in lipid bilayers.

Abstract

We devise a soft, solvent-free, coarse-grained model for lipid bilayer membranes. The non-bonded interactions take the form of a weighted-density functional which allows us to describe the thermodynamics of self-assembly and packing effects of the coarse-grained beads in terms of a density expansion of the equation of state and the weighting functions that regularize the microscopic bead densities, respectively. Identifying the length and energy scales via the bilayer thickness and the thermal energy scale, kT, the model qualitatively reproduces key characteristics (e.g., bending rigidity, area per lipid molecules, and compressibility) of lipid membranes. We employ this model to study the main phase transition between the liquid and the gel phase of the bilayer membrane. We accurately locate the phase coexistence using free energy calculations and also obtain estimates for the bare and the thermodynamic line tension.