Phase Transition and dissipation driven budding in lipid vesicles

TL;DR

This study reveals how rapid, non-equilibrium membrane budding in lipid vesicles occurs due to mechanical perturbations during phase transitions, with theoretical predictions matching experimental observations.

Contribution

It demonstrates that non-equilibrium budding is driven by rapid phase transitions and dissipation effects, a phenomenon previously unexplored at short timescales.

Findings

Rapid phase transitions induce immediate budding in GUVs.

Dissipation influences the size and number of buds formed.

Theoretical model accurately predicts critical rates for budding.

Abstract

Membrane budding has been extensively studied as an equilibrium process attributed to the formation of coexisting domains or changes in the vesicle area to volume ratio (reduced volume). In contrast, non-equilibrium budding remains experimentally widely unexplored especially when time scales fall well below the characteristic diffusion time of lipids{\tau} . We show that localized mechanical perturbations, initiated by driving giant unilamellar vesicles (GUVs) through their lipid phase transition, leads to the immediate formation of rapidly growing, multiply localized, non-equilibrium buds, when the transition takes place at short timescales (<{\tau}). We show that these buds arise from small fluid-like perturbations and grow as spherical caps in the third dimension, since in plane spreading is obstructed by the continuous rigid gel-like matrix. Accounting for both three and two dimensional viscosity, we demonstrate that dissipation decreases the size scale of the system and therefore favours the formation of multiple buds as long as the perturbation takes place above a certain critical rate. This rate depends on membrane and media viscosity and is qualitatively and quantitatively correctly predicted by our theoretical description.