Switchable Wetting of Stimulus Responsive Polymer Brushes by Lipid Vesicles: Experiments and Simulations

TL;DR

This study investigates how lipid vesicles interact with stimulus-responsive polymer brushes, demonstrating a switchable wetting behavior modulated by ions and supported by experiments and simulations.

Contribution

It introduces a combined experimental and simulation approach to understand vesicle adhesion and wetting transitions on polymer brushes with stimulus-responsive properties.

Findings

Cd2+ ions induce polymer brush compaction and modulate vesicle adhesion.

A critical threshold of [Cd2+] causes a switch from non-wetting to partial wetting.

Finite-range interactions and buoyancy significantly influence vesicle adhesion behavior.

Abstract

We grafted polyacrylic acid brushes containing cysteine side chains at a defined surface density on planar lipid membranes. Specular X-ray reflectivity data indicated that the addition of Cd2+ ions induces the compaction of the polymer brush layer and modulates the adhesion of lipid vesicles. The critical threshold level inducing the switch from non-wetting to partial wetting state, [Cd2+] = 0.25 mM, was determined by microinterferometry. The interactions between vesicles and brushes were evaluated by height fluctuations of the membrane in contact with brushes and the shape of vesicles near the surface. To analyze these experiments, we have studied adhesion of axially symmetric vesicles for finite-range membrane-substrate interaction and buoyancy through simulations. We found that the local transversality condition that relates the maximal curvature at the edge of the adhesion zone to the adhesion strength remains rather accurate. Thus, although it is not experimentally possible to prepare vesicles at zero buoyancy, we can use the transversality condition to estimate the adhesion strength. However, the adhesion diagram is significantly modified by a finite range of membrane-substrate interaction and buoyancy. For downward buoyancy, vesicles merely sediment onto the substrate and there is no mean-field adhesion transition. For upward buoyancy, adhered vesicles are metastable at best. Thus, a mean-field adhesion transition can only occur at vanishing buoyancy. Only for zero-range membrane-substrate interaction does a second-order adhesion transition occur at finite interaction strength. For any finite-range interaction, the transition occurs when the membrane-substrate interaction changes from repulsive to attractive. We present a adhesion diagram as a function of adhesion strength and buoyancy and compare the adhesion behavior of vesicles to the wetting behavior of droplets of liquids.