Influence of surface pinning points on diffusion of adsorbed lipid vesicles
Journal article, 2009

Using a simple model of a vesicle and a substrate, we have studied surface diffusion of an adsorbed vesicle. We show that the experimentally observed but unexplained fact, that a neutral (POPC) vesicle adsorbed to a SiO2 or mica surface does not diffuse but can be moved laterally by an atomic force microscope (AFM) t, without rupture, can be explained by transient (i.e., temporary) pinning of lipid head groups to surface charges. We studied the surface diffusion for different vesicle adsorption strengths (without any pinning taking place), with the observation that stronger vesicle-surface attraction leads to slower surface diffusion. However, the surface diffusion was still significant and too high to explain the experimentally observed immobility. When allowing transient lipid pinning between the vesicle and the , a 1-2 orders of magnitude decrease in the surface diffusion coefficient was observed. For a lipid adsorption potential of around 20 kB-T and a lipid pinning potential of about 25 kB-T, the vesicle is found to be practically immobile on the surface.

membranes

bilayer

molecular-dynamics

Temperature-dependence

adsorption

AFM

QCM-D

computer-simulation

Author

Simon Klacar

Chalmers, Applied Physics, Chemical Physics

Kristian Dimitrievski

Chalmers, Applied Physics, Chemical Physics

Bengt Herbert Kasemo

Chalmers, Applied Physics, Chemical Physics

Journal of Physical Chemistry B

1520-6106 (ISSN) 1520-5207 (eISSN)

Vol. 113 17 5681-5685

Subject Categories

Atom and Molecular Physics and Optics

Other Physics Topics

DOI

10.1021/jp810874h

More information

Created

10/7/2017