Membrane stiffening in Chitosan mediated multilamellar vesicles of alkyl ether carboxylates

Hypothesis: Membrane undulations are known to strongly affect the stability of uni-and multilamellar vesicles formed by surfactants or phospholipids. Herein, based on the same arguments, we hypothesise that the properties of polyelectrolyte mediated surfactant multilamellar vesicles, in particular the multi-plicity - i.e. the number of layers forming the vesicle - depend on the dynamics of the membrane.Experiments: Small-angle neutron scattering (SANS) and neutron spin-echo (NSE) were used to probe the structure and the dynamics of the multilayered vesicles formed in mixtures of the biopolymer chitosan and oppositely charged alkyl ether carboxylates. The neutron scattering data are complemented by static and dynamic light scattering experiments. Experiments were performed in polyelectrolyte excess condi-tions, and at a pH close to the pKa of the surfactant.Findings: The structural investigation shows very clearly that multilayered surfactant/polyelectrolyte vesicles are formed in the investigated mixtures. Only 3 to 5 layers form, on average, one vesicle, as sim-ilarly found in mixtures of chitosan and phospholipid vesicles. NSE shows that the surfactant membrane becomes stiffer upon complexation with chitosan, and that the fluctuation of the layers is strongly cou-pled in time and space. Such strong coupling and the increase in overall stiffness is associated with a high entropic cost. Accordingly, the combined SANS and NSE study points out that the low multiplicity found in multilayered vesicles involving the rigid polysaccharide chitosan arises from the strongly coupled dynamics of the membrane layers.(c) 2022 Published by Elsevier Inc.

Automated summary

Based on the dynamics of the membrane, we hypothesize that the number of layers in polyelectrolyte mediated surfactant multilamellar vesicles depends on membrane undulations. Experimental findings show that the membrane becomes stiffer and the fluctuations of the layers are strongly coupled in time and space when surfactants are complexed with chitosan. This results in a low number of layers in the vesicles.